PROPOSED Local Coverage Determination (LCD)

Skin Substitute Grafts/Cellular and Tissue-Based Products for the Treatment of Diabetic Foot Ulcers and Venous Leg Ulcers

DL39760

Expand All | Collapse All
Proposed LCD
Proposed LCDs are works in progress that are available on the Medicare Coverage Database site for public review. Proposed LCDs are not necessarily a reflection of the current policies or practices of the contractor.

Document Note

Note History

Contractor Information

Proposed LCD Information

Document Information

Source LCD ID
N/A
Proposed LCD ID
DL39760
Original ICD-9 LCD ID
Not Applicable
Proposed LCD Title
Skin Substitute Grafts/Cellular and Tissue-Based Products for the Treatment of Diabetic Foot Ulcers and Venous Leg Ulcers
Proposed LCD in Comment Period
Source Proposed LCD
Original Effective Date
N/A
Revision Effective Date
N/A
Revision Ending Date
N/A
Retirement Date
N/A
Notice Period Start Date
N/A
Notice Period End Date
N/A

CPT codes, descriptions, and other data only are copyright 2023 American Medical Association. All Rights Reserved. Applicable FARS/HHSARS apply.

Fee schedules, relative value units, conversion factors and/or related components are not assigned by the AMA, are not part of CPT, and the AMA is not recommending their use. The AMA does not directly or indirectly practice medicine or dispense medical services. The AMA assumes no liability for data contained or not contained herein.

Current Dental Terminology © 2023 American Dental Association. All rights reserved.

Copyright © 2024, the American Hospital Association, Chicago, Illinois. Reproduced with permission. No portion of the AHA copyrighted materials contained within this publication may be copied without the express written consent of the AHA. AHA copyrighted materials including the UB‐04 codes and descriptions may not be removed, copied, or utilized within any software, product, service, solution, or derivative work without the written consent of the AHA. If an entity wishes to utilize any AHA materials, please contact the AHA at 312‐893‐6816.

Making copies or utilizing the content of the UB‐04 Manual, including the codes and/or descriptions, for internal purposes, resale and/or to be used in any product or publication; creating any modified or derivative work of the UB‐04 Manual and/or codes and descriptions; and/or making any commercial use of UB‐04 Manual or any portion thereof, including the codes and/or descriptions, is only authorized with an express license from the American Hospital Association. The American Hospital Association (the "AHA") has not reviewed, and is not responsible for, the completeness or accuracy of any information contained in this material, nor was the AHA or any of its affiliates, involved in the preparation of this material, or the analysis of information provided in the material. The views and/or positions presented in the material do not necessarily represent the views of the AHA. CMS and its products and services are not endorsed by the AHA or any of its affiliates.

Issue

Issue Description

This Local Coverage Determination (LCD) has been developed to create a policy consistent with current evidence. This LCD covers skin substitute grafts/cellular and tissue-based products (CTP) for the treatment of diabetic foot ulcers (DFU) and venous leg ulcers (VLU) in the Medicare population. Diabetic foot ulcers and VLU have multifactor etiologies requiring targeted therapy. Both are associated with significant morbidity, including amputations, and diminished quality of life. Numerous remedies including systemic and local treatments have been proposed. Skin substitute grafts/CTP are marketed as purported treatments for these ulcers. Their effectiveness is currently an active area of investigation. Despite lack of definitive improved health outcomes in the Medicare population coverage will be provided for skin substitute grafts/CTP having peer-reviewed, published evidence supporting their use as adjunctive treatment for chronic ulcers shown to have failed established methods to affect healing.

Issue - Explanation of Change Between Proposed LCD and Final LCD

CMS National Coverage Policy

This LCD supplements but does not replace, modify, or supersede existing Medicare applicable National Coverage Determinations (NCDs) or payment policy rules and regulations for skin substitute grafts/cellular and tissue-based products for the treatment of diabetic foot ulcers and venous leg ulcers. Federal Statute and subsequent Medicare regulations regarding provision and payment for medical services are lengthy. They are not repeated in this LCD. Neither Medicare payment policy rules nor this LCD replace, modify, or supersede applicable state statutes regarding medical practice or other health practice professions acts, definitions and scopes of practice. All providers who report services for Medicare payment must fully understand and follow all existing laws, regulations, and rules for Medicare payment for skin substitute grafts/cellular and tissue-based products for the treatment of diabetic foot ulcers and venous leg ulcers and must properly submit only valid claims service and products utilized. Please review, understand and apply the necessity provisions in the policy according to the Manual guidelines. Relevant CMS manual instructions and policies may be found in the following Internet-Only Manuals (IOMs) published on the CMS Web site:

IOM Citations:

  • CMS IOM Publication 100-02, Medicare Benefit Policy Manual,
    • Chapter 15, Section 50.4.1 Approved Use of Drug
  • CMS IOM Publication 100-03, Medicare National Coverage Determinations (NCD) Manual,
    • Chapter 1, Part 4 Section 270.3 Blood-Derived Products for Chronic Non-Healing Wounds, Section 270.4 Treatment of Decubitus Ulcers and Section 270.5 Porcine Skin and Gradient Pressure Dressings
  • CMS IOM Publication 100-04, Medicare Claims Processing Manual,
    • Chapter 17, Section 40 Discarded Drugs and Biologicals
  • CMS IOM Publication 100-08, Medicare Program Integrity Manual,
    • Chapter 13, Section 5.4 Reasonable and Necessary Provision in an LCD
  • CMS IOM Publication 100-04, Medicare Program Integrity Manual,
    • Chapter 17, Section 10 Payment Rules for Drugs and Biologicals

Social Security Act (Title XVIII) Standard References:

  • Title XVIII of the Social Security Act, Section 1862(a)(1)(A) states that no Medicare payment may be made for items or services which are not reasonable and necessary for the diagnosis or treatment of illness or injury.
  • Title XVIII of the Social Security Act, Section 1862(a)(7). This section excludes routine physical examinations.

Code of Federal Regulations (CFR) References:

  • CFR, Title 21, Volume 8, Chapter 1, Subchapter L, Part 1271.10 Human cells, tissues, and cellular and tissue- based products

Coverage Guidance

Coverage Indications, Limitations, and/or Medical Necessity

Coverage Guidance

Compliance with the provisions in this LCD may be monitored and addressed through post payment data analysis and subsequent medical review audits.

History/Background and General Information

Application of skin substitute graft and CTP for ulcer care indications other than DFU or VLU are not addressed by this LCD. Use of skin substitute graft/CTP must meet the reasonable and necessary threshold for coverage and these devices must be used in accordance with their intended use as approved/regulated by the United States (U.S.) Food and Drug Administration (FDA).

Depending on the purpose of the product and its proposed functions, skin substitute graft/CTP are regulated by the FDA premarket approval (PMA) process, FDA 510(k) premarket notification process, or the FDA regulations for human cells, tissues, and cellular and tissue-based products (HCT/Ps). A product with proposed benefit to chronic ulcer healing does not assume the designation of a skin substitute graft/CTP. FDA classification and indication are not the sole determinants of designation as a skin substitute graft/CTP or provide the reasonable and necessary threshold for coverage.

Chronic DFU and VLU may be unresponsive to initial therapy or persist despite appropriate standardized care. A DFU or VLU having failed to respond to standard of care treatment after 4 weeks (28 days) may be considered chronic and the addition of a skin substitute graft /CTP may be considered reasonable and necessary for certain patients.1-6

Patients receiving skin replacement surgery with a skin substitute graft/CTP should be under the care of a physician/non-physician practitioner (NPP) for the treatment of a systemic disease process (e.g., diabetes mellitus, chronic venous insufficiency, or peripheral vascular disease). It is imperative that systemic disease be monitored and treated to ensure adequate healing of the ulcer.2,6,7

The medical record documentation must support the medical necessity for skin replacement therapy and the product’s use as an ulcer treatment, other than as a wound dressing or covering.

Covered Indications

If the patient meets all criteria as outlined in this LCD, application of a skin substitute graft or CTP in the treatment of DFU and VLU is considered reasonable and necessary for the following conditions:

1. The presence of a chronic, non-infected DFU having failed to respond to documented standard of care (SOC) treatment (outlined below) for a minimum of 4 weeks with documented compliance.6-8

2. The presence of a chronic, non-infected VLU having failed to respond to documented standard of care treatment (outlined below) for a minimum of 4 weeks with documented compliance.4,6,9,10

For purposes of this LCD, SOC treatment includes:4,5,7,9,11,12

  • Comprehensive patient assessment (history, exam, Ankle-Brachial Index [ABI]) and diagnostic tests as indicated) in an implemented treatment plan.
  • For patients with a DFU: assessment of Type 1 or Type 2 diabetes and management history with attention to certain comorbidities (e.g., vascular disease, neuropathy, osteomyelitis), review of current blood glucose levels/hemoglobin A1c (HbA1c), diet and nutritional status, activity level, physical exam that includes assessment of skin, ulcer, regional arterial perfusion (ABI), and assessment of off-loading device or use of appropriate footwear.
  • For patients with a VLU: assessment of clinical history (prior ulcers, phlebitis), physical exam (edema, skin changes), ABI, evaluation of superficial or deep venous reflux, perforator incompetence, and chronic (or acute) venous thrombosis. The use of a firm strength compression garment (>20 mmHg) or multi-layered compressive dressings is an essential component of SOC for venous stasis ulcers. 2,4,5

3. An implemented treatment plan demonstrating all the following: 5,6,10

  • Debridement as appropriate to a clean granular base.
  • Documented evidence of offloading for DFU and some form of sustained compression dressings for VLU.
  • Infection control with removal of foreign body or nidus of infection.
  • Management of exudate with maintenance of a moist environment (moist saline gauze, other classic dressings, bioactive dressing, etc.).
  • Documentation of smoking history, and counselling on the effect of smoking on wound healing. Treatment for smoking cessation and outcome of counselling (if applicable).

4. The skin substitute graft/CTP is applied to an ulcer that has failed to heal or stalled in response to documented standard of care treatment. Documentation of response requires measurements of the initial ulcer, pre- and post-completion of at least 4 weeks of SOC, with additional measurements at initial placement and each subsequent placement of the skin substitute graft/CTP. Standard of care measures without measurable signs of healing must have preceded the application for a minimum of 4 weeks and must continue for the course of therapy. Continuous compression therapy for VLU must be documented for the episode of care.7,9,13

5. The medical record documentation must include the interventions that have failed during prior ulcer evaluation and management. The record must include an updated medication history, review of pertinent medical problems that may have arisen since the previous ulcer evaluation, and explanation of the planned skin replacement with choice of skin substitute graft/CTP product. The procedure risks and complications must also be reviewed and documented.10-12,14,15

6. The patient is under the care of a qualified physician/NPP for the treatment of the systemic disease process(es) etiologic for the condition (e.g., venous insufficiency, diabetes, neuropathy) and documented in the medical record.5,6,10,15

Coverage requirements for skin substitute grafts/CTP

To qualify as skin substitute graft/CTP the product must be:

  1. A non-autologous human cellular or tissue product (e.g., dermal or epidermal, cellular and acellular, homograft OR allograft), OR non-human cellular and tissue product (i.e., xenograft), OR biological product (synthetic or xenogeneic) which applied as a sheet, allowing the scaffolding for skin growth and is intended to remain on the recipient and grow in place or allow recipient’s cells to grow into the implanted graft material16 AND
  2. Have quality supporting evidence to demonstrate the product’s safety, effectiveness, and positive clinical outcomes in the function as a graft for DFU and/or VLU.4,10 Predicate products are not sufficient evidence for an individual product.

Note: Liquid or gel preparations are not considered grafts. Their fluidity does not allow graft placement and stabilization of the product on the wound.14

Limitations (per ulcer episode of care)

The following are considered not reasonable and necessary2,4-6,9,17:

  1. Greater than four applications of a skin substitute graft/CTP within the episode of skin replacement therapy (defined as12 weeks from the first application of a skin substitute graft/CTP). In exceptional cases in which 4 applications is not sufficient for adequate wound healing, additional applications may be considered with documentation that includes progression of wound closure under current treatment plan and medical necessity for additional applications.17
  2. Application of a skin substitute graft/CTP beyond 12-weeks per episode within the episode of skin replacement therapy. In exceptional cases in which 12 weeks is not sufficient for adequate wound healing, additional duration of care may be considered with documentation demonstrating progression of wound closure under current treatment plan and benefit expected from additional applications.
  3. Repeat applications of skin substitute graft/CTP when a previous application was unsuccessful. Unsuccessful treatment is defined as increase in size or depth of an ulcer, no measurable change from baseline, and no sign of improvement or indication that improvement is likely (such as granulation, epithelialization, or progress towards closure). Unsuccessful therapy also includes reoccurrence of the ulcer in the same location within 12 months from initial application.
  4. Application of skin substitute graft/CTP in patients with inadequate control of underlying conditions or exacerbating factors, or other contraindications (e.g., uncontrolled diabetes, active infection, progressive necrosis, active Charcot arthropathy of the ulcer extremity, active vasculitis, or ischemia).6
  5. Use of surgical preparation services (e.g., debridement), in conjunction with routine, simple or repeat skin replacement surgery with a skin substitute graft/CTP.
  6. Excessive wastage (discarded amount).
    • The skin substitute graft/CTP must be used in an efficient manner utilizing the most appropriate size product available at the time of treatment. It is expected that use of product, size and preparation should conform to that most closely fitting the wound with the least amount of wastage.

     7. All liquid or gel skin substitute products or CTPs for ulcer. 14

     8. Placement of skin substitute graft/CTP on infected, ischemic, or necrotic wound bed.9,10

Provider Qualifications

Services provided within the LCD coverage indications will be considered reasonable and necessary when all aspects of care are within the scope of practice of the provider’s professional licensure. All procedures must be performed by appropriately trained providers in the appropriate setting.

Notice: Services performed for any given diagnosis must meet all the indications and limitations stated in this LCD, the general requirements for medical necessity as stated in CMS payment policy manuals, all existing CMS national coverage determinations, and all Medicare payment rules.

Definitions

Autografts/tissue cultured autografts: Includes the harvest and application of an autologous skin graft. These products are designed to circumvent the challenges with autologous skin grafts in the treatment of chronic wounds, ulcers or burns.

Chronic Wound: A chronic wound may be defined as one that is physiologically impaired due to a disruption of the wound healing cycle as a result of impaired angiogenesis, innervation, or cellular migration, among other reasons for 4 weeks or longer.3-5,18

Cellular and Tissue-Based Products (CTP) grafts (also called skin substitute graft*): Include homologous human cellular and tissue products (e.g., dermal or epidermal, cellular and acellular, homograft or allograft), non-human cellular and tissue products (i.e., xenograft), and biological products (synthetic or xenogeneic) that form a sheet scaffolding for skin growth when applied in a sheet over an open wound or ulcer to augment closure or skin growth.2,16

Failed response: An ulcer that has increased in size or depth, or no change in baseline size or depth, or no sign of improvement or indication that improvement is likely (such as granulation, epithelialization, or progress towards closing).

Stalled Wound: An ulcer that has entered a nonhealing or intransigent phase.19

Wound dressing or coverings: Applications applied to wounds as a selective barrier to clean, cover and protect wounds from the surrounding environment to promote optimal environment for wound healing.

*There is a lack of clarity in the definition of skin substitute. For the purpose of this policy, skin substitute grafts will align with the AMA CPT codebook16 description “non-human skin substitute grafts and biological products that form a sheet scaffolding for skin growth”. This surface is not intended to be removed, but grows into place or serves as surface for new skin to grow in.

 

Summary of Evidence

A literature search was conducted using the following key words: non-healing; ulcer; chronic; diabetic foot; foot ulcer; venous leg ulcer; guidelines; ulcer healing; skin substitutes; dermal skin substitute; human skin allograft; randomized trial; standard of care; venous leg ulcer; skin grafts; ulcer dressing; human derived products; animal derived products; FDA regulations. The literature search was filtered to locate articles within 5-10 years, full- text articles, clinical trials, and systematic reviews. In general, improved health outcomes of interest include patient quality of life and function.

Case reports, case series and retrospective reports were not reviewed due to low quality evidence. Review papers, editorials and unpublished reports were not included in the analysis. Literature for use of products outside of DFU and VLU was not included in the evidence review. Much of the literature for DFU overlapped with diabetic lower extremity ulcers so both are included in the review.

Introduction

DFU and VLU, having failed to respond to 4 weeks SOC treatment, may meet reasonable and necessary criteria for the adjunctive application of a skin substitute graft/CTP for certain patients. Diabetic foot ulcers may affect up to 6% of Medicare beneficiaries with either Type I or Type II diabetes. Chronic wounds such as DFU and VLU impact patient quality of life due to impaired mobility, pain, and progressive morbidity.2,4,6,20

Evidence-Based Guidelines for Standard of Care

Evidence-based guidelines indicate that SOC treatment of lower extremity ulcers (e.g., DFU and VLU) should include mechanical offloading, infection control, mechanical compression, limb elevation, debridement of necrotic tissue, management of systemic disease and medications, nutrition assessment, tissue perfusion and oxygenation, education regarding care of the foot, callus, and nail and fitting of shoes, as well as counseling on the risk of continued tobacco use. In addition, maintenance of a moist ulcer environment through appropriate dressings facilitates development of healthy granulation tissue and epithelialization and potentiates complete healing at an ulcer site. Dressings are an integral part of ulcer management by maintaining a moist environment, limiting contamination, and absorbing exudate.5-7,9,11,12,15

A comprehensive assessment of patients and their ulcers will also facilitate appropriate care by identifying and correcting systemic causes of impaired healing. The presence of a severe illness or systemic disease and drug treatments, such as immunosuppressive drugs and systemic steroids, may inhibit ulcer healing by changes in immune tolerance, metabolism, inflammation, nutrition, and tissue perfusion. Therefore, this information, in conjunction with a detailed history of the ulcer itself, is essential.6,7,9

Vascular evaluation is also vital for all chronic ulcers. Palpation of pulses may be problematic in cases of medial arterial calcification. An ankle-brachial index (ABI) should be taken for patients with a questionable pulse deficit although the ABI levels may be falsely elevated with medial arterial calcification. The patient is considered to have impaired arterial perfusion when the ABI is below 0.9. Any ABI less than 1.0 suggests a degree of vascular disease.5 To supplement ankle-brachial studies, toe blood pressure readings, pulse volume recordings, transcutaneous oxygen measurements (TCOMs), and skin perfusion pressure measurements have been suggested as acceptable benchmarks for the prediction of ulcer healing.

Venous ulcers require a series of diagnostic testing to verify superficial or deep venous reflux, perforator incompetence, and chronic (or acute) venous thrombosis. In this regard, venous duplex ultrasound is recommended and if the venous duplex ultrasound does not provide definitive diagnostic information, a venous plethysmography is recommended. Patients with mixed arterial and venous disease require a combination of arterial and venous noninvasive testing. The use of a Class 3 (most supportive) high-compression method is strongly recommended in the treatment of venous ulcers. High strength compression may be applied using techniques such as multilayered elastic compression, inelastic compression, Unna boots, compression stockings, and others. The extent of compression should be modified for patients with mixed venous/arterial disease.5,8,9

The clinical practice guidelines of the Society for Vascular Surgery and the American Venous Forum recommend that patients with VLU have the ulcer classified using the Clinical class, Etiology, Anatomy, and Pathophysiology (CEAP) classification (confirmed by duplex scan). The Venous Clinical Severity Score (VCSS) is recommended to assess changes in response to therapy. Specific classification of venous disease is essential for standardization of venous disease severity and evaluation of treatment efficiency.9

The Society for Vascular Surgery in collaboration with the American Podiatric Medical Association and the Society for Vascular Medicine has recommended a SOC treatment schedule for DFU includes weekly to monthly ulcer evaluations of size and healing progress, infection control, debridement of all devitalized tissue and surrounding callus material, dressings that maintain a moist ulcer environment, control of exudate, and avoidance of maceration of adjacent intact skin. Adequate glycemic control is also recommended to reduce the incidence of DFU and infections in addition to periodic assessments of appropriate footwear or off-loading devices.7,9,13

Evidence-Based Guidelines for Skin Substitute Grafts/CTP

Skin substitute grafts/CTP are a heterogeneous group of biological and synthetic elements that allow the temporary or permanent occlusion of ulcers. Dermal substitutes may vary from skin xenografts or allografts to a combination of autologous keratinocytes over the dermal matrix, but all address the goal of resemblance to an individual’s skin to the greatest extent possible.13 Skin substitute grafts/CTP are considered an advanced therapy adjunctive to the established SOC treatment protocols for ulcer care to increase the chances of healing. In this regard, evidence-based guidelines recommend ulcer bed preparation prior to the application of any biologically active dressing which includes complete removal of slough, debris, and necrotic tissue.15 Skin substitute grafts may be considered in conjunction with SOC treatment for DFU that have failed to demonstrate more than 50% ulcer area reduction after a minimum of 4 weeks of standard therapy.7 For VLU, if substantial ulcer improvement is not demonstrated after a minimum of 4 weeks of standard therapy, skin substitute grafts or CTP may be considered in addition to compression therapy.4,6,9

Product Classifications

Several classification systems have been proposed to categorize products but, there is not a universally accepted classification system. The products vary widely, ranging from synthetic or natural, a variety of origins, with additives and processing impacting the final product.21 Even products derived from the same origin are variable since these products undergo proprietary processing. Skin substitute grafts/CTP may share similarities, but they are individually unique in their proprietary processing, thickness, cell count, presence of living cells and other features. In 2001 a classification system was proposed that put skin substitutes into 3 groups: Class I cultured epidermal equivalents alone, Class II dermal components which are from processed skin or have been manufactured with extracellular matrix proteins, and Class III both dermal and epidermal.22 Kumar created a classification system in 2008 which divides products into 3 classes based on temporary, single and bilayer materials and included dermal or epidural and natural or synthetic into the classification.23 The Davison-Kotler classification system was developed to classify the differences between the products based on functionality according to cellularity (acellular or cellular), layering (single or bilayer), replaced region (epidermis, dermis, or both), material used (natural, synthetic, or both), and permanence (temporary or permanent). 22 The result is products within the same class, varying significantly and impacting the product’s function indeterminately .24

Potential Harm

The potential harm of skin substitutes is challenged by lack of high-quality studies and long-term data. The risk of human-based products include infections being transmitted from the donor tissue to the recipient. Most products undergo stringent processing to reduce this risk, but bacterial and viral transmission risk remains. The duration of cells delivered and effect in the wound basement membrane is not fully understood.25 Some types of grafts are at risk of graft rejection and there is variability in cosmetic results. Adherence to underlying tissues may vary based on hydrophilic surface properties of the graft which may impact effectiveness.25 Concerns have arisen regarding specific constituent molecules within the matrix with the potential to elicit adverse responses in host tissues. The mechanism of changes in the extracellular matrix (ECM) through cell-matrix interactions and ECM remodeling is not fully understood, eliciting concern for the derived microenvironment promoting tumorigenesis, metastasis, inflammatory or autoimmune disease evolution. 26 Very few studies explore long term safety of skin substitute grafts/CTP so true risk associated with these products remains unclear.

Health Care Disparities

There is a paucity of literature addressing health care disparities in the use of skin substitutes specifically for DFU and VLU. Diabetic management is known to be impacted by social determinants of health with worse outcomes noted in minority and socioeconomically disadvantaged populations. Comprehensive care models with multidisciplinary teams have proven effective in treatment of DFU by improving access to care, access to specialist and effective and timely treatment.27 Teams include a combination of primary care, endocrinology, vascular surgeons, orthopedic surgeons, podiatrists, and wound care specialists. The literature reviewed for DFU included patients with diabetes. The majority of reviewed literature did not represent racial diversity with subjects outside the Medicare population. Future research should aim to include a diverse population representative of those impacted by the condition and include representation of the Medicare population in age distribution.

 

Agency for Healthcare Research and Quality (AHRQ) Technical Brief

The AHRQ provided an evidenced-based technical brief for skin substitute grafts for treating chronic ulcers.4 This technical brief was developed to describe assorted products that may be considered skin substitute grafts in the U.S., which are utilized for the treatment of chronic ulcers. In addition, systems utilized to classify skin substitute grafts were assessed, randomized controlled trials (RCTs) involving skin substitute grafts were reviewed, and recommendations were made regarding best practices for future studies. Search of the published literature since 2012 was conducted for systematic reviews/meta-analyses, RCTs, and prospective non-randomized comparative analysis studying commercially available skin substitute grafts for individuals with DFU, VLU, pressure ulcers, and arterial leg ulcers..

Seventy-six skin substitute grafts were identified and categorized using the Davison-Kotler classification system, a method structured according to cellularity, layering, replaced region, material used, and permanence. Of these, 68 (89%) were categorized as acellular dermal substitutes, largely replacements from human placental membranes and animal tissue sources. Acellular dermal substitutes prepared from natural biological materials are the most common commercially available skin substitute graft products for treating or managing chronic ulcers. Cellularity is a significant difference among skin substitute grafts as the presence of cells raises the rejection risk and production complexity. This category includes decellularized donated human dermis (14 products recognized), human placental membranes (28 products recognized), and animal tissue (21 products recognized). Fewer products are prepared from synthetic materials (2 products recognized) or a blend of natural and synthetic materials (two products recognized). A limited number of skin substitute products are acellular replacements for both the epidermis and dermis (one product recognized). Only 8 products were recognized that contained cells and would be classified in the cellular grouping.

Three systematic reviews and 22 RCTs studied the utilization of 16 distinct skin substitutes, comprising acellular dermal substitutes, cellular dermal substitutes, and cellular epidermal and dermal substitutes in DFU, pressure ulcers, and VLU. Twenty-one ongoing studies (all RCTs) assessed an additional nine skin substitute grafts with comparable classifications. It was noted that studies seldom reported clinical outcomes, such as amputation, ulcer recurrence at least 2 weeks after treatment ended, or patient-related outcomes, such as return to function, pain, exudate, and odor. This review found that more studies are needed to assess the effectiveness of most skin substitutes and this future research needs to be better designed and include clinically relevant outcomes.

Of the 22 included RCTs, 16 studies contrasted a skin substitute with SOC. The SOC for each ulcer type involved sharp debridement, glucose control, compression bandages for VLU, pressure redistribution support surfaces for pressure ulcers, infection control, offloading, and daily dressing changes with a moisture-retentive dressing, such as an alginate or hydrocolloid type dressing. Though 85% of the studies examining acellular dermal substitutes portrayed the experimental intervention as favorable over SOC for ulcer healing and quicker time to heal, the data is not adequate to determine whether ulcer recurrence or other sequela are less frequent with acellular dermal substitutes. Only 3 studies contrasted cellular dermal substitutes with SOC. Clinical evidence for cellular dermal substitutes may be limited by the lack of robust, well-controlled clinical trials.

Of the 6 head-to-head comparative studies, results from 5 studies did not show substantial differences between skin substitute grafts in outcomes measured at the latest follow-up (>12 weeks). One study concluding at 12 weeks described a substantial difference in ulcer healing favoring an acellular dermal skin substitute over a cellular epidermal and dermal skin substitute. Another study compared 2 acellular dermal substitutes and seemed to have deliberately underpowered 1 arm of the study as the statistical significance was not elucidated or expected for this study arm. Of the 2 studies reporting on recurrence, 1 study described comparable recurrence, while the other study reported no recurrence at 26 weeks. The current evidence base, as portrayed by the authors for the literature reviewed, may be inadequate to determine superiority of 1 skin substitute graft product over another.

The report acknowledges the potential risk of bias due to 20 of the 22 RCTs reviewed being industry sponsored. This AHRQ Technical Brief also noted that a skin substitute’s commercial availability is not a reflection of its legal status. Manufacturers self-determine whether their human cell, tissue, or cellular or tissue-based product (HCT/P) may be marketed without FDA preapproval and frequently misunderstand or mischaracterize the conditions necessary for the product to be regulated solely for communicable disease risk. The Code of Federal Regulations 21 CFR 1271.10(a) is referenced;. FDA Announces Comprehensive Regenerative Medicine Policy Framework was cited.14

Systemic Review and Meta-Analysis

Santema et al.28 provided a systematic review and meta-analysis to assess the efficiency of skin substitute grafts utilized for the treatment of DFU regarding ulcer healing and limb salvage. Using the Cochrane Collaboration methodology, 17 clinical trials were identified, which included a total of 1,655 randomized study participants with DFU. The number of study participants per clinical trial ranged from 23 to 314. Fourteen studies included chronic or difficult to heal ulcers that were present for a minimum of 2, 4, or 6 weeks.

Skin substitute grafts were contrasted with SOC in 13 trials. The results collectively demonstrated that SOC treatment, combined with a skin substitute product enhanced the chances of attaining complete ulcer closure in contrast to SOC alone after 6 to 16 weeks (risk ratio [RR] 1.55, 95% confidence interval [CI] 1.30 to 1.85, low quality of evidence). Apligraf/Graftskin, Epifix, and Hyalograft 3D were the only individual products that demonstrated a statistically substantial beneficial effect on complete ulcer closure (i.e., full epithelialization without any evidence of drainage or bleeding). Four clinical trials contrasted 2 different types of skin substitutes, although no product demonstrated a greater effect over another. Sixteen of the trials evaluated the efficacy of a bioengineered skin substitute. Only 1 trial evaluated the efficacy of a non-bioengineered skin graft.

The total occurrence of lower limb amputations was only reported for 2 trials and the results for these 2 trials collectively produced a substantially lower amputation rate for individuals treated with skin substitute grafts (RR 0.42 95% CI 0.23 to 0.81), though the absolute risk difference (RD) was small (-0.06, 95% CI -0.10 to -0.01, very low quality of evidence). Of the included studies, 16 reported on adverse events (AEs) in diverse ways, although there were no reports of a substantial difference in the incidence of AEs between the intervention and the control group. Additionally, support of long-term effectiveness is lacking, and cost-effectiveness is unclear. Noted limitations included a variable risk of bias among the studies, the lack of blinding (i.e., study participants and investigators knew which patients were receiving the experimental therapy and which patients were receiving the standard therapy), and 15 of the studies conveyed industry involvement; the majority did not indicate if the industry applied any limitations regarding data analysis or publication.28

Jones et al.29 systematic literature review sought to evaluate the effect of skin substitute grafts for the treatment of VLU. Using the Cochrane Collaboration methodology, one new trial was identified, generating a total of 17 RCTs, which included a total of 1,034 study participants. The studies were comprised of participants of any age, in any care setting with VLU. Given that the process for diagnosis of venous ulceration differed between studies, a standard definition was not applied. The trials also involved study participants with arterial, mixed, neuropathic, and diabetic ulcers provided that the outcomes for patients with venous ulcers were conveyed separately. To be included in the review, trials also had to report at least one of the primary outcomes objective measures of healing, e.g., relative or absolute rate of change in ulcer area, time for complete healing, or proportion of ulcers healed within the trial period.

Eleven studies contrasted a graft with SOC. Two of these studies (102 patients) contrasted an autograft with a dressing, 3 studies (80 patients) contrasted a frozen allograft with a dressing, and 2 studies (45 patients) contrasted a fresh allograft with a dressing. Two studies (345 patients) contrasted a tissue-engineered skin (bilayer artificial skin) with a dressing. In 2 studies (97 patients) a single-layer dermal replacement was compared with SOC.

Six studies compare alternative skin grafting techniques. The first study (92 patients) differentiated an autograft with a frozen allograft; a second study (51 patients) contrasted a pinch graft (autograft) with a porcine dermis (xenograft); the third study (110 patients) compared growth-arrested human keratinocytes and fibroblasts with a placebo; the fourth study (10 patients) analyzed an autograft delivered on porcine pads with an autograft delivered on porcine gelatin microbeads; the fifth study (92 patients) contrasted a meshed graft with a cultured keratinocyte autograft; and the sixth study (50 patients) contrasted a frozen keratinocyte allograft with a lyophilized (freeze-dried) keratinocyte allograft.

Overall, the results show that substantially more ulcers healed when treated with bilayer artificial skin than with dressings. There was inadequate evidence from the other trials to establish whether other types of skin grafting improved the healing of venous ulcers. The authors concluded that bilayer artificial skin, used together with compression bandaging, improves venous ulcer healing as compared to a simple dressing plus compression.

It was noted that the overall quality of the studies reviewed was poor, thus affecting the risk of inherent bias. Many studies did not have inclusion criteria or insufficient information regarding randomization techniques. In addition, withdrawals and AEs were inadequately reported. Deficient data regarding withdrawals and the inclination to perform per-protocol analyses rather than intention-to-treat (ITT) analyses signify that the outcomes in the original study documentation may be biased.29

A 2017 meta-analysis of RCT comparing amniotic tissue products to SOC in nonhealing DFU was conducted. PubMed, Cochrane Central Register of Controlled Trials, and the Cochrane Database of Systematic Reviews search identified 596 potentially relevant articles of which 5 met the selection criteria. The pooled set included 259 patients and the pooled relative risk of healing with amniotic products compared with control was 2.7496 (2.05725–3.66524, p< 0.001). The products included in this analysis were Amnioexcel, Epifix, and Grafix. Four trials changed the amniotic product weekly; 1 paper reported an average of 2.5 applications of Epifix, and in 1 study where reapplication was at the discretion of the clinician, no decrease in healing was found compared to the per protocol application changes. The author concludes that there is benefit in healing rates of amniotic products for DFU and if this impacts other outcomes and subsequent complications such as amputation and death, further investigation will be required.30

A 2020 systematic review/meta-analysis reported on complete healing rates for DFU with acellular matrix.31 Nine RCT with 897 patients were included. They report those treated with an acellular matrix had higher healing rates at 12 weeks (risk ratio [RR] =1:73, 95% confidence interval [ CI[: 1.31 to 2.30) and 16 weeks (RR = 1:56, 95% CI: 1.28 to 1.91), a shorter time to complete healing (mean difference [ MD] = −2:41; 95% CI: -3.49 to -1.32), and fewer AEs (RR = 0:64, 95% CI: 0.44 to 0.93) compared to SOC. RCTs include Graftjacket, Oasis ultra matrix, DermACELL, Integra and AlloPatch. The heterogenicity reported varies depending on the outcome measures but the analysis is limited by high variety in wound types, differing products and number of applications, variations in SOC in control arms, different durations of treatment and risk of bias in the included studies.

A 2017 systematic review and meta-analysis identified 6 RCT comparing acellular dermal matrix (ADM) to SOC for DFU. Different commercial products of ADM were included in this meta-analysis, including DermACELL, Graftjacket, Integra Dermal Regeneration Template (IDRT), and human reticular acellular dermis matrix (HR-ADM). The pooled group included a total of 632 DFU patients and sample size of the studies ranged from 14-154 for a duration of 4-16 weeks. Studies were pooled and analyzed (with and without the study that only extended to four weeks) and concluded that complete healing rate in the ADM group was higher than SOC [risk ratio (RR) 2.31, 95% confidence interval (CI) 1.42 to 3.76 I2=74% which is 2.31 times more likely for complete wound healing than SOC at 12 weeks. The authors rated the strength of evidence as moderate and acknowledge the limitation related to lack of blinding. This meta-analysis is limited by risk of publication bias, lack of uniform ADM the products, variation in dressing products and potential variation within SOC, different application number amongst the different studies, small samples of individual studies, short term follow up, and fairly high heterogeneity within some outcome measures leading to the authors call for more robust studies.32

A 2012 systematic review of RCTs evaluating wound closure rates for patients treated with advanced wound matrix compared to SOC for VLU was conducted.33 One RCT was found for three products Apligraf [n = 130 treatment, n = 110 control]; Oasis Wound Matrix [n = 62 treatment, n = 58 control]; and Talymed [n = 22 treatment, n = 20 control]. In the Talymed study 62 patients in the treatment arm with varying applications frequency reported statistically significant closure rate compared to SOC, but this was only found in 1 of the 3 arms (biweekly application group). Risk of bias assessment was not conducted, but they reference the AHRQ report4 which reported higher degree of bias for the Apligraf and Oasis studies that were included due to lack of blinding. Limitations of this report include variations in assessment period across the studies, baseline wound characteristics were not compared, and only one arm of the Talymed study was included with a sample size too small to determine effect.

Systematic reviews for skin substitute graft/CTP are challenged by multiple factors. These reviews pool different products with different features, types of wounds, baseline health factors, duration of treatment, number of applications and variations in SOC creating significant factor variance. Even within the same study variability in SOC and managements are not clearly defined. Most included studies have notable risk of bias, small sample sizes, and short-term follow-up resulting in overall low-quality literature. The systematic reviews are limited by the quality of the included studies and heterogeneity between studies so even with positive outcomes, there is a lack certainty that the effect is due to the skin substitute/CPT itself.

Clinical Trials for Skin Substitute Grafts or CTP for Diabetic Foot Ulcers

Affinity

A multi centered, RCT was conducted across 14 centers to assess the clinical outcomes of hypothermically stored amniotic membrane (HSAM) versus SOC for DFU. After a 2-week screening phase, 76 participants were randomized with random allocation sequence to either Affinity or SOC and followed for 16 weeks. Wound measurements were validated with an Aranz laser-assisted wound measurement device. Product was changed weekly or until the ulcer healed. Wound closure for Affinity-treated ulcers (n=38) was significantly greater than SOC (n=38) by 12 weeks (55 vs 29%; p = 0.02) and 16 weeks (58 vs 29%; p = 0.01) respectively.34 Strengths of the study include the randomization, screening and follow-up phase, comparison to SOC, adequately powered, the use of multi-centered sites and an overall low risk of bias. Limitations include lack of blinding, and short-term follow-up. This study also addresses a population with complex wounds extending into the muscle or tendon which is a particularly difficult population to treat. Additional studies include a basic science report exploring the mechanism of how the product may work35, and a case report and series.

 

AlloPatch/Flex HD/AllopathHD/Matrix HD

Zelen et al.36 performed a RCT to evaluate the healing rates, safety, and cost using an open-structure human reticular acellular dermal matrix (HR-ADM) (i.e., AlloPatch® PliableTM) plus SOC to SOC alone for DFU. A total of 40 subjects were randomized to HR-ADM plus SOC (n = 20) (AlloPatch applications weekly) or SOC alone (n = 20). The primary outcome of this study focused on a comparison of ulcer healing at 6 weeks between these 2 groups. Wounds were considered as healed if there was complete (100%) re-epithelization with no drainage and no need for dressing. At 12 weeks, 80% (16/20) of the AlloPatch-treated ulcers had healed contrasted with 20% (4/20) of the ulcers treated with SOC alone (p=0.00036). The mean time to heal within 12 weeks was 40 days (95% CI: 27–52 days) for the AlloPatch versus 77 days (95% CI: 70–84 days) for the SOC group (p=0.00014). The average number of AlloPatch grafts used to achieve closure per ulcer was 4.7 (SD=3.3) at 12 weeks. There was no occurrence of increased AEs or SAEs between groups, or any AEs related to the graft. This study concluded that the use of AlloPatch plus SOC is more effective in the treatment of DFU than with SOC alone. However, this study had high risk of bias due to missing outcome data and was also limited by short-term follow-up, and small sample size. The authors also followed the patients that failed SOC arm and were eligible for cross-over treatment in a retrospective format. Twelve patients received the allograft and 83% achieved complete wound healing with mean time of 21 days to closure.37 Due to the retrospective study design it is not clear if the wounds would have closed with continued SOC during this timeframe.

Literature was also found in breast reconstruction, rotator cuff repair, hernia repair, and lab research38-40

Amnioband

Glat et al.41 conducted a RCT to contrast a dehydrated human amnion and chorion allograft (dHACA) (i.e., AmnioBand) with SOC and a tissue-engineered skin substitute (TESS) (i.e., Apligraf) with SOC in the treatment of DFU. At the 12-week assessment, it was found the mean time to healing was 32 days. (95% CI, 22.3–41.0) for the AmnioBand group versus 63 days (95% CI, 54.1–72.6) for the Apligraf group. The healing rate at 12 weeks was 90% (27/30) for the AmnioBand group versus 40% (12/30) for the Apligraf group. Limitations noted for this study include lack of blinding, short-term follow-up, and high risk of bias.41

DiDomenico et al.42 conducted a prospective, RCT to compare a dehydrated human amnion and chorion allograft (dHACA) (i.e., AmnioBand) used with SOC to SOC alone in the treatment of DFU for up to 12 weeks. At 6 weeks, 70% (14/20) of the DFU in the AmnioBand group achieved healing compared to 15% (3/20) of the DFU in the SOC group. At 12 weeks, 85% (17/20) of the DFU in the AmnioBand group healed compared with 25% (5/20) in the SOC group (mean time to heal of 36 and 70 days, respectively). At 12 weeks, the average number of grafts used per healed wound for the AmnioBand group was 3.8 ± SD 2.2 (median 3.0). All analyses used the ITT approach, and the risk of bias was low. Limitations were short-term follow-up and lack of blinding.42

DiDomenico et al.43 performed a RCT to compare a dehydrated human amnion and chorion allograft (dHACA) (i.e., AmnioBand) used with SOC to SOC alone in the treatment of DFU for up to 12 weeks. Eighty patients participated in the study: 40 patients in the AmnioBand group and 40 patients in the SOC group. The AmnioBand was applied weekly during the study period until healing occurred (complete epithelialization without drainage), the patient was withdrawn, or the study was completed. At six weeks, 68% (27/40) of the DFU in the AmnioBand group achieved healing contrasted to 20% (8/40) of the DFU in the SOC group (p=1.9 × 10−5). At 12 weeks, 85% (34/40) of the DFU in the AmnioBand group achieved healing compared with 33% (13/40) of the DFU in the SOC group. The average time to heal within 12 weeks was substantially quicker for the AmnioBand group contrasted with the SOC group, 37 days versus 67 days in the SOC group (p=0.000006). The average number of grafts used per healed wound during the same time was 4.0 (SD: 2.56) at 12 weeks. All analyses used the ITT approach, and the risk of bias was low. Limitations include lack of blinding, and short-term follow up.

Amnioband is also reviewed in the VLU section.

Amnioexcel

Snyder et al.44 performed a multi-center RCT for assessment of a dehydrated amniotic membrane allograft (DAMA) (i.e., Amnioexcel) with SOC (n=15) in comparison to SOC alone (n=14) for chronic DFU for 6 weeks. The Amnioexcel with SOC group wounds were debrided, Amnioexcel applied, covered with non-adherent dressings, lightly secured, and wrapped with a compression dressing. Patients in the Amnioexcel with SOC group had a total of 4.3 + 1.7 allografts applied; Frequency of the application was left to individual provider. Results showed that 33% of patients in the Amnioexcel with SOC group achieved complete wound closure at or before week 6, compared with 0% of the SOC alone group (ITT population, p=0.017). The per protocol population showed 45.5% of patients in the Amnioexcel with SOC group achieved complete wound closure, while 0% of SOC-alone patients achieved complete closure (p=0.0083). Limitations of this study included 4 early withdrawals leaving only 25 patients in the final cohort, small sample size, lack of blinding, and high risk of bias due to stratification of wound type prior to randomization, per-protocol reporting only without intention to treat analysis, and lack of validation of outcome measurements. The authors call for the need for additional studies which are necessary to confirm if the findings were related to the allograft and longer-term follow-up.44

Apligraf (formerly GraftSkin)

A prospective RCT was comprised of patients with DFU. A total of 208 patients from 24 sites were randomly assigned into either the Apligraf® (formerly Graftskin®) (n=112 patients) or SOC (n=96 patients) group and followed for 12 weeks. Complete wound healing was reported in 56% of Graftskin patients compared to 38% of the control group. Authors report Graftskin time to complete closure was significantly lower than the SOC group(p=0.0026). Fourty-four patients withdrew from the study before study completion. Average applications of Graftskin per patient were 3.9 (range 1-5) for the duration of the study. The average number of applications of 3.9 (range 1-5) with 1 application [n=10]), 2 applications [n=11], 3 applications [n=15], 4 applications [n=17] and 5 applications [n=59]) used per patient over 12 weeks. Ulcer recurrence was 5.9% in the Graftskin group and 12.9% in the control group at 6 month follow up. Limitations include high risk of bias, moderate number of patients lost to follow up, and additional dressing changes allowed in both groups if ulcer was not healed by week 5.45

A prospective, multicenter, open-label RCT compared Apligraf plus SOC to SOC alone in DFU patients in the European Union (EU) and Australia to a similar study in the U.S. The EU and Australian studies were comparable and data from both studies were pooled. The EU and Australian studies were comprised of 72 patients, 33 in the Apligraf group and 29 in SOC group and the U.S. study was compromised of 208 patients: 112 in Apligraf group and 96 in the control group. The mean ulcer duration was significantly longer in the EU and Australian study (21 months) compared to 10 months in the U.S. Adverse events were reported for 12 weeks in both studies and were comparable and not related to the graft. At 12 weeks, combining the data from both studies, 55.2% of the Apligraf group achieved wound closure as compared to 34.3% in SOC arm (P = 0.0005; Fishers exact test), and Apligraf subjects had a significantly shorter time to complete wound closure (P = 0.0004; log-rank test). Limitations include premature study closure (non-safety related) for the EU and Australian studies which were underpowered due to halting study enrollment. Due to pooling of 2 different studies, it was difficult to assess risk of bias of the individual studies.46

An international multi-center, RCT was conducted in patients with DFU. This study was halted due to “registration process difficulties”. A total of 82 patients were randomized into the Apligraf group + SOC (n=33) and SOC alone (n=39). At 12 weeks, wound closure in the Apligraf group (n=33) was 51.5% as compared to 26.3% in the SOC group (n=38). The Apligraf group achieved complete wound healing over a shorter duration as compared to the SOC group (p=0.059, Log-rank test). The Apligraf group took a median of 84 days to heal compared to no median reported in the SOC group due to less than 50% achieving wound closure. An average of 1.8 Apligraf applications over 12 weeks were utilized. Limitations include no median time to heal in the SOC group, halting of the study, and lack of blinding.47

Additional evidence of Apligraf is reviewed in the following sections Amnioband41, Epifix48, Theraskin, and retrospective study(n=226)49 and in the VLU section. In the Kirsner et al. study the average number of applications over 4 weeks was 3.5 for EpiFix and 2.5 for Apligraf.49

Artacent

Sledge et al.50 performed an observational study which included 26 patients with DFU (4.65±4.89cm2) with failure to heal by >50% after 2 to 4 weeks of SOC treatment and randomized to a larger clinical trial that had been discontinued for logistical reasons. Patients were randomized to weekly or biweekly applications of dual layer amniotic membrane plus SOC for 12 weeks. A total of 17/26 (65%) achieved complete closure. The small sample size precluded meaningful comparison between the weekly and biweekly applications. Limitations of the study include risk of bias, observational design, lack of control group, variability in length of SOC treatment, small sample size, and inability to determine if healing was impacted by the product, as well as frequency of product applications or other factors. The evidence was not sufficient to determine if the product was effective for treatment of DFU.

Biovance

An observational study included 179 chronic wounds of which 47 were DFU. Twenty-eight ulcers studied had failed 32 previous treatments with 1 or more advanced biologic treatments and 48.4% of these showed improvement after treatment with Biovance within an average of 8 weeks. For all wound types (n=166) the closure rate was 41.6% within 8 weeks with mean application of 2.12 products.51 The study was limited by not reporting wound reduction size, outcomes for wound types were not reported separately and small sample size, lack of randomization, blinding or controls. Without a control group, the percentage of wounds that would have healed with SOC is unknown. Additional evidence includes a case series with 14 subjects.52 Evidence was not sufficient to determine the efficacy of this product for wound healing.

DermACELL

A multi-centered, RCT compared healing rates with a human acellular dermal matrix (DermACELL) (n=53), SOC (n=56) and a second acellular dermal matrix (Graftjacket) (n=23) for full thickness DFU. One to 2 applications of the graft were applied at the discretion of the Investigator for 16 weeks. The DermACELL arm had a significantly higher proportion of completely healed ulcers than the SOC arm (67.9% vs 48.1%; p=0.0385) and a nonsignificant higher proportion than the Graftjacket arm (67.9% vs 47.8%; p= 0.1149). There were no serious AEs related to the graft reported.53 This same study population was reported by Cazzell et al. after subjects were followed for 24 weeks.54 These 2 studies were published in 2 different journals but share authors and data sets are identical, so it appears to be the same study population. The DermACELL group had a significantly higher healing rate over SOC at 16 and 24 weeks which was not found in the Graftjacket group. Closed ulcers in the single application DermaACELL arm remained healed at a significantly greater rate than the conventional care arm at 4 weeks post termination (100% vs. 86.7%; p =0.0435). Strength of the studies include randomization, consistent diagnostic criteria with the same type of ulcers and 24-week follow-up.54 Limitations of the study include variation in SOC, lack of blinding, short-term follow-up, randomization methodology was not reported, and some concerns of risk of bias.

A prospective single arm, multicentered trial included 61 participants with large and complex DFU, with the average size 29.0 cm2 and, 59/61 had exposed bone. Participants received treatment with acellular dermal matrix allograft (DermACELL). Up to 1 additional application was allowed if the wound required further coverage for exposed deep tissue, was less than 75% granulated at 4 weeks or less than 50% granulated after 8 weeks. Wound measurements were validated with a laser measurement device. Fourteen participants did not complete the 16 weeks of which 8 required surgical intervention for their targeted wound, but there were no AEs related to the allograft. The authors report 100% granulation and 31.9% closure by 16 weeks in the per protocol group with 9 receiving a second application with an average of 1.2 applications. In the intention to treat group 90.2% achieved granulation and 24.6% closure by 16 weeks with an average of 1.2 applications. The study did not extend past 16 weeks, but it was postulated that many of the wounds not healed would continue healing if allowed additional time. This underscores the challenges in this difficult population of large ulcers extending to bone.55 This study is limited by lack of control arm or randomization, short term follow up, and small sample size.

Additional studies are in the form of case reports and series. Breast reconstruction and burns were not reviewed in this analysis.

Dermagraft

A RCT study at 35 centers enrolled 314 patients and reported on 245 with chronic DFU. Patients meeting the inclusion criteria were matched and randomized to Dermagraft or SOC. Subjects received up to 7 additional applications at weekly intervals over the course of the study. The authors reported complete wound closure in 30% (39/130) in the Dermagraft group as compared to 18.3% (21/115) in the SOC group at week 12. They reported similar AEs in both groups with fewer ulcer related AEs in the Dermagraft group.56 The study is limited by concerns for risk of bias, and short term follow-up.

In 1996 a multi-centered RCT with 50 subjects was conducted comparing Dermagraft at 3 different doses to SOC for DFUs over a 12-week period. Treatment groups included weekly application of one piece of Dermagraft for a total of 8 applications (Group A [n=12]), application of 2 pieces of Dermagraft every 2 weeks for a total of 8 (Group B [n=14]), application of 1 piece of graft every 2 weeks for a total of 4 (Group C [n=11]), and SOC alone (Group D [n=13]). The authors noted that Group A demonstrated statistically significant wound healing (p=0.017) by 12 weeks with a 50% closure rate compared to 50%, 18.2% and 23.1% closure rates for groups B, C, and D respectively. 57 This study is limited by small sample size, short-term follow-up, lack of blinding, and risk of bias.

Dermagraft was reported in a RCT comparing Dermagraft to Theraskin for DFU58 (see Theraskin section). Dermagraft is also reviewed in the VLU section.

Epicord

Tettelbach et al.59 performed a multi-center, RCT, to compare dehydrated human umbilical cord (i.e., EpiCord) with SOC to treat chronic DFU. A total of 155 patients were treated and included in the ITT analysis: 101 in the EpiCord group and 54 in the SOC group. T healing rate at 12 weeks was 70% (71/101) for the EpiCord group and 48% (26/54) in the SOC group (p=0.0089). The median number of EpiCord allografts applied was 7 (range 2-12). Strengths of this study include a control group (alginate), larger sample size and low risk of bias. Limitations of the study include lack of blinding, and short-term follow-up.

Epicord was also included in a systematic review in which the authors conclude biological skin substitutes were 1.67 times more likely to heal by 12 weeks than SOC dressings (p<0.00001). They also state that further studies are needed to determine the benefits of the different products and the long-term implications of these products.60

EpiFix

A RCT aimed to investigate wound healing for DFU with Epifix compared to SOC. Twenty-five subjects were randomized to EpiFix with replacement of the product every 2 weeks or SOC and followed for 6 weeks. The authors report wound healing in 92% of the EpiFix group and 8% of the SOC group. “The EpiFix material, placed on an every other week regimen, aggressively closed the wounds under consideration in a far shorter time than standard wound treatment.”61 Sample size was too small to draw conclusions based upon these results and the study was challenged by lack of blinding and high risk of bias. The outcomes in the SOC arm were concerning because the results were well below those reported by other studies for SOC treatment. In addition, the protocol SOC was not defined in the paper.

A 2016 multi-center RCT with 100 participants compared dehydrated human/amnion/chorion membrane (dHACM) (i.e.,EpiFix®) to SOC and bioengineered skin substitute (Apligraf®), concluding that dHACM was superior in achieving complete wound closure within 4–6 weeks. The proportion of wounds achieving complete closure within the 12-week study period were 73% (24/33), 97% (31/32), and 51% (18/35) for Apligraf, EpiFix and SOC, respectively (adjusted p=0.00019). Mean time-to-heal was 47.9 days (95% CI: 38.2–57.7) with Apligraf, 23.6 days (95% CI: 17.0–30.2) with EpiFix group and 57.4 days (95%CI: 48.2–66.6) with the SOC only group (adjusted p=3.2x 10.7). Median number of grafts used per healed wound were six (range 1–13) and 2⋅5 (range 1–12) for the Apligraf and EpiFix groups. The study was limited by small sample size, lack of blinding and high risk of bias.48

A multi-centered RCT which included 110 patients with DFU was undertaken to determine whether EpiFix led to improved wound healing compared to SOC. Both ITT and per-protocol participants receiving weekly EpiFix (n=47) were significantly more likely to completely heal than those not receiving EpiFix (n=51), ITT was 70% versus 50%, p=0.0338, per-protocol was 81% versus 55%, p = 0.0093).62 The study had a low risk of bias. Limitations included the short term follow up, and lack of blinding.

EpiFix was included in multiple systematic reviews and meta-analysis. The AHRQ report4, Cochrane Systematic Review30 and Paggiaro systematic review.63 There is also a NICE innovation briefing on EpiFix.64 Additional literature includes case series, lab studies and additional studies in the VLU population reviewed in that section below.

A prospective RCT was performed to compare weekly applications of Apligraf (n=20), EpiFix (n=20), or SOC (n=20) effectiveness in DFU. Three sites and 65 subjects entered the 2-week run-in period while 60 were randomized to each treatment group. Wound closure was as follows for 4 and 6 week follow up: EpiFix (85% and 95%), Apligraf (35% and 45%), and SOC (30% and 35%). The mean number of applications used in the Apligraf group was 6.2 per patient and 2.15 for EpiFix in 6 weeks. All EpiFix patients exited the study by the 6 week follow up while 20% of the Apligraf patients remained unhealed at 12 weeks. Limitations include that the study was inadequately powered to reach statistical significance between Apligraf and SOC group at 6 weeks, short duration of follow up after patient healing period, and the lack of comparison of 12-week healing rates due to missing outcome data which created a high risk of bias.65

Grafix

Lavery et al.66 performed an RCT to contrast the effectiveness of a human viable wound matrix (hVWM) (i.e., Grafix®) to SOC for ulcer closure in chronic DFU. Patients in the active treatment group received SOC plus an application of Grafix once a week (± 3 days) for up to 84 days (blinded treatment phase) and the control group received SOC ulcer therapy once a week (± 3 days) for up to 84 days. The percentage of patients who attained complete ulcer closure was substantially higher in the active treatment group (62%) compared with the control group (21%, p=0.0001). The median time for healing was 42 days in the active treatment arm contrasted with 69.5 days in the control arm (p=0.019). There were less AEs in the active arm (44% versus 66%, p=0.031) and less ulcer-related infections (18% versus 36.2%, p=0.044). The authors concluded that treatment with Grafix substantially improved DFU healing in comparison to SOC therapy. Limitations of the study included lack of blinding, short-term follow-up, and high risk of bias.

Additional literature includes a retrospective report of 441 wounds from a healthcare database to evaluate the proportion of DFU that achieved complete closure with viable cryopreserved placental membranes (vCPM) (Grafix PRIME and Grafix CORE) as compared to standard wound care by 12 weeks and the number of wound related infections and amputations. They reported closure in 59.4% of 350 wounds with the median treatment duration of 42 days and a median of 4 applications (95% CI 4-5) of vCPM with a 3% rate of amputation and an incidence of 2% for infections. Smaller wounds were quicker to heal. There was no comparison to wounds that did not have vCPM applied. Limitations of the study include its retrospective nature, lack of standardized treatment practices, no comparator group, lack of a control cohort, risk of incomplete records, and variabilities in evaluations.67

Grafix CORE

Frykberg et al.68 conducted a prospective, multicentered, open labeled single arm RCT using vCPM (Grafix CORE®, Osiris Therapeutics, Inc) in 31 complex DFU with exposed deep structures. The wounds were cleaned and debrided weekly with weekly application of vCPM and protective foam dressings. Fifty-nine percent achieved complete wound closure by 16 weeks. These data show that vCPM is a safe and effective option for the successful management of complex wounds with exposed tendon and bone. As vCPM was not combined with other advanced modalities (i.e. NPWT) during the course of treatment in this study, it would be of interest in the future to investigate the cumulative benefits of vCPM as part of a multimodal approach to complex wounds with exposure of deep structures or bone. This study was limited by a lack of comparison to standard wound care, no disclosure of funding sources suggesting higher potential risk of bias and high dropout rate given the small number of patients enrolled. Evidence was not sufficient to determine the efficacy of this product for wound healing.

Graftjacket

A pilot study was conducted to evaluate the potential role of Graftjacket in ulcer management with 40 subjects comparing Graftjacket to gauze dressings with a suggested potential role in ulcer management. Rates of healing were reported as decrease in wound area by 67.4% in the Graftjacket group compared to 34% in the SOC group at 4 weeks.69 A second RCT study was conducted to evaluate the effectiveness of Graftjacket for chronic non-healing lower extremity wounds. Subjects received a single application of Graftjacket (n=14) compared to controls treated with gauze dressings (n=14) and followed for 16 weeks. A total of 85.71% of the treatment group ulcers were healed compared to 28.57% of the control group at the conclusion of the study (p=0.006).70 Limitations of both studies included a small sample size and high risk of bias.

A multi centered RCT compared subjects with DFU receiving acellular matrix (Graftjacket Regenerative Tissue Matrix) (n=47) to SOC (n=39). The authors reported a complete healing time of 69.6% at 5.7 weeks for the treatment group compared to 46.2% at 6.8 weeks for the control group. The proportion of healed ulcers between the groups was statistically significant (p= 0.0289) with odds of healing 2.7 times higher in the study group than the SOC group. Subjects received a single application and were followed to 12 weeks. Six adverse events were reported but not related to the graft except in one case where the graft was no longer on the wound.71 Strengths of the study include randomization and defined control group with certain limitations noted such as a short term follow up and high risk of bias.

These 3 studies were pooled in a meta-analysis (n=154) comparing Graftjacket to SOC and reported a statistically significant reduction in ulcer size in 1.7 weeks and a fourfold improvement in the chance of healing in the Graftjacket group. The authors conclude that a single application of this product after sharp debridement and offloading may improve healing for DFU and the model used predicted an average of 1.7 weeks reduction in healing time with this approach. The median number of applications per patient, after initial application, was 1 (range 1-15). There were differences in outcome measures in the 3 studies challenging the pooled results. Limitations include high risk of bias including publication and reporting biases, study selection biases, incomplete data selection, and a high risk of bias, due to small sample sizes and differences in endpoints. 72

Additional studies include two RCT in which Graftjacket was compared to DermACELL and SOC, but with only 23 subjects in Graftjacket arm, the study was not sufficiently powered to draw conclusions.54 Other investigations (see section on DermACELL), include a Cochrane review analysis28 and multiple studies investigating the role of the product in tendon repair and breast reconstruction.

Integra

Driver et al. conducted The Foot Ulcer New Dermal Replacement Study (FOUNDER), a RCT with 153 patients in the control arm who received SOC treatment and 154 patients in the active treatment arm received Integra Dermal Regeneration Matrix for DFU. Both groups underwent 14-day run-in periods where they received SOC treatment and eligible patients were randomized with software algorithm and ulcers were measured at onset. Complete closure of the ulcer at 16 weeks was significantly greater in the active group (51%; 79/154) in comparison to the control group (32%; 49/153, p=0.001). There were no significant adverse events in either group.73 Strength of the study included the randomized design, large sample size, control group, multi-centered, run-in period, set wound type and inclusions/exclusion criteria. Limitations of the study include lack of double blinding, the short- term follow-up and high risk of bias.

A prospective pilot study evaluated 10 patients treated with Integra bilayer wound matrix for DFU. The authors report 70% (7/10) achieved complete wound healing by 12 weeks.74 This study is limited by study design, very small sample size and short-term follow-up. Additional literature includes case reports, series and retrospective reviews.

Kerecis Omega3

A double blinded RCT compared fish skin allograft (Kerecis Omega3 Wound) to dehydrated human amnion/chorion membrane allograft (EpiFix) for induced wounds. Subjects (n=170) received punch biopsies and the graft was placed over the induced wound. The subject and assessor were blinded to the treatment group. Wounds treated with fish skin healed significantly faster (hazard ratio 2.37; 95% confidence interval: (1.75–3.21; p = 0.0014) compared with wounds treated with EpiFix over a 28-day period. The average was 1.6 applications per subject for the Kerecis Omega3 wound and 1.4 applications for Epifix.75 This was a high-quality study, but the results were not applicable to chronic non-healing wounds.

A multi-centered RCT compared fish skin allograft (Kerecis Omega Wound) + SOC to SOC alone in 49 patients with chronic DFU after a 2-week screening period. At 12 weeks, 16 of 24 patients' DFU (67%) in the fish skin arm were completely closed, compared with 8 of 25 patients' DFU (32%) in the SOC arm (p =0.0152 [N = 49]; significant at p<0 .047). The median number of applications to achieve closure was 5 (in arm 1).76 Limitations include high risk of bias due to missing outcome date, small sample size and short-term follow-up period.

Additional literature includes review papers. Seth et al. summarizes case reports, case series and retrospective studies, and noted that additional RCTs are ongoing.77,78 This evidence is insufficient to validate net positive outcomes for DFU or VLU.

MatriStem

A multi centered observational study was conducted at 13 US centers and included 56 subjects comparing MatriStem MicroMatrix (MSMM) and MatriStem Wound Matrix (MSWM) (porcine-derived) (n=27) to ulcers treated with Dermagraft (n=29) for DFU. The matrix was applied weekly until wound closure or 1 application per week without wound closure whichever came first to a maximum of 8 applications. Subjects were followed for 6 months for ulcer recurrence with one recurrence in both groups. There were no statistically significant differences between the 2 groups in the following: complete wound closure at day 56 (p=0.244), change in wound size over eight-week treatment period (p=0.762); complete wound closure at day 70 (p=0.768); or mean time to closure (p=0.523).8 This study's strength includes the multicentered sites and following subjects for 6 months for recurrence, but only 10 subjects were followed for this duration. The small sample size is not sufficient to determine efficacy of this product for wound healing.

Microlyte matrix

Manning et al.79 performed an open-label, prospective pilot study to evaluate a bioresorbable polymeric matrix infused with ionic and metallic silver (i.e., Microlyte matrix) as a primary wound contact dressing in the treatment of 32 patients (median age of 62 years) with a total of 35 hard-to-heal wounds along with SOC. The wounds encompassed venous stasis ulcers, DFU, postoperative surgical wounds, burn wounds, and chronic, non-pressure lower extremity ulcers unresponsive to standard protocols of care. Of the 35 chronic wounds, the majority consisted of venous stasis ulcers (54%) (19/35), followed by DFU (23%; 8/35). The mean wound surface area at the start of the study was 6.7 cm2 (range 0.1 cm2 – 33 cm2); the median wound surface area was 2.1 cm2. These wounds were considered as nonhealing for a median of 39 weeks (range, 3-137 weeks) and suspected to have persistent microbial colonization that had not responded to standard antimicrobial products and antibiotics.

The micrometer-thick bioresorbable matrix conforms closely to the underlying wound bed to exert localized and sustained antimicrobial action of noncytotoxic levels of silver. The matrix was applied to the wounds once every 3 days to provide a scaffold for uniform loading of silver nanoparticles and a template for cells migration and then covered with a secondary dressing. Any residual matrix still in the wound was not removed due to the bioresorbable nature of the matrix. Three patients were lost to follow-up after initial application. At three weeks, 72% of wounds (22/32) had an average wound area reduction of 66%. Of the 16 venous stasis ulcers, 11 improved by an average healing rate of 60%, and 6 of 8 DFU improved by an average wound area reduction of 79%. At the 3-week assessment, the burn wound, and postoperative wounds had an average wound area reduction of 38% and 58%, respectively. By 12 weeks, 91% of wounds (29/32) either healed completely (i.e., fully re-epithelialized) or improved substantially with an average wound area reduction of 73%. The venous stasis ulcers and DFU had an average wound area reduction greater than 75%, with visual signs of healthy granulation tissue formation and re-epithelialization. The study had certain limitations which included a small sample size, and use of the same clinical investigator who performed all assessments during the study.79 There was not sufficient evidence to determine the efficacy of this product for wound healing.

Mirragen

There has been interest in bioactive glass as a pathway to wound healing due to postulated ability to release ions that can stimulate processes, such as hemostasis, antibacterial efficacy, epithelial cell migration, angiogenesis, and fibroblastic cell proliferation.80 A literature review of bioactive glass applications introduced the potential of this product and called for further research to understand the clinical role.81,82 A randomized trial was conducted to evaluate a unique resorbable glass microfiber matrix (Mirragen; Advanced Wound Matrix) compared to SOC for 12 weeks. All patients received standard diabetic wound care and 20 were treated with the matrix while the others received SOC only. The primary endpoint was non-infected wound healing at 12 weeks. The authors report that in the intent-to-treat analysis results at 12 weeks showed that 70% (14/20) of the Mirragen-treated DFU healed compared with 25% (5/20) treated with SOC alone (adjusted p = 0.006).83 Strengths of the study include robust design, randomization, ITT analysis, and multiple sites. While the study was adequately powered per sample sized calculation the large drop-out in the SOC group (12/20) resulted in high-risk bias due to missing outcome data. Combined with the small sample size, lack of blinding and short-term follow-up ranging from 6-12 weeks there was not sufficient evidence to understand safety, effectiveness, and long-term outcomes of this product.

NEOX CORD/TTAX01

A multi-centered prospective trial of cryopreserved human umbilical cord (TTAX01; NEOX) enrolled 32 subjects with complex wounds which extended to muscle, fascia or bone with underlying osteomyelitis with a mean duration of 6.1 ± 9.0 (range: 0.2–47.1) months and wound area at screening of 3.8 ± 2.9 (range: 1.0–9.6) cm2 which was increased to 7.4 ± 5.8 (range: 1.1–28.6) cm2 after aggressive debridement. Initial closure occurred in 18 of 32 (56%) wounds, with 16 (50%) of these having confirmed closure in 16 weeks with a median of one-product application. Ulcers with biopsy confirmed osteomyelitis (n=20) showed initial closure in 12 (60%) and confirmed closure in 10 (50%). Mean healing time was 12.8 ± 4.3 weeks. The average number of applications was 1.5 + 0.8 applications (median of 1, range 1–3) over 16 weeks. 84 These same patients were reported on in a follow-up report that included 30 subjects with evaluation for safety, while subjects with a remaining open or closed index wound (n=29) were evaluated for efficacy. One subject had his unhealed wound removed in a minor amputation in the previous study. They were followed for 1 year and the adverse events reported were all typical for the population under study, and none were attributable to NEOX. One previously healed wound re-opened, 1 previously unconfirmed closed wound remained healed, and 9 new wound closures occurred, with 25 of 29 (86.2%) healed in the ITT population. This included use of additional products, minor amputation (n=2) and one major amputation. 85. Limitations include small sample size, lack of controls, and no randomization. However, this investigation did assess complex wounds that are rarely included in clinical studies. Additional literature includes a basic science report, case series and small retrospective reports. These studies have inherent limitations due to the small sample size and observational design and there is no way to be certain that the treated wounds would have similar healing as compared to other skin substitutes or SOC. The potential benefit in a complex population (exposed tendon, muscle, and bone) warrants further investigation.

NeoPatch

A multi-centered prospective study was conducted with 63 patients with chronic DFU. Wounds were classified by size into ‘small’ (≤2.0 cm2), ‘medium’ (>2.0–4.0 cm2), and ‘large’ (>4.0–25.0 cm2). After a 2-week run in period patients were treated with chorioamniotic allograft (NeoPatch) on a weekly basis until the study period ended or wound closure to a maximum of 11 applications. At week 12, 13/23 small ulcers, 5/15 medium, and 1/10 large ulcers achieved closure, with a mean number of applications of 6.2, 6.6, and 8.0, respectively. The mean for the entire group was 40% closure (19/48) with 6.4 applications in 12 weeks. Of the adverse events reported most were related to the ulcer with no reported adverse events attributable to the allograft.86 Limitations of the study include the lack of randomization, control group, short term follow-up, small sample size, and potential risk of bias.

Oasis Ultra Tri-Layer Matrix

A RCT comprised of 11 centers and 82 subjects with DFU was completed to compare clinical outcomes of patients treated with tri-layer Oasis vs. SOC. Patients were randomized into Oasis group (n=41) or SOC (n=41) group and evaluated for 12 weeks or until complete wound closure was achieved. The Oasis group achieved a significantly greater number of complete closures compared to the SOC group (54% vs. 32%, P=0.021) at 12 weeks. Limitations include unblinded design, short duration of follow up, and high risk of bias. Strengths of the study were comprised of the randomization process and use of a digital wound measurement device.87

PriMatrix

Lantis et al. (2021) conducted a multicenter RCT to evaluate the safety and efficacy of a fetal bovine acellular dermal matrix (PriMatrix) plus SOC versus SOC alone for treating hard-to-heal DFU. Participants (n=226) and 161 completed the protocol with 59.5% (47/79) with wound closure in the PriMatrix group and 35.4% (29/82) in the SOC group (p=0.002) in the per protocol analysis. Of wounds that healed, median time to close was 43 days for PriMatrix group and 57 days for SOC group. The median number of applications of PriMatrix to achieve closure was 1.88 Adverse events were similar between groups and no product-related serious adverse events occurred. The author noted study limitations such as short term follow up, inability to blind investigators or subjects to treatment type, patient selection bias towards healthier patients, and an overall high risk of bias.

A prospective trial reported on 55 subjects from 9 centers with DFU treated with PriMatrix and followed for 12 weeks. 76% healed by 12 weeks with a mean time to healing of 53.1 ± 21.9 days. The mean number of applications for these healed wounds over 12 weeks was 2.0 ± 1.4, with 59.1% healing with a single application of PriMatrix and 22.9% healing with 2 applications. For subjects not healed by 12 weeks, the average wound area reduction was 71.4%.89 Study is limited by observational design without control group.

Additional literature includes a basic science report90 and a retrospective review.91,92

PuraPly

A prospective, noninterventional, multicentered study was conducted to evaluate the effectiveness of purified native type I collagen matrix plus polyhexamethylene biguanide antimicrobial (PHMB) on cutaneous wounds (PuraPly AM®). A cohort of 307 patients with VLU (n=67), DFU (n=62), pressure ulcers (n=45), post-surgical wounds (n=54), and other wounds (n=79) were treated with PuraPly and followed for 12 weeks. The number of applications ranged from 1-2 (21.8%) to 10 (<2%). They report that 73.2% of wounds were reduced from baseline and 63.4% had reached ≥70% reduction in area at 12 weeks with 37% of wounds achieving complete wound closure at 12 weeks. The average number of applications was 5.2 with 21.8% receiving 1 or 2 applications (21.8%) and <2% receiving 10 or more applications. No adverse events were reported related to the product.93 The study is limited by lack of a control group, blinding or randomization, short term follow-up, and high-risk of bias. While this study shows promising results, it is difficult to determine whether the treated wounds would have similar healing as compared to other skin substitutes or SOC. Additional literature includes a case series and retrospective review.

Restrata

In a 2017 report Restrata is introduced as a fully-synthetic, resorbable electrospun material (Restrata Wound Matrix) that exhibits structural similarities to the native extracellular matrix. The product was testedin a swine model.94 A retrosepctive review of the product reported on 82 ulcers in patients with DFU (n=34) or VLU (n=34) and other wounds (n=14). They report 85% of thee wounds achieved compete closure at 12 weeks.95 Limitations include study design without controls not sufficient to conclude if the outcome were directly related to the novel product and insufficent follow-up time to establish safety.

TheraSkin

A RCT trial investigated 50 subjects with DFU were treated with cryopreserved bioactive split thickness skin allograft (TheraSkin) and 50 were treated with SOC (collagen alginate dressing). The authors reported at 12 weeks 76% (38/50) of the TheraSkin group versus 36% (18/50) for the SOC group achieved healing. The number of allografts to achieve healing was not reported.96 Strengths of the study include randomization, ITT analysis, and low risk of bias. Despite the high dropout rate in SOC arm (n=19) the investigator used the last observation carried forward method to account for missing outcome data in the SOC group. Limitations in the study include small sample size, lack of blinding, and short-term follow-up.

A prospective study reported on 17 patients with DFU treated with the bioengineered skin substitute (Apligraf) and 12 were treated with a cryopreserved split thickness skin allograft (TheraSkin). Most received a single application with the decision to reapply left to the treating provider. The authors report 41.3% of the ulcers treated with Apligraf and 66.7% of the ulcers treated with TheraSkin were closed at 12 weeks, 47.1% treated with Apligraf closed at 20 weeks. The number of closed TheraSkin treated ulcers remained 66.7% at 20 weeks. The average number of applications of Apligraf was 1.53(SD=1.65). The number of applications of Theraskin was 1.38 (SD= 0.29). There were no significant adverse events reported. 97 Limitations of the study include small sample size, lack of control, short term follow up, and high risk of bias.

Sanders et al.58 performed a multi-centered RCT to contrast an in vitro- engineered, human fibroblast-derived dermal skin substitute (HFDS) (i.e., Dermagraft to a biologically active cryopreserved human skin allograft (HSA) (i.e., TheraSkin®) in the treatment of DFU. The primary objectives were to establish the relative number of DFU healed (100% epithelization without drainage) and the number of grafts needed by week 12. Twenty-three eligible patients were randomly assigned to the Dermagraft treatment group (12 patients) (mean age 57) or the Theraskin treatment group (11 patients) (mean age 60). Patients in the TheraSkin group received a product application every other week and patients in the HFDS group were treated every week with SOC. After the week 12 visit, no additional biologically active products were used in either treatment group. Patients with incomplete ulcer closure continued to be evaluated through week 20; subsequent treatment was then provided outside the scope of the study. At week 12, seven (63.6%) ulcers in the TheraSkin treatment group versus four (33.3%) in the Dermagraft treatment group were healed (P=0.0498). At the end of week 20, 90.91% of ulcers in the Theraskin group versus 66.67% of ulcers in the Dermagraft group were healed (P=0.4282). The average of 8.92 applications (range 6-12 applications) in up to 20 weeks for Dermagraft and mean applications of 4.36 (range 2-7) in up to 20 weeks for Theraskin.58

Time to healing in the TheraSkin group was substantially less (8.9 weeks) than in the HFDS group (12.5 weeks) (log-rank test, P=0.0323). The results of this study showed that, after 12 weeks of care, DFU treated with HSA were probably twice as likely to heal as DFU managed with Dermagraft with about half the number of grafts required. Limitations noted for this study include small sample size, short-term follow-up and high risk of bias58

Additional literature includes two large retrospective matched cohort studies 98,99 several cost-analysis, and an animal model study.

Clinical Trials for Skin substitute graft/CPTs for Venous Leg Ulcers

Amnioband

Serena et al.100 performed an open-label, multicenter RCT comparing 2 application treatments of dehydrated human amniotic and chorion allograft (dHACA) (i.e., AmnioBand) with SOC versus SOC alone for the treatment of 60 patients with VLU. Patients were randomized into 1 of 3 study groups: SOC alone (control), weekly AmnioBand with SOC or biweekly AmnioBand with SOC (20 patients per group). At 12 weeks, healing rates were 30/40 (75%) in the two AmnioBand groups and 6/20 (30%) in the SOC group; p= 0.001. Treatment with AmnioBand continued to be significant after adjustment for wound area (p= 0.002), with an odds ratio of 8.7 (95% CI: 2.2-33.6). Only six VLU (30%) were healed in the SOC group contrasted to 15 (75%) in the weekly AmnioBand group (p= 0.02) and 15 (75%) in the biweekly AmnioBand group (p= 0.02). There were no significant differences in the proportion of wounds with percent area reduction (PAR) ≥40% at 4 weeks among all groups. All analyses used the ITT approach, and the risk of bias was low. Limitations include lack of blinding and short-term follow.100

Apligraf (formerly GraftSkin)

Falanga et al. (1998) performed a multicenter RCT to evaluate a allogeneic human skin equivalent (HSE) Apligraf group (n=146) versus SOC (n=129) in 275 patients with VLU. At 6 months, 63% Apligraf vs. 49% SOC patients were healed. Median time to complete wound closure was 61 days in the Apligraf group vs. 181 days in the SOC group. An average of 3.34 applications of Apligraf per patient were utilized.101 There were some concerns for risk of bias due to per protocol analysis only as well as short-term follow-up.

A prospective RCT included 120 patients with hard to heal VLU for a duration of greater than 1 year. Patients were randomized into an Apligraf plus compression therapy (n=74) or standard compression therapy (n=48) groups. Wound closure at 6 months was reported as 47% for the Apligraf group versus 19% for the control group. The authors conclude at 6 months, that patients treated with Apligraf were twice as likely to achieve complete wound closure as compared to standard compression therapy. They report Apligraf was over 60% more effective than the control in achieving wound closure. Limitations include high risk of bias, and lack of blinding.102

A prospective randomized pilot study was conducted to estimate the relative difference in the effectiveness of Apligraf and Theraskin and compression therapy for the treatment of VLU. A total of 31 participants were randomized and they reported a higher healing rate in the Theraskin cohort (93.3%) as compared to the Apligraf cohort (75.0%) at 12 weeks, but it was not statistically signficiant. At 20 weeks follow up, the Theraskin cohort remained at a 93.3% versus Apligraf cohort at an 83.3% healing rate. The mean number of applications was 3.33 in the Apligraf group and 2.27 in the Theraskin group for 12 weeks. Limitations of this study include low sample size, and high risk of bias. There were no adverse events reported.103

DermACELL

Cazzell104 conducted a multicenter, RCT designed to evaluate the safety and efficacy of human decellularized acellular dermal matrices (Dermacell AWM®) (n=18) contrasted with SOC (n=10) in patients with chronic VLU. The study participants were randomly assigned to the D-ADM (i.e., DermACELL AWM®) treatment arm or a SOC treatment arm in a 2:1 ratio. A blinded, independent adjudicator also assessed the healing condition of all ulcers. Patients could have a maximum of two DermACELL applications, which included the first application at baseline and 9 (50%) received a second application during the study. At 24 weeks, patients in the DermACELL arm demonstrated a strong trend of reduction in the ulcer area, with a mean reduction of 59.6%, in comparison to the SOC arm, with a mean reduction of 8.1%. Also, the ulcer areas in the SOC arm increased more than 100% in size for one-third (3/9) of the patients. Furthermore, healed ulcers in the DermACELL arm stayed closed at a significantly greater rate after initial confirmation of complete ulcer closure than healed ulcers in the control arm. Limitations noted for this study included a small patient population with an unbalanced proportion between the 2 groups (2:1) that ensured a low probability of achieving statistical significance, insufficient criteria for investigators to follow when deciding if a second application would be appropriate, and a short-term follow-up. The overall risk of bias was low.

Dermagraft

Harding et al.105 conducted a multicenter RCT that assessed the human fibroblast-derived dermal substitute (HFDS) (i.e., Dermagraft®) plus compression therapy contrasted with compression therapy alone in the treatment of VLU. The primary outcome variable was the proportion of patients with completely healed study ulcers by 12 weeks. Sixty-four (34%) of 186 patients in the Dermagraft group demonstrated healing by week 12 compared with 56 (31%) of 180 patients in the control group (P=0.235). For ulcers ≤ 12 months duration, 49 (52%) of 94 patients in the Dermagraft group contrasted with 36 (37%) of 97 patients in the control group healed at 12 weeks (P=0.029). For ulcers ≤ 10 cm2, complete healing at week 12 was shown in 55 (47%) of 117 patients in the HFDS group contrasted with 47 (39%) of 120 patients in the control group (p=0.223). The most common AEs were ulcer infection, cellulitis, and skin ulcer. The occurrence of AEs was not significantly different between the treatment and control groups. Statistical significance was not achieved for the primary outcome of complete closure in patients with VLU completely healed by 12 weeks. The study had some concerns for risk of bias due to high dropout rate and lack of validation of outcome measurements.105

EpiFix

A multi-centered, RCT was conducted to evaluate a dehydrated human amnion/chorion membrane allograft (EpiFix) (n=53) with SOC to SOC alone (n=31) for VLU. Subjects randomized to allograft received 1 (n=26) or 2 applications (n=27). At 4 weeks, 62% in the allograft group and 32% in the control group showed a greater than 40% wound closure (p=0.005), and wound size reduction of 48.1% and 19%, respectively. The authors reported the group with 2 applications (baseline and 2 weeks later) had the fastest healing time.106 Limitations include lack of blinding, small sample size, and short-term follow up.

Another multi-centered RCT comparing EpiFix + SOC to SOC alone (multilayer compression therapy) for 109 subjects with VLU and followed for 16 weeks. Participants receiving weekly application of EpiFix (n=52) and compression were significantly more likely to experience complete wound healing than those receiving standard wound care and compression (n=57) (60% versus 35% at 12 weeks, P=0.0128, and 71% versus 44% at 16 weeks, p=0.0065).107 Limitations of the study include lack of blinding, short term follow up, and high risk for bias.

Oasis Products

Oasis Wound Matrix:

Landsman et al. conducted an RCT of 26 subjects with DFU. Subjects were randomized and treated with either Dermagraft (n=13), or Oasis Wound Matrix (n=13) in conjunction with SOC. Wound dressing was applied for 12 weeks and subjects were followed for 20 weeks. Closure rate for Oasis was 76.9% and Dermagraft is 84.6% with average closure time of 40.90 ± 32.32 days. No statistically significant difference was reported in closure time between the two groups. The average number of applications was 2.54 (±0.78) of Dermagraft and 6.46 ± 1.39 of Oasis in 12 weeks.108 Limitations include small sample size, short term follow-up and some concerns for bias.

Niezgoda et al. conducted a multicenter RCT to compare the rate of healing in DFU patients. Patients were randomized to either the OASIS Wound Matrix (n=37) group or Regranex Gel (n=36) plus a secondary dressing group. At 12-week follow-up, the Oasis group achieved 49% wound healing as compared to 28% in the Regranex group. Limitations included small sample size, lack of standardization between centers in debridement techniques, frequency of wound dressing changes, lack of blinding, and some concerns for bias.109

A 2010 RCT was conducted to compare the Oasis Wound Matrix (n=25) to SOC (n=25) in VLU. Investigators assessed the wounds weekly and utilized digital planimetry for wound measurement. At 8 weeks complete wound closure was achieved in 80% (20/25) of Oasis Wound Matrix patients as compared to 65% (15/23) in the SOC group (p<0.05). A statistically significant difference was reported for mean ulcer duration. Complete healing was achieved in the treatment group, 5.4 weeks, vs. 8.3 weeks in the SOC group, (p=0.02). Granulation tissue was considered in cases where complete wound closure was not achieved by 8 weeks. The granulation of tissue increased from baseline to 8 weeks in the Oasis group and was reported as 50% and 65%, respectively, while the control group reported a loss of granulation from a baseline of 50% to a decrease of 38% at 8 weeks. Two subjects withdrew from the control group due to relocation. No adverse effects were reported. Limitations include small sample size, lack of blinding, and some concerns for bias.110

Mostow and colleagues conducted a multicenter RCT comprised of 120 patients with VLU to compare the Oasis Wound Matrix plus SOC (n=62) to SOC alone (n=58). Following a 2-week screening period, patients were randomized into 1 of the 2 groups and followed for 12 weeks. A total of 19 patients assigned to the SOC alone group crossed over into the treatment group due to a lack of healing at 6 months. Healing was achieved in 26% (5/19) of these patients after receiving an average of 4 applications of the Oasis product. The primary outcome was proportion of healed ulcers at 12 weeks. Although the data was still analyzed, 20% of patients were lost to follow up (12 in each group). At 12 weeks, the treatment group achieved 55% healing as compared to 34% in the SOC group. Ulcer recurrence did not occur in any of the healed patients in the treatment group over a 6-month period. The average number of applications for VLU was 4 (applied to 5/19 crossover patients). A total of 23 adverse events were reported and evenly distributed between the two groups. Limitations include lack of blinding, small sample size, short duration of follow up, limited number of wounds evaluated at 6 months, and high risk of bias.111

Additional literature is reviewed in Dermagraft section. Literature reviewed but not summarized in this policy includes a retrospective comparative study in the treatment of VLU.112

Unspecified Oasis Products

O’Donnell and associates conducted a systematic review of RCTs to determine if complex wound coverings impacted wound healing as compared to simple wound dressings. A total of 20 RCTs were included and stratified into 3 classes semi occlusive/occlusive group (n = 8), growth factor group (n = 7), and human skin equivalent group (n = 5). Five of the RCTs (25%) yielded statistical significance for improved proportion of ulcer healing in the treatment group over the control: zinc oxide pastes bandage (79% vs 56%) and Tegasorb (59% vs 15%) in the semi occlusive/occlusive group and perilesional injection of granulocyte-macrophage colony-stimulating factor (57% vs 19%) and porcine collagen derived from small-intestine submucosa (Oasis; 55% vs 34%) in the growth factor group. In the sole significant RCT from the human skin equivalent group, Apligraf (63%) was superior to Tegapore (49%).”3 See Apligraf section.

A 2019 single blinded RCT comprised of patients with DFU compared 8 weeks of treatment using either Dermagraft (n=29) or Oasis devices (n=31) (active treatment phase) followed by 4 weeks of SOC (maintenance phase), and SOC (n=29) alone. Each treatment group achieved a statistically significant reduction in wound area from weeks 1 to 28. No differences were reported between groups in complete wound closure by 12 or 28 weeks of treatment. Complete wound closure at 12 weeks was Dermagraft (8/17) 47.1%, Oasis (14/19) 73.7%, and SOC 57.9% (11/19). Complete wound closure by study conclusion was Dermagraft (11/17) 64.7%, Oasis (15/19) 78.9%, and SOC 73.7% (14/19). The study was an interim report and did not have enough enrolled to meet the sample size needed, and there was a high risk of bias due to per-protocol analysis only for this interim data. The authors were surprised at the higher healing rates for SOC than what was reported in the U.S. literature and postulated that unintentional bias may have resulted in lower efficacy in the SOC group or favoring SOC in their study.113 The final results were not identified as being published therefore there is a potential risk for publication bias. See the Dermagraft section.

Romanelli et al. conducted a RCT to compare Oasis (n=27) and Hyaloskin (n=27) products in the healing VLU at 16 weeks of treatment. Patients were assessed by complete wound healing, time until dressing change, pain and comfort. A total of 82.6% of Oasis ulcers achieved complete wound closure as compared to 46.2% of Hyaloskin ulcers. Treatment favored Oasis treated ulcers which were statistically significant for time to dressing change (p< 0.05), pain (p< 0.05) and patient comfort (p< 0.01). Four patients were lost to follow up. No adverse events were reported. Limitations include self-reporting bias, small sample size, lack of blinding, and some concerns for bias related to randomization.114

Demling and associates reported an interim analysis of a prospective RCT to examine the effectiveness of Oasis products compared to SOC in treating VLU. The primary outcome was wound closure at 12 weeks. At 12 weeks, 84 patients were evaluated in which 71% (32/45) of Oasis vs. 46% (18/39) SOC patients achieved complete wound healing. Significant improvements in the incidence of healing were reported in the Oasis patients vs. SOC (p=0.018). Interim results were reported on per-protocol analysis rather than the intention to treat population introducing a high risk of bias.115 The final results were not identified in the literature and do not appear to have been published, which potentiates the risk for publication bias.

Talymed

A RCT enrolled 82 patients comparing a poly-N-acetyl glucosamine, nanofiber-derived, technology (Talymed) to SOC for VLU. Subjects were randomized to treatment with Talymed applied once, every other week, every 3 weeks, or SOC alone and followed for wound healing at 20 weeks. At 20 weeks, the proportion of patients with completely healed VLU was 45.0% (n = 9 of 20), 86.4% (n = 19 of 22), and 65.0% (n = 13 of 20) for groups receiving standard care plus Talymed only once, every other week, or every 3 weeks, respectively, versus 45.0% (n = 9 of 20) for those receiving standard care alone.116 The biweekly application group showed improvement over the standard of care arm (p<0.01). Strengths include randomization, blinded investigator, and presence of a control arm. The investigation had limitations which consisted of a small sample size and high risk of bias due to missing outcome data. While these results were promising the sample size was too small to determine if the outcomes were related to the product. The authors acknowledge that this was a pilot study and there was a need for a larger study to confirm the findings. Further, 2 of the 3 study arms did not show significant differences from the SOC group.

Additional literature consists of case report117 and was included in a systematic review33 (see above).

Risk of Bias Assessment

A risk of bias assessment was conducted for all RCTs to evaluate them using the same tool and identify areas of potential concern in study designs. Risk of Bias 2 tool118 (RoB2) was used and is described in the Cochrane handbook119 and utilized in GRADE. This tool is different than the tool used in the AHRQ report4 and the other systematic reviews published prior to 2019 (see the section addressing Systematic Reviews) when the updated tool was published. The revised version requires a judgement about the risk of bias arising from each domain- based on answers to the signaling questions. Judgements are ‘Low’, ‘High’, or can express ‘Some concerns’ and included in the evidence review and Table 1 for each product assessed. The overall result must reflect the highest value assigned to any domain. While almost all included studies were funded by industry, this is not an underlying reason to determine that bias exists using RoB2. This tool requires evaluation of multiple aspects of the trial design and assesses if risk of bias was introduced regardless of funding source.

Table 1: Evidence for Covered Products

 

 

Skin Substitutes/CTP

(per sq cm unless otherwise stated)

Ulcer Type

Literature

Risk-of-bias Assessment

Affinity

DFU

1. RCT (n=76) reported wound closure at 16 weeks of 63% for Affinity arm and 38% in SOC (n=38)34

1. Low risk 34

Amnioband, guardian

DFU

1. RCT (n=60) reported healing rate at 12 weeks was 90% for the Amnioband group versus 40% for the Apligraf group.41

2. RCT (n=40) reported at 12 weeks 85% of the DFU in the Amnioband group healed compared with 25% in the SOC group.120

3. RCT (n=80) reported at 12 weeks, 85% of the DFU in the Amnioband group achieved healing compared with 33% of the DFU in the SOC group. 121

 

 

 

1. High risk due to missing outcome data41

2. Low risk 120

3. Low risk 121

Amnioband, guardian

VLU

1. RCT (n=60) healing rates at 12 weeks were 75% in the two Amnioband groups and 30% in the SOC group.100

1. Low risk100

 

Apligraf

DFU

1.RCT (n=208) reported wound closure at 12 weeks of 56% for Apligraf and 38% for SOC.45

2.RCT (n=72) reported on wound closure at 12 weeks of 55.2% for Apligraf and 34.3% for SOC.46

3.RCT (n=82) reported on wound healing at 12 weeks of 51.5% for Apligraf and 26.3% for SOC.47

4.RCT (n=60) reported on wound closure at 6 weeks of 95% for EpiFix, 45% for Apligraf and 35% for SOC.65

1. High risk due to lack of validation of outcome measurements45

2. Unable to complete due to pooling data from 2 different studies into one paper.46

3. High risk due to lack of validation of outcome measures47

4. High risk due to missing outcome data65

Apligraf

VLU

1.RCT (n=275) reported on wound closure at 6 months of 63% for Apligraf and 49% for SOC.122

2. RCT (n=120) reported on wound closure at 24 weeks of 47% for Apligraf and 19% SOC.102

3. RCT (n=31) reported on wound healing at 12 weeks of 93.3% for Theraskin and 75% for Apligraf.103

1. Some concerns due to potential deviations from intended intervention (no ITT)122

2. High risk because it was unclear if allocation was concealed, data in text and table do not match, unclear if all outcome data was reported and lack of validation of outcome measures in unblinded study102

3. High risk due to potential deviations from intended intervention (no ITT), and lack of validation of outcome measures in unblinded study, did not enroll planned sample size 103

DermACELL, awm, porous

DFU

 

1. RCT (n=168) reported healing rate at 16 weeks was 67.9% in DermaCell arm, 48.1% in SOC arm 47.8% in the Graftjacket arm.53,54

2. Prospective study (n=61) of large complex wounds treated with DermACELL with 24.6% closure at 16 weeks.55

1. Some concerns due to randomization53,54

2. NA

DermACELL, awm,
porous

VLU

1. RCT (n=28) reported on wound
closure of 59.6% for DermACELL
and 8.1% for SOC at 24 weeks.104

1. Low risk104

Dermagraft

DFU

1. RCT (n=314) reported wound closure at 12 weeks of 30% of Dermagraft group and 18.3% in SOC group.56

2. RCT (n=23) reported wound closure at 20 weeks with 90.91% in Theraskin group and 66.67% in Dermagraft group.58

3. RCT (n=50) on wound closure at 12 weeks with 50% for Dermagraft and 8% SOC group.57

1. Some concerns due to missing outcome data56

2.High risk due to unclear randomization, potential deviations from intended intervention (no ITT) and lack of validation of outcome measurements 58

3. High risk due to missing outcome data, lack of validation of outcome and unclear randomization.57

Dermagraft

VLU

1. RCT (n=366) reported on wound closure at 12 weeks of 34% for Dermagraft and 31% for SOC.105

1. Some concerns due to high dropout rate (missing outcomes), and lack of validation of outcome measurements105

 

Epicord

 

 

1. RCT (n=155) reported wound closure at 12 weeks of 70% for EpiCord and 48% for SOC.59

1. Low risk59

Epifix

DFU

1. RCT (n=25) reported wound healing at 6 weeks in EpiFix group of 92% and 8% in SOC group.61

2. RCT (n=104) reported wound closure 12 weeks of 73% for Apligraf, 97% for EpiFix and 51% for SOC. 48

3. RCT (n=110) reported on wound closure at 12 weeks of 70% EpiFix and 50% SOC in the ITT analysis.62

4. RCT (n=60) reported on wound closure at 6 weeks of 95% for EpiFix, 45% for Apligraf and 35% for SOC.65

 

1. High risk due to lack of validation of outcome measurements61

2. High risk due to unbalanced and missing outcome data48

3. Low risk62

4. High risk of bias due to missing outcome data65

Epifix

VLU

1. RCT (n=53) reported wound reduction in 4 weeks was 62% for EpiFix and 32% for SOC.106

2. RCT (n=109) reported wound closure at 16 weeks for VLU was 71% for EpiFix and 44% for SOC.107 The follow-up report included ITT analysis reported similar results with 50% in EpiFix group and 31% in SOC.123

1. Low risk106

2. The 2018 paper was high risk due to potential deviations from intended intervention (no ITT) and missing outcome data107 while the 2019123 was high only due to missing outcome data.

FlexHD/AllopathHD/ Allopatch pliable/ Matrix HD

DFU

1. RCT (n=40) reported wound healing at 12 weeks of 80% for AlloPatch and 20% for SOC36, additional 40 patients enrolled and reported similar results124

2. Literature also in breast reconstruction, rotator cuff repair, hernia repair, and lab research38-40 and a retrospective report37

1. High risk due to missing data outcomes124

2. NA

Grafix stravix prime pl

 

1. RCT (n=97) reported wound closure at 12 weeks was 62% in Grafix group and 21% in SOC group.66

2. Retrospective report (n=441)67

1. High risk as randomization was not described, and missing outcome data 66

2. NA

Graftjacket

DFU

1. RCT (n=40) reported on wound healing at 12 weeks with a 67.4% reduction with Graftjacket and 34% with SOC.69

2. RCT (n=28) reported on wound closure at 16 weeks of 85.71% in Graftjacket arm and 28.57% in SOC.70

3. RCT (n=86) reported on mean wound healing time of 12 weeks was 30.4% with Graftjacket and 53.9% with SOC.71

4. RCT (n=168) reported on wound closure at 16 weeks of 67.9% for DermACELL, 47.8% for Graftjacket, and 48.1% for SOC.53,54

5. These studies were included in a meta-analysis72 and Graftjacket in another125

1 & 2. High risk due to unclear randomization, potential deviations from intended intervention (no ITT), lack of validation of outcome measurements, and statistical plan not described 69,70

3. High risk due to unclear randomization, lack of validation of outcome measurements71

4. Low risk53,54

5. NA

Integra or Omniograft dermal regeneration template

DFU

1. RCT (n=307) reported wound closure at 16 weeks of 51% in Integra group and 32% in SOC group.73

1. High risk due to missing outcome data73

 

Oasis tri-layer wound

DFU

1. RCT (n=82) reported on wound closure at 12 weeks with 54% for Oasis Tri-layer and 32% for SOC.87

 

1. High risk due to missing outcome data87

 

Oasis wound matrix DFU

1. RCT (n=26) reported no difference in closure time for Dermagraft (84.6% or Oasis Wound Matrix (76.9%)108

2. RCT (n=73) reported on wound healing at 12 weeks of 49% for Oasis wound matrix and 28% for Regranex gel.109

Additional literature on pressure ulcers.

1. Some concerns due to no validation of wound measurements 108

2. Some concerns due lack of validation of outcome measurements109

Oasis wound matrix VLU

1. RCT (n=48) reported wound closure at 8 weeks of 80% for Oasis wound matrix and 65% for SOC.110

2. RCT (n=120) reported on wound healing at 12 weeks of 55% in Oasis group and 34% in SOC.111

3. RCT (n=89 reported on wound closure at 12 weeks with 47.1% for Dermagraft, 73.7% for Oasis and 57.9% for SOC.113

4. RCT (n=84) reported on wound closure at 12 weeks of 71% Oasis and 46% SOC.115

1. Some concerns due to randomization process110

2. High risk due to missing outcome data, lack of validation of outcome measurements 111

3. High risk of bias due to per-protocol analysis only113

4. High risk due to per-protocol analysis, missing outcome data and uncertain method for outcome measurements or blinding protocol115

PriMatrix DFU

1. RCT (n=161) reported wound closure at 12 weeks of 59.5% for PrimMatrix arm and 35.4% for SOC arm.88

2. Prospective trial(n=55)89, retrospective91,92 and lab90

1. High risk due to lack of blinding and analysis of outcome measures 88

2. NA

Theraskin DFU

1. RCT (n=50) reported on wound healing at 12 weeks was 76% for TheraSkin and 36% for SOC.96

2. RCT (n=23) reported wound closure at 20 weeks with 90.91% in Theraskin group and 66.67% in Dermagraft group.58

3. A small prospective study (n=29),97 retrospective cohort studies,98,99 and lab study126

1. Low risk96

2. High risk58

3. NA

 

Table 2: Evidence for Non-Covered Products

Skin Substitutes (Per sq cm unless otherwise stated)

Evidence (Published, peer reviewed literature to support use in chronic DFU/VFU)

Comment

Ac5 advanced wound system (ac5)

No literature identified

 

Acesso dl, Acesso tl

No literature identified

 

Activate matrix

No literature identified

 

AlloDerm

Evidence in breast surgery and hernia repair

Insufficient evidence for DFU/VLU

Allogen, per cc

No literature identified

 

Alloskin, Alloskin ac

Evidence in burn and orthopedics

Insufficient evidence for DFU/VLU

Allowrap DS or DRY

Literature in tarsal tunnel, thoracic outlet syndrome, proctectomy, and burns

Insufficient evidence for DFU/VLU

American amnion, American amnion AC, American Amnion, Tri-Layer

No literature identified

 

Amnio bio or axobiomembrane

No literature identified

 

Amnio quad-core

No literature identified

 

Amnio Wound

No literature identified

 

Amnioamp-MP

No literature identified

 

Amnioarmor

No literature identified

 

Amnioband particulate, 1 mg

No literature identified

 

Amniocore, Amniocore pro, Amniocore pro+

No literature identified

 

Amniocyte plus, per 0.5cc

No literature identified

 

Amnioexcel, Amnioexcel plus or biodexcel

Small RCT44

Insufficient evidence (see LCD section Amnioexcel)

Amniomatrix or Biomatrix, injectable, 1 cc

No literature identified

 

Amnio-maxx or amnio-maxx lite

No literature identified

 

Amniorepair or Altiply

No literature identified

 

Amniotext patch

Case report127

Insufficient evidence

Amniotext, per cc

No literature identified

 

Amnio-tri-core amniotic

No literature identified

 

Amniowrap2

No literature identified

 

Amniply, for topical use only

No literature identified

 

Apis

Retrospective comparative study of 47 wounds128, case serie129

Insufficient evidence

Architect ecm px fx

No literature identified

 

Artacent ac, 1 mg

No literature identified

 

Artacent am

Observational study (n=26) 130

Insufficient evidence

Artacent cord

No literature identified

 

Artacent wound

Observational study (n=26)130

Insufficient evidence

Arthroflex

Evidence for rotator cuff repair

Insufficient evidence for DFU/VLU

Ascent, 0.5 mg

No literature identified

 

Axolotl ambient or axolotl cryo, 0.1mg

No literature identified

 

Axolotl graft or axolotl dualgraft

No literature identified

 

Barrera SL or barrera dl

No literature identified

 

Bellacell HD or Surederm

Literature for breast surgery

Insufficient evidence for DFU/VLU

Bio-connekt wound matrix

No literature identified

 

BioDFence dryflex

No literature identified

 

Bionextpatch

No literature identified

 

Biovance, Biovance tri-Layer or biovance 3L

Observational study51, case series52

Insufficient evidence (see LCD section Biovance)

Carepatch

No literature identified

 

Celera dual layer or celera dual membrane

No literature identified

 

Cellesta cord, Cellesta or Cellesta Duo

No literature identified

 

Cellesta flowable amnion per 0.5cc

No literature identified

 

Cocoon membrane

No literature identified

 

Cogenex amniotic membrane

No literature identified

 

Cogenex flowable amnion, per 0.5cc

No literature identified

 

Coll-e-derm

No literature identified

 

Complete aa, Complete aca, Complete sl, Complete ft

No literature identified

 

Corecyte, for topical use only, per 0.5cc

No literature identified

 

Coretext or protext, per cc

No literature identified

 

Corplex P

No literature identified

 

Corplex P, per cc

No literature identified

 

Cryo-cord

No literature identified

 

Cygnus

No literature identified

 

Cygnus dual

No literature identified

 

Cygnus, matrix

Lab study131

Insufficient evidence

Cymetra, injectable, 1 cc

No literature identified

 

Cytal (formerly Matristem)

One RCT8 and 2 case series 132,133

Insufficient evidence (see LCD section Matristem)

Dermabind dl, Dermabind ch, Dermabind sl

No literature identified

 

DermaBind tl or Amniobind

No literature identified

 

Dermacyte amniotic membrane allograft

Case report 134

Insufficient evidence

Derma-gide

No literature identified

 

Dermapure

Retrospective review (n=37)135

Insufficient evidence

Dermavest, plurivest

Case series136, Lab study137

Insufficient evidence

Derm-maxx

No literature identified

 

Dual layer impax membrane

No literature identified

 

Emerge matrix

No literature identified

 

Enverse

No literature identified

 

Epieffect

No literature identified

 

EpiFix injectable, 1 mg

No literature identified

 

Esano a, Esano aaa, Esano ac, Esano aca

No literature identified

 

Excellagen, 0.1cc

Lab paper138

Insufficient evidence

EZ-derm

Evidence in burn.

Insufficient evidence for DFU/VLU

Floweramnioflo, 0.1 cc

No literature identified

 

Floweramniopatch

No literature identified

 

Flowerderm

No literature identified

 

Fluid flow or fluid gf, 1 cc

No literature identified

 

Gammagraft

Bench139/ case report

Insufficient evidence

Genesis amniotic membrane

No literature identified

 

Grafix core, grafixpl core

Prospective study in 31 complex wounds achieving 59% closure.68

 

Retrospective report (n=441)67

Insufficient evidence (see LCD section GrafixCORE)

Grafix plus

No literature identified

 

Graftjacket Xpress, injectable, 1 cc

No literature identified

 

Helicoll

Literature for split-thickness graft donor sites.

Insufficient evidence for DFU/VLU

Hmatrix

Evidence in breast surgery, head and neck, and hand/arm reconstruction, and abdominal wall closure.

Insufficient evidence for DFU/VLU

Hyalomatrix

Evidence in burns, trauma, skin cancer. Evidence in ulcer management includes case series140-143 and a review article144

Insufficient evidence

Innovaburn or Innovamatrix xl

Review paper145

Insufficient evidence

Innovamatrix ac, Innovamatrix fs

No literature identified

 

Innovamatrix pd 1mg

No literature identified

 

Integra bilayer dermal matrix wound dressing

No literature identified

 

Integra flowable wound matrix, injectable, 1 cc

No literature identified

 

Integra Meshed Bilayer Wound Matrix

No literature identified

 

Interfyl, 1 mg

Literature on soft tissue reconstruction

Insufficient evidence for DFU/VLU

Keramatrix or Kerasorb

No literature identified

Insufficient evidence

Kerecis Omega3/ Kerecis omega3, MariGen shield

RCT (n=170) for healing in punch biopsy site75, RCT (n=49) reported wound closure at 12 weeks of 67% for Kerecis and 32% for SOC with high risk of bias due to missing outcome data.76

Insufficient evidence (see LCD section Kerecis)

Keroxx (2.5G/CC), 1 cc

No literature identified

 

Lamellas xt, Lamellas

No literature identified

 

Matrion

Lab study69

Insufficient evidence

Matristem micromatrix, 1 mg, MAtristem wound matrix, Matristem burn matrix

One RCT8 and 2 case series 132,133

Insufficient evidence for DFU/VLU (see LCD section Matristem)

Mediskin

Evidence for split-thickness graft donor sites.

Insufficient evidence for DFU/VLU

Membrane graft or membrane wrap

No literature identified

 

Membrane wrap-hydro

No literature identified

 

Memoderm, Dermaspan, Tranzgraft, or Integuply

Case report146

Insufficient evidence

Mgl-complete

No literature identified

 

Microlyte, Matrix

Prospective observational study in 35 chronic wounds with 91% healing or improved at 12 weeks.79

Insufficient evidence (see LCD section Microlyte Matrix)

Miro3d

No literature identified

 

Miroderm

Prospective pilot study in 7 wounds,147 and prospective observational study of 38 ulcers148

Insufficient evidence

Mirragen adv wnd matrix

Bench papers80,81/ case series149, small RCT 83/ review paper82

Insufficient evidence (see LCD section Mirragen)

MyOwnSkin

No literature identified

 

Neomatrix

No literature identified

 

Neopatch or Therion

No literature identified

 

Neostim tl, Neostim membrane, Neostim dl

No literature identified

 

Neox 100 or clarix 100

Prospective trail (n=32)84,85

Insufficient evidence (see LCD section Neox)

Neox cord 1K, Neox Cord rt, or Clarix cord 1K

No literature identified

 

Neox Flo or Clarix Flo, 1 mg

Case series150

Insufficient evidence

Novachor

No literature identified

 

Novafix, Novafix dl

No literature identified

 

Novosorb Synpath Dermal Matrix

Book chapter (bench studies)151 (review article152

Insufficient evidence

Nudyn dl or nudyn dl mesh, Nudyn sl or nudyn slw

No literature identified

 

NuShield

Case report153, Retrospective report with 50 wounds.154 Literature in talar dome lesions.

Insufficient evidence for DFU/VLU

Oasis burn matrix

No literature identified

 

Omeza collagen matrix, per 100 mg

Bench papers155,156

Insufficient evidence lacks clinical studies

Orion

No literature identified

 

Palingen or Promarx, 0.36 mg per 0.25cc

Literature in plantar fasciitis

Insufficient evidence for DFU/VLU

Palingen, palingen xplus, or Promarx

Literature in plantar fasciitis

Insufficient evidence for DFU/VLU

Permeaderm b, Permeaderm c

No literature identified

 

Phoenix wound matrix

No literature identified

 

Polycyte, for topical use only, per 0.5cc

No literature identified

 

Porcine implant, Permacol

Evidence in hernia repair

Insufficient evidence for DFU/VLU

Procenta, per 200 mg

No literature identified

 

Progenamatrix

No literature identified

 

Puraply, Puraply xt

Prospective, noninterventional study (n=307)93

Insufficient evidence (see LCD section Puraply)

Puraply, am

Prospective, noninterventional study (n=307)93, case series157-159

Insufficient evidence (see LCD section Puraply)

Rebound matrix

No literature identified

 

Reguard, for topical use

No literature identified

 

Relese

No literature identified

 

Repriza

Literature in plastic surgery

Insufficient evidence for DFU/VLU

Resolve matrix

No literature identified

 

Restorigin

No literature identified

 

Restorigin, 1 cc

No literature identified

 

Restrata

Retrospective review 82 wounds95

Insufficient evidence due to low quality

Revita

No literature identified

 

Revitalon

No literature identified

 

Revoshield + amniotic barrier, per sq cm

No literature identified

 

Sanopellis

No literature identified

 

Signature apatch

No literature identified

 

Skin Sub, NOS

 

 

Skin substitute, FDA cleared as a device, not otherwise specified

 

 

Skin te

No literature identified

 

Strattice TM

Evidence in abdominal wall closure/hernia repair

Insufficient evidence for DFU/VLU

Supra sdrm

No literature identified

 

Suprathel

No literature identified

 

Surfactor or Nudyn, per 0.5cc

No literature identified

 

Surgicord

No literature identified

 

Surgigraft, Surgraft tl, Surgraft ft, Surgraft xt, Surgigraft-dual

No literature identified

 

SurgiMend Collagen Matrix, per 0.5 sq cm

 

Evidence in breast surgery

Insufficient evidence for DFU/VLU

Surgraft

No literature identified

 

Symphony

No literature identified

 

Tag

No literature identified

 

Talymed

One RCT116, one case report117, literature on use in bone wound healing160 and lab reasearch161

Insufficient evidence (see LCD section Talymed)

Tensix

Case reports146

Insufficient evidence

Theragenesis

No literature identified

 

Transcyte

Literature in burns

Insufficient evidence for DFU/VLU

Truskin

No literature identified

 

Unite biomatrix

Abstract and case report162

Insufficient evidence

Via Matrix

No literature identified

 

Vendaje, Vendaje ac

No literature identified

 

VIM

No literature identified

 

Woundex flow, Bioskin flow, 0.5 cc

No literature identified

 

Woundex, BioSkin

Retrospective study (n=20)163

Insufficient evidence

Woundfix, Biowound, Woundfix plus, biowound plus, Woundfix xplus or biowound xplus

No literature identified

 

Woundplus membrane or e-graft

No literature identified

 

Xcell amnio matrix

No literature identified

 

Xcellerate

No literature identified

 

Xcellistem, 1 mg

No literature identified

 

XCM biologic tissue matrix

Literature for chest wall defects

Insufficient evidence for DFU/VLU

Xwrap

No literature identified

 

Zenith amniotic membrane

No literature identified

 

Application changes

A 2021 industry-sponsored study presented a retrospective analysis from the Medicare Limited Data set (2015-2018) comparing lower extremity diabetic ulcers (LEDUs) treatment with advanced treatments (AT) defined as cellular and acellular dermal substitutes, compared to no advanced treatments (NAT). Out of 9,738,760 patients identified with a diagnosis of diabetes, 909,813 had a lower extremity diabetic ulcer (LEDU). Patients treated exclusively with AT or NAT were included in the analysis (i.e., patient treated with another type of advanced treatment were excluded). A set of covariates that included patient demographics, LEDU characteristics, year of episode start, prior treatments, prior visits, and comorbidities was identified. Based on this set, propensity scores were used to create two comparable groups with similar distributions of observed covariates. In propensity-matched Group 1, AT patients had fewer minor amputations (p = 0.0367), major amputations (p < 0.0001), ED visits (p<0.0001), and readmissions (p<0.0001) contrasted with NAT patients (12,676 episodes per cohort). The authors then took a second step in the analysis to attempt to determine the effectiveness of AT following parameter for use contrasted to patients with AT not following parameter for use. They reported patients had fewer minor amputations (p = 0.002) in those following parameters for use (1,131 episodes per cohort). They conclude advanced treatments with skin substitutes were associated with significant reduction in major and minor amputations, emergency room visits, and hospital readmissions compared to those without advanced treatments. They also conclude that following the parameters improved outcomes.17 The study is limited by lack of blinding and randomization which restricts the ability to determine if these outcomes were directly related to the treatment with skin substitute. It is unclear whether the study considered a number of factors that would be expected to influence outcomes, including visit frequency, compliance with care, infection treatment, and the use of additional products/treatments. It is difficult to draw the conclusion that the improvement was due solely to the advanced treatment with skin substitutes and not related to other factors from a retrospective study.

The study does report on frequency of application. Patients who received AT with skin substitute grafts (propensity-matched Group 1) had 3.7(3.6) applications on average (n=12,313). In Group 2 the average number of applications in the parameter for use group was 4.9(3.8) (n=1131) and in the not following parameter for use group the average was 3.5 (3.3). 17

The number of applications in the reported literature is variable and differs among products. Factors to considerinclude whether the application was made per protocol, whether those protocols require a product change or is at the discretion of the provider, and any applications made on an as needed basis. In a meta-analysis of amniotic products, 4/5 trial protocols were designed to change the product weekly. In the fifth trial where changes were left to provider discretion, there was no decease in wound healing.30

Societal Input

National Institute for Health and Care Excellence (NICE) Diabetic foot problems: prevention and management164

The clinical guideline on diabetic foot problems considers dermal or skin substitute grafts as an appropriate addition to standard care in treating diabetic foot ulcers only when healing has not progressed with SOC on the advice of the multidisciplinary foot care service.

International Working Group on the Diabetic Foot (IWGDF)12

IWGDF recommends the consideration of placental-derived products as an adjunctive treatment to the best standard of care when standard care alone has failed to reduce the size of the ulcer. (GRADE Strength of recommendation:

Weak; Quality of evidence: Low). This was based on several studies, including those of moderate bias, suggesting that placenta-derived products may have a beneficial effect on ulcer healing. The authors also state these findings need to be confirmed in large, randomized trials and there is insufficient evidence to support superiority of any product(s).

For topically applied treatments, the IWGDF advises against the use of bioengineered skin products compared to SOC.

For both recommendations, the IWGDF considered the available evidence to be of low quality, and their recommendation was weak (e.g., based on the quality of evidence, balance between benefits and harms, patient values and preferences, and cost or resource utilization).

Wound Healing Society (WHS)5,11

The WHS has published updated evidence-based guidelines on the treatment of diabetic ulcers. Regarding the use of skin substitutes, the WHS concluded that level I evidence suggests that cellular and acellular skin equivalents improve the healing of diabetes-related foot ulcers. In these guidelines Level I required at least 2 RCT supporting the intervention of the guidelines. The quality of evidence was not assessed.

  • In evidence-based guidelines for venous ulcers, the WHS stated that there is evidence that a bi-layered living human skin equivalent, used in conjunction with compression bandaging, increases the incidence and speed of healing for venous ulcers compared with compression and a simple dressing (Level I evidence). The WHS recommends adequate ulcer bed preparation and control of excess bioburden levels prior to application of a biologically active dressing.

They also noted that cultured epithelial autografts or allografts have not been demonstrated to improve stable healing of venous ulcers (Level I). The WHS also stated that there is Level II evidence that a porcine small intestinal submucosal construct may enhance healing of venous ulcers.5

Society for Vascular Surgery/American Podiatric Medical Association/Society for Vascular Medicine (SVS/APMA/SVM)

The SVS/APMA/SVM published a joint evidence-based guideline using Grades of Recommendation Assessment, Development, and Evaluation system for the management of patients with diabetes, including treatment of diabetes related chronic foot ulcers.7

These organizations’ recommendations for diabetic foot ulcers failing to demonstrate improvement (> 50% ulcer area reduction) after a minimum of 4 weeks of standard ulcer therapy include:

  • Adjunctive ulcer therapy options with negative pressure therapy, biologics (platelet-derived growth factor, living cellular therapy, extracellular matrix products, amniotic membrane products) and hyperbaric oxygen therapy. The choice of adjuvant therapy is based on clinical findings, availability of therapy, and cost-effectiveness; there is no recommendation on ordering of therapy choice (Grade 1B).
  • Consideration of living cellular therapy using a bilayer keratinocyte/fibroblast construct or a fibroblast-seeded matrix for treatment of diabetic foot ulcers when the individual is recalcitrant to standard therapy (Grade 2B).
  • Consideration of the use of extracellular matrix products employing acellular human dermis or porcine small intestinal submucosal tissue as an adjunctive therapy for diabetic foot ulcers when the individual is recalcitrant to standard therapy (Grade 2C).

Wound Healing Foundation (WHF)

The WHF published the results of a Consensus Panel on Chronic Wounds composed of dermatology, general surgery, vascular surgery, pediatric surgery, plastic surgery, podiatry, nursing, and wound healing research experts in diverse practice settings. The panel agreed that a chronic wound is designated as a “stalled wound” when it has failed to progress towards healing, following 4 weeks of standard evaluation and management during which identified etiologic factors have been addressed. The importance of treating the underlying condition contributing to the wound development is emphasized as essential for healing. Identified elements in the standard of care (SOC) treatment for these wounds include debridement, infection control, moisture management, dressing and protection, compression in venous and lymphatic ulcers, and offloading. Negative pressure wound therapy, grafting and hyperbaric oxygen are identified as advanced or adjunctive treatment modalities. Decision-making depending on the level of evidence for a specific product and wound type is recommended for cellular and tissue-based products (CTP). Unlike autologous skin grafts, the homologous grafts do not persist and act as a template for cell growth; however, advantages include no donor site, application in office or operating room, possible growth factors and immunomodulators, reduction of insensible water loss and preparation of wound bed for autografting. Disadvantages include prolonged or repeat applications which may delay final grafting and definitive wound coverage. However, the consensus panel did not include the evidence level or qualify the strength of this recommendation.10

 

Analysis of Evidence (Rationale for Determination)

Due to the heterogeneity of randomized controlled trials, poor study designs, small sample sizes, lack of comparators or standardization of practices, lack of long-term efficacy and safety data, and high risk of bias in the current body of literature, there is insufficient evidence to demonstrate efficacy of most skin substitute/CTP in DFU/VLU healing. Moreover, this evidence is challenged by a low level of certainty in the estimated wound-healing effect attributable to these products. Many products have been marketed as substantial equivalents without establishing their role in ulcer healing. Potential risks with these products are not adequately addressed due to lack of long-term safety. Lastly, clinical outcomes have rarely been reported beyond 12 weeks in the current literature, raising additional concern for the durability of the estimated therapeutic benefit(s).

Despite these limitations, a promising trend within the literature towards outcome improvement is identified. Therefore, to be considered reasonable and necessary for coverage, each skin substitute/CTP must demonstrate net positive health outcome(s) in a well-defined patient population. Specifically, wound closure attributable to the individual product(s) proven in clinical trials with meaningful degree of certainty is required. Therefore, a limited coverage position for specific products in specific patient populations has been taken to facilitate access to skin substitute graft/CTP products with clinically meaningful net-positive clinical outcome(s) validated by evidentiary review.

The intent of a skin substitute graft/CTP is to augment wound healing by promotion of skin growth and wound closure. Inherent to this process is stability and adherence of the product which allows it to remain in place to promote skin growth and wound closure with incorporation of the graft. A product requiring removal or replacement without the benefit of incorporation more clearly is characterized as a dressing. There is a trend within the published literature suggesting that products with fewer applications result in shorter closure time. However, direct comparisons of products have not been conducted. Most products resorb into the wound, therefore additional product may be beneficial to facilitate continued wound closure in the event the wound is improving with the use of the skin substitute graft. While there are no studies that directly assess the number of applications required for wound closure, reports throughout the literature suggest the mean closure time is approximately 4 applications within 12 weeks. In the largest reported cohort of 12,313 ulcers treated with skin substitute grafts the mean number of applications was 3.7 with a standard deviation of 3.6.17 Moreover, products evaluated in the evidence review also reported a similar number of applications and time duration. Based on this evidence most ulcers would be expected to close within a maximum of 4 applications and 12 weeks. Ulcer size and immune compromise has been cited by expert opinion as grounds for additional applications secondary to extended time to heal. Therefore, an exception has been added to the policy to ensure that patients who have documented benefit of wound healing with the skin substitute graft use may receive additional applications or duration of care with documented clinical indications. The additional application or extension would be identified with a modifier and documentation in the medical record will be required to explain the clinical rationale for the exception and may be subject to medical review.

There is a clear need for further investigation and understanding of skin substitute grafts and their role in management of chronic wounds such as DFU and VLU. Future investigations will clarify the role of these products, compare products, establish standardized practice for utilization and allow a better understanding of products (and alternative treatments) most beneficial to healing diverse wounds, with the expectation of improved outcomes for patients suffering from these complex conditions.

 

Proposed Process Information

Synopsis of Changes
Changes Fields Changed
Not Applicable N/A
Associated Information
N/A
Sources of Information
N/A
Bibliography
  1. NICE. Chronic wounds: advanced wound dressings and antimicrobial dressings. National Institute for Health Care Excellence. https://www.nice.org.uk/. Published 2016. Accessed 12/14/23.
  2. Pourmoussa A, Gardner DJ, Johnson MB, Wong AK. An update and review of cell-based wound dressings and their integration into clinical practice. Ann Transl Med. 2016;4(23):457.
  3. O'Donnell TF, Jr., Lau J. A systematic review of randomized controlled trials of wound dressings for chronic venous ulcer. J Vasc Surg. 2006;44(5):1118-1125.
  4. Snyder D, Sullivan N, Margolis D, Schoelles K. Skin substitutes for treating chronic wounds. Technology Assessment Program Project ID No. WNDT0818. (Prepared by the ECRI Institute-Penn Medicine Evidence-based Practice Center under Contract No. HHSA 290-2015-00005-I) Skin Substitutes for Treating Chronic Wounds Web site. https://www.ncbi.nlm.nih.gov/pubmed/32101391

Published 2020. Accessed 12/14/23.

  1. Marston W, Tang J, Kirsner RS, Ennis W. Wound Healing Society 2015 update on guidelines for venous ulcers. J Wound repair. 2016;24(1):136-144.
  2. Frykberg R, Banks J. Challenges in the Treatment of Chronic Wounds. J Advances in wound care. 2015;4(9):560-582. doi:doi:10.1089/wound.2015.0635.
  3. Hingorani A, LaMuraglia GM, Henke P, et al. The management of diabetic foot: A clinical practice guideline by the Society for Vascular Surgery in collaboration with the American Podiatric Medical Association and the Society for Vascular Medicine. J Vasc Surg. 2016;63(2 Suppl):3S-21S.
  4. Frykberg R, Cazzell S, Arroyo-Rivera J, et al. Evaluation of tissue engineering products for the management of neuropathic diabetic foot ulcers: an interim analysis. Journal of wound care. 2016;25(Sup7):S18-S25.
  5. O'Donnell TF, Jr., Passman MA, Marston WA, et al. Management of venous leg ulcers: clinical practice guidelines of the Society for Vascular Surgery (R) and the American Venous Forum. J Vasc Surg. 2014;60(2 Suppl):3S-59S.
  6. Eriksson E, Liu PY, Schultz GS, et al. Chronic wounds: Treatment consensus. Wound repair and regeneration. 2022;30(2):156-171.
  7. Lavery LA, Davis KE, Berriman SJ, et al. WHS guidelines update: diabetic foot ulcer treatment guidelines. 2016;24(1):112-126.
  8. Rayman G, Vas P, Dhatariya K, Driver V, Hartemann A, Londahl M. IWGDF Guideline on interventions to enhance healing of foot ulcers in persons with diabetes. https://iwgdfguidelines.org/wp-content/uploads/2021/03/06-Wound-Healing-Guideline.pdf. Published 2019. Accessed.
  9. (AHRQ). AfHRaQ. Evidence-based Practice Center Technical Brief Protocol. Project Title: Skin substitute graft for Treating Chronic Wounds. https://effectivehealthcare.ahrq.gov/products/skin-substitutes/protocol. Published 2018 (rev 2019). Accessed3/15/2023.
  10. FDA. FDA announces comprehensive regenerative medicine policy framework. U.S. Food and Drug Administration. https://www.fda.gov/news-events/press-announcements/fda-announces-comprehensive-regenerative-medicine-policy-framework. Published 2017. Accessed3/15/23.
  11. Schaper NC vNJ, Apelqvist J, Bus SA, Hinchliffe RJ, Lipsky BA; IWGDF Editorial Board. Practical Guidelines on the prevention and management of diabetic foot disease (IWGDF 2019 update). Diabetes Metab Res Rev. 2020 36:Suppl 1:e3266.
  12. Panel CE. CPT 2024. In: Association AM, ed2024.
  13. Armstrong DG, Tettelbach WH, Chang TJ, et al. Observed Impact of Skin Substitutes in Lower Extremity Diabetic Ulcers: A Retrospective Analysis of a Medicare Limited Database (2015-2018). 2021.
  14. Evans K, PJ K. Overview of treatment of chronic wounds. UpToDate. www.uptodate.com. Updated 7/13/22. Accessed 1/10/23.
  15. Widgerow AD. Deconstructing the stalled wound. Wounds: a compendium of clinical research and practice. 2012;24(3):58-66.
  16. Armstrong DG, Boulton AJM, Bus SA. Diabetic Foot Ulcers and Their Recurrence. New England Journal of Medicine. 2017;376(24):2367-2375.
  17. Ferreira MC, Paggiaro AO, Isaac C, Teixeira Neto N, Santos GBd. Skin substitutes: current concepts and a new classification system. Revista Brasileira de Cirurgia Plástica. 2011;26:696-702.
  18. Davison-Kotler E, Sharma V, Kang NV, Garcia-Gareta E. A Universal Classification System of Skin Substitutes Inspired by Factorial Design. Tissue Eng Part B Rev. 2018;24(4):279-288.
  19. Vecin NM, Kirsner RS. Skin substitutes as treatment for chronic wounds: current and future directions. Frontiers in Medicine. 2023;10.
  20. Koob TJ, Lim JJ, Zabek N, Massee M. Cytokines in single layer amnion allografts compared to multilayer amnion/chorion allografts for wound healing. Journal of Biomedical Materials Research Part B: Applied Biomaterials. 2015;103(5):1133-1140.
  21. Vyas KS, Vasconez HC. Wound healing: biologics, skin substitutes, biomembranes and scaffolds. Paper presented at: Healthcare2014.
  22. Winkler J, Abisoye-Ogunniyan A, Metcalf KJ, Werb Z. Concepts of extracellular matrix remodelling in tumour progression and metastasis. Nature communications. 2020;11(1):5120.
  23. Sorber R, Abularrage, Christopher J. Diabetic foot ulcers: Epidemiology and the role of multidisciplinary care teams. Seminars in vascular surgery. 2021;34(1):47-53.
  24. Santema TB, Poyck PP, Ubbink DT. Systematic review and meta-analysis of skin substitutes in the treatment of diabetic foot ulcers: Highlights of a Cochrane systematic review. Wound Repair Regen. 2016;24(4):737-744.
  25. Jones JE NE, Al-Hity A. Skin grafting for venous leg ulcers. Cochrane Database of Systematic Reviews. 2013;Art. No.: CD001737(1).
  26. Haugh AM, Witt JG, Hauch A, et al. Amnion membrane in diabetic foot wounds: a meta-analysis. Plastic and Reconstructive Surgery Global Open. 2017;5(4).
  27. Luthringer M, Mukherjee T, Arguello-Angarita M, Granick MS, Alvarez OM. Human-derived Acellular Dermal Matrix Grafts for Treatment of Diabetic Foot Ulcers: A Systematic Review and Meta-analysis. Wounds. 2020;32(2):57-65.
  28. Guo X, Mu D, Gao F. Efficacy and safety of acellular dermal matrix in diabetic foot ulcer treatment: a systematic review and meta-analysis. International Journal of Surgery. 2017;40:1-7.
  29. Hankin CS, Knispel J, Lopes M, Bronstone A, Maus E. Clinical and cost efficacy of advanced wound care matrices for venous ulcers. Journal of Managed Care Pharmacy. 2012;18(5):375-384.
  30. Serena TE, Yaakov R, Moore S, et al. A randomized controlled clinical trial of a hypothermically stored amniotic membrane for use in diabetic foot ulcers. Journal of Comparative Effectiveness Research. 2020;9(1):23-34.
  31. McQuilling JP, Vines JB, Mowry KC. In vitro assessment of a novel, hypothermically stored amniotic membrane for use in a chronic wound environment. International wound journal. 2017;14(6):993-1005.
  32. Zelen C, Orgill D, Serena T, et al. A prospective, randomised, controlled, multicentre clinical trial examining healing rates, safety and cost to closure of an acellular reticular allogenic human dermis versus standard of care in the treatment of chronic diabetic foot ulcers. Int Wound J. 2017;14(2):307-315.
  33. Zelen CM, Orgill DP, Serena TE, et al. Human Reticular Acellular Dermal Matrix in the Healing of Chronic Diabetic Foot Ulcerations that Failed Standard Conservative Treatment: A Retrospective Crossover Study. Wounds: a Compendium of Clinical Research and Practice. 2017;29(2):39-45.
  34. Barber FA, Aziz-Jacobo J. Biomechanical testing of commercially available soft-tissue augmentation materials. Arthroscopy: the journal of arthroscopic & related surgery. 2009;25(11):1233-1239.
  35. Agrawal H, Tholpady SS, Capito AE, Drake DB, Katz AJ. Macrophage phenotypes correspond with remodeling outcomes of various acellular dermal matrices. Open Journal of Regenerative Medicine. 2012;1(03):51-59.
  36. Dasgupta A, Orgill D, Galiano RD, et al. A novel reticular dermal graft leverages architectural and biological properties to support wound repair. Plastic and Reconstructive Surgery Global Open. 2016;4(10).
  37. Glat P, Orgill DP, Galiano R, et al. Placental Membrane Provides Improved Healing Efficacy and Lower Cost Versus a Tissue-Engineered Human Skin in the Treatment of Diabetic Foot Ulcerations. Plast Reconstr Surg Glob Open. 2019;7(8):e2371.
  38. DiDomenico LA, Orgill DP, Galiano RD, et al. Aseptically processed placental membrane improves healing of diabetic foot ulcerations: prospective, randomized clinical trial. Plastic and Reconstructive Surgery Global Open. 2016;4(10).
  39. DiDomenico LA, Orgill DP, Galiano RD, et al. Use of an aseptically processed, dehydrated human amnion and chorion membrane improves likelihood and rate of healing in chronic diabetic foot ulcers: a prospective, randomised, multi-centre clinical trial in 80 patients. International wound journal. 2018;15(6):950-957.
  40. Snyder RJ, Shimozaki K, Tallis A, et al. A Prospective, Randomized, Multicenter, Controlled Evaluation of the Use of Dehydrated Amniotic Membrane Allograft Compared to Standard of Care for the Closure of Chronic Diabetic Foot Ulcer. Wounds: a compendium of clinical research and practice. 2016;28(3):70-77.
  41. Veves A, Falanga V, Armstrong DG, Sabolinski ML, Apligraf Diabetic Foot Ulcer S. Graftskin, a human skin equivalent, is effective in the management of noninfected neuropathic diabetic foot ulcers: a prospective randomized multicenter clinical trial. Diabetes Care. 2001;24(2):290-295.
  42. Steinberg JS, Edmonds M, Hurley DP, Jr., King WN. Confirmatory data from EU study supports Apligraf for the treatment of neuropathic diabetic foot ulcers. J Am Podiatr Med Assoc. 2010;100(1):73-77.
  43. Edmonds M, European, Australian Apligraf Diabetic Foot Ulcer Study G. Apligraf in the treatment of neuropathic diabetic foot ulcers. Int J Low Extrem Wounds. 2009;8(1):11-18.
  44. Zelen CM, Serena TE, Gould L, et al. Treatment of chronic diabetic lower extremity ulcers with advanced therapies: a prospective, randomised, controlled, multi-centre comparative study examining clinical efficacy and cost. International wound journal. 2016;13(2):272-282.
  45. Kirsner RS, Sabolinski ML, Parsons NB, Skornicki M, Marston WA. Comparative effectiveness of a bioengineered living cellular construct vs. a dehydrated human amniotic membrane allograft for the treatment of diabetic foot ulcers in a real world setting. Wound Repair Regen. 2015;23(5):737-744.
  46. Sledge I, Maislin D, Bernarducci D, Snyder R, Serena TE. Use of a dual-layer amniotic membrane in the treatment of diabetic foot ulcers: an observational study. Journal of Wound Care. 2020;29(Sup9):S8-S12.
  47. Smiell JM, Treaduvell T, Hahn HD. Real-world Experience with a Decellularized Dehydrated Human Amniotic Membrane Allograft. Wounds. 2015;27(6):158-169.
  48. Letendre S, LaPorta G, O'Donnell E, Dempsey J, Leonard K. Pilot trial of biovance collagen-based wound covering for diabetic ulcers. Advances in Skin & Wound Care. 2009;22(4):161-166.
  49. Walters J, Cazzell S, Pham H, Vayser D, Reyzelman A. Healing rates in a multicenter assessment of a sterile, room temperature, acellular dermal matrix versus conventional care wound management and an active comparator in the treatment of full-thickness diabetic foot ulcers. Eplasty. 2016;16.
  50. Cazzell S, Vayser D, Pham H, et al. A randomized clinical trial of a human acellular dermal matrix demonstrated superior healing rates for chronic diabetic foot ulcers over conventional care and an active acellular dermal matrix comparator. Wound Repair Regen. 2017;25(3):483-497.
  51. Cazzell S, Moyer PM, Samsell B, Dorsch K, McLean J, Moore MA. A prospective, multicenter, single-arm clinical trial for treatment of complex diabetic foot ulcers with deep exposure using acellular dermal matrix. Advances in Skin & Wound Care. 2019;32(9):409.
  52. Marston WA, Hanft J, Norwood P, Pollak R, Dermagraft Diabetic Foot Ulcer Study G. The efficacy and safety of Dermagraft in improving the healing of chronic diabetic foot ulcers: results of a prospective randomized trial. Diabetes Care. 2003;26(6):1701-1705.
  53. Gentzkow GD, Iwasaki SD, Hershon KS, et al. Use of dermagraft, a cultured human dermis, to treat diabetic foot ulcers. Diabetes care. 1996;19(4):350-354.
  54. Sanders L, Landsman AS, Landsman A, et al. A prospective, multicenter, randomized, controlled clinical trial comparing a bioengineered skin substitute to a human skin allograft. Ostomy/wound management. 2014;60(9):26-38.
  55. Tettelbach W, Cazzell S, Sigal F, et al. A multicentre prospective randomised controlled comparative parallel study of dehydrated human umbilical cord (EpiCord) allograft for the treatment of diabetic foot ulcers. International wound journal. 2018;16(1):122-130.
  56. Gordon AJ, Alfonso AR, Nicholson J, Chiu ES. Evidence for Healing Diabetic Foot Ulcers With Biologic Skin Substitutes: A Systematic Review and Meta-Analysis. Ann Plast Surg. 2019;83(4S Suppl 1):S31-S44.
  57. Zelen CM, Serena TE, Denoziere G, Fetterolf DE. A prospective randomised comparative parallel study of amniotic membrane wound graft in the management of diabetic foot ulcers. Int Wound J. 2013;10(5):502-507.
  58. Tettelbach W, Cazzell S, Reyzelman AM, Sigal F, Caporusso JM, Agnew PS. A confirmatory study on the efficacy of dehydrated human amnion/chorion membrane dHACM allograft in the management of diabetic foot ulcers: A prospective, multicentre, randomised, controlled study of 110 patients from 14 wound clinics. Int Wound J. 2019;16(1):19-29.
  59. Paggiaro AO, Menezes AG, Ferrassi AD, De Carvalho VF, Gemperli R. Biological effects of amniotic membrane on diabetic foot wounds: a systematic review. Journal of wound care. 2018;27(2):S19-S25.
  60. NICE. EpiFix for chronic wounds National Institute for Health and Care Excellence. https://www.nice.org.uk

Published 2018. Accessed 9/20/23.

  1. Zelen CM, Gould L, Serena TE, Carter MJ, Keller J, Li WW. A prospective, randomised, controlled, multi-centre comparative effectiveness study of healing using dehydrated human amnion/chorion membrane allograft, bioengineered skin substitute or standard of care for treatment of chronic lower extremity diabetic ulcers. Int Wound J. 2015;12(6):724-732.
  2. Lavery L, Fulmer J, Shebetka K, et al. The efficacy and safety of Grafix®) for the treatment of chronic diabetic foot ulcers: results of a multi-centre, controlled, randomised, blinded, clinical trial. Int Wound J. 2014 5:554-560.
  3. Raspovic KM, Wukich DK, Naiman DQ, et al. Effectiveness of viable cryopreserved placental membranes for management of diabetic foot ulcers in a real world setting. Wound Repair and Regeneration. 2018;26(2):213-220.
  4. Frykberg RG, Gibbons GW, Walters JL, Wukich DK, Milstein FC. A prospective, multicentre, open-label, single-arm clinical trial for treatment of chronic complex diabetic foot wounds with exposed tendon and/or bone: positive clinical outcomes of viable cryopreserved human placental membrane. International wound journal. 2017;14(3):569-577.
  5. Brigido SA, Boc SF, Lopez RC. Effective management of major lower extremity wounds using an acellular regenerative tissue matrix: a pilot study. In. Vol 27: SLACK Incorporated Thorofare, NJ; 2004:S145-S149.
  6. Brigido SA. The use of an acellular dermal regenerative tissue matrix in the treatment of lower extremity wounds: a prospective 16-week pilot study. International wound journal. 2006;3(3):181-187.
  7. Reyzelman A, Crews RT, Moore JC, et al. Clinical effectiveness of an acellular dermal regenerative tissue matrix compared to standard wound management in healing diabetic foot ulcers: a prospective, randomised, multicentre study. International wound journal. 2009;6(3):196-208.
  8. Reyzelman A, Bazarov I. Human acellular dermal wound matrix for treatment of DFU: literature review and analysis. Journal of Wound Care. 2015;24(3):128-134.
  9. Driver VR LL, Reyzelman AM, et al. . A clinical trial of Integra Template for diabetic foot ulcer treatment. Wound Repair Regen 2015 23(6):891-900.
  10. Yao M, Attalla K, Ren Y, French MA, Driver VR. Ease of use, safety, and efficacy of integra bilayer wound matrix in the treatment of diabetic foot ulcers in an outpatient clinical setting: a prospective pilot study. Journal of the American Podiatric Medical Association. 2013;103(4):274-280.
  11. Kirsner RS, Margolis DJ, Baldursson BT, et al. Fish skin grafts compared to human amnion/chorion membrane allografts: a double-blind, prospective, randomized clinical trial of acute wound healing. Wound repair and regeneration. 2020;28(1):75-80.
  12. Lullove EJ, Liden B, Winters C, McEneaney P, Raphael A, JC LI. A Multicenter, Blinded, Randomized Controlled Clinical Trial Evaluating the Effect of Omega-3-Rich Fish Skin in the Treatment of Chronic, Nonresponsive Diabetic Foot Ulcers. Wounds: a Compendium of Clinical Research and Practice. 2021;33(7):169-177.
  13. Esmaeili A, Biazar E, Ebrahimi M, Heidari Keshel S, Kheilnezhad B, Saeedi Landi F. Acellular fish skin for wound healing. International Wound Journal. 2023.
  14. Seth N, Chopra D, Lev-Tov H. Fish skin grafts with omega-3 for treatment of chronic wounds: exploring the role of omega-3 fatty acids in wound healing and a review of clinical healing outcomes. Surg Technol Int. 2022;40:38-46.
  15. Manning SW HD, Shillinglaw WR, et al. Efficacy of a Bioresorbable Matrix in Healing Complex Chronic Wounds: An Open-Label Prospective Pilot Study. Wounds. 2020;32(11):309-318.
  16. Solanki AK, Lali FV, Autefage H, et al. Bioactive glasses and electrospun composites that release cobalt to stimulate the HIF pathway for wound healing applications. Biomaterials research. 2021;25:1-16.
  17. Cannio M, Bellucci D, Roether JA, Boccaccini DN, Cannillo V. Bioactive glass applications: A literature review of human clinical trials. Materials. 2021;14(18):5440.
  18. Naseri S, Lepry WC, Nazhat SN. Bioactive glasses in wound healing: hope or hype? Journal of Materials Chemistry B. 2017;5(31):6167-6174.
  19. Armstrong DG, Orgill DP, Galiano RD, et al. A multi-centre, single-blinded randomised controlled clinical trial evaluating the effect of resorbable glass fibre matrix in the treatment of diabetic foot ulcers. Int Wound J. 2022;19(4):791-801.
  20. Marston WA, Lantis 2nd JC, Wu SC, et al. An open-label trial of cryopreserved human umbilical cord in the treatment of complex diabetic foot ulcers complicated by osteomyelitis. Wound Repair and Regeneration. 2019;27(6):680-686.
  21. Marston WA, Lantis JC, Wu SC, et al. One-year safety, healing and amputation rates of Wagner 3-4 diabetic foot ulcers treated with cryopreserved umbilical cord (TTAX01). Wound Repair and Regeneration. 2020;28(4):526-531.
  22. Pacaccio DJ, Cazzell SM, Halperin GJ, et al. Human placental membrane as a wound cover for chronic diabetic foot ulcers: a prospective, postmarket, CLOSURE study. Journal of Wound Care. 2018;27(Sup7):S28-S37.
  23. Cazzell SM, Lange DL, Dickerson JE, Jr., Slade HB. The Management of Diabetic Foot Ulcers with Porcine Small Intestine Submucosa Tri-Layer Matrix: A Randomized Controlled Trial. Adv Wound Care (New Rochelle). 2015;4(12):711-718.
  24. Lantis JC, Snyder R, Reyzelman AM, et al. Fetal bovine acellular dermal matrix for the closure of diabetic foot ulcers: a prospective randomised controlled trial. J Wound Care. 2021;30(Sup7):S18-S27.
  25. Kavros SJ, Dutra T, Gonzalez-Cruz R, et al. The use of PriMatrix, a fetal bovine acellular dermal matrix, in healing chronic diabetic foot ulcers: a prospective multicenter study. Advances in skin & wound care. 2014;27(8):356-362.
  26. Strauss NH, Brietstein RJ. Fetal Bovine Dermal Repair Scaffold Used for the Treatment of Difficult-to-Heal Complex Wounds. Wounds: a Compendium of Clinical Research and Practice. 2012;24(11):327-334.
  27. Karr JC. Retrospective comparison of diabetic foot ulcer and venous stasis ulcer healing outcome between a dermal repair scaffold (PriMatrix) and a bilayered living cell therapy (Apligraf). Advances in skin & wound care. 2011;24(3):119-125.
  28. Lullove E. Acellular fetal bovine dermal matrix in the treatment of nonhealing wounds in patients with complex comorbidities. Journal of the American Podiatric Medical Association. 2012;102(3):233-239.
  29. Bain MA, Koullias GJ, Morse K, Wendling S, Sabolinski ML. Type I collagen matrix plus polyhexamethylene biguanide antimicrobial for the treatment of cutaneous wounds. Journal of Comparative Effectiveness Research. 2020;9(10):691-703.
  30. MacEwan MR, MacEwan S, Kovacs TR, Batts J. What Makes the Optimal Wound Healing Material? A Review of Current Science and Introduction of a Synthetic Nanofabricated Wound Care Scaffold. Cureus. 2017;9(10):e1736.
  31. Regulski MJ, MacEwan MR. Implantable Nanomedical Scaffold Facilitates Healing of Chronic Lower Extremity Wounds. Wounds. 2018;30(8):E77-E80.
  32. Armstrong DG, Galiano RD, Orgill DP, et al. Multi-centre prospective randomised controlled clinical trial to evaluate a bioactive split thickness skin allograft vs standard of care in the treatment of diabetic foot ulcers. International Wound Journal. 2022;19(4):932-944.
  33. DiDomenico L, Landsman AR, Emch KJ, Landsman A. A prospective comparison of diabetic foot ulcers treated with either a cryopreserved skin allograft or a bioengineered skin substitute. Wounds. 2011;23(7):184-189.
  34. Gurtner GC, Garcia AD, Bakewell K, Alarcon JB. A retrospective matched-cohort study of 3994 lower extremity wounds of multiple etiologies across 644 institutions comparing a bioactive human skin allograft, TheraSkin, plus standard of care, to standard of care alone. International Wound Journal. 2020;17(1):55-64.
  35. Barbul A GG, Gordon H, Bakewell K, Carter MJ. Matched-cohort study comparing bioactive human split-thickness skin allograft plus standard of care to standard of care alone in the treatment of diabetic ulcers: A retrospective analysis across 470 institutions. Wound Repair Regen. 2020 28(1):81-89.
  36. Serena TE, Orgill DP, Armstrong DG, et al. A Multicenter Randomized Controlled Clinical Trial Evaluating Two Application Regimens of Dehydrated Human Amniotic Membrane and Standard of Care vs Standard of Care Alone in the Treatment of Venous Leg Ulcers. Plastic and Reconstructive Surgery. 2022.
  37. Falanga V. Apligraf treatment of venous ulcers and other chronic wounds. J Dermatol. 1998;25(12):812-817.
  38. Falanga V, Sabolinski M. A bilayered living skin construct (APLIGRAF) accelerates complete closure of hard-to-heal venous ulcers. Wound Repair Regen. 1999;7(4):201-207.
  39. Towler MA, Rush EW, Richardson MK, Williams CL. Randomized, Prospective, Blinded-Enrollment, Head-To-Head Venous Leg Ulcer Healing Trial Comparing Living, Bioengineered Skin Graft Substitute (Apligraf) with Living, Cryopreserved, Human Skin Allograft (TheraSkin). Clin Podiatr Med Surg. 2018;35(3):357-365.
  40. Cazzell S. A Randomized Controlled Trial Comparing a Human Acellular Dermal Matrix Versus Conventional Care for the Treatment of Venous Leg Ulcers. Wounds. 2019;31(3):68-74.
  41. Harding K SM, Cardinal M. . A prospective, multicentre, randomised controlled study of human fibroblast-derived dermal substitute (Dermagraft) in patients with venous leg ulcers. . Int Wound J. 2013;10(2):132-137.
  42. Serena TE, Carter MJ, Le LT, Sabo MJ, DiMarco DT, EpiFix VLUSG. A multicenter, randomized, controlled clinical trial evaluating the use of dehydrated human amnion/chorion membrane allografts and multilayer compression therapy vs. multilayer compression therapy alone in the treatment of venous leg ulcers. Wound Repair Regen. 2014;22(6):688-693.
  43. Bianchi C, Cazzell S, Vayser D, et al. A multicentre randomised controlled trial evaluating the efficacy of dehydrated human amnion/chorion membrane (EpiFix((R)) ) allograft for the treatment of venous leg ulcers. Int Wound J. 2018;15(1):114-122.
  44. Landsman A, Roukis TS, DeFronzo DJ, Agnew P, Petranto RD, Surprenant M. Living cells or collagen matrix: which is more beneficial in the treatment of diabetic foot ulcers? Wounds: a compendium of clinical research and practice. 2008;20(5):111-116.
  45. Niezgoda JA, Van Gils CC, Frykberg RG, Hodde JP. Randomized clinical trial comparing OASIS Wound Matrix to Regranex Gel for diabetic ulcers. Adv Skin Wound Care. 2005;18(5 Pt 1):258-266.
  46. Romanelli M, Dini V, Bertone MS. Randomized comparison of OASIS wound matrix versus moist wound dressing in the treatment of difficult-to-heal wounds of mixed arterial/venous etiology. Advances in skin & wound care. 2010;23(1):34-38.
  47. Mostow EN, Haraway GD, Dalsing M, Hodde JP, King D, Group OVUS. Effectiveness of an extracellular matrix graft (OASIS Wound Matrix) in the treatment of chronic leg ulcers: a randomized clinical trial. Journal of vascular surgery. 2005;41(5):837-843.
  48. Marston WA, Sabolinski ML, Parsons NB, Kirsner RS. Comparative effectiveness of a bilayered living cellular construct and a porcine collagen wound dressing in the treatment of venous leg ulcers. Wound repair and regeneration. 2014;22(3):334-340.
  49. Tchanque-Fossuo CN, Dahle SE, Lev-Tov H, et al. Cellular versus acellular matrix devices in the treatment of diabetic foot ulcers: Interim results of a comparative efficacy randomized controlled trial. J Tissue Eng Regen Med. 2019;13(8):1430-1437.
  50. Romanelli M, Dini V, Bertone M, Barbanera S, Brilli C. OASIS® wound matrix versus Hyaloskin® in the treatment of difficult-to-heal wounds of mixed arterial/venous aetiology. International wound journal. 2007;4(1):3-7.
  51. Demling RH, Niezgoda JA, Haraway GD, Mostow E. Small intestinal submucosa wound matrix and full-thickness venous ulcers: preliminary results. Wounds. 2004;16(1):18-22.
  52. Kelechi TJ, Mueller M, Hankin CS, Bronstone A, Samies J, Bonham PA. A randomized, investigator-blinded, controlled pilot study to evaluate the safety and efficacy of a poly-N-acetyl glucosamine–derived membrane material in patients with venous leg ulcers. Journal of the American Academy of Dermatology. 2012;66(6):e209-e215.
  53. Maus EA. Successful treatment of two refractory venous stasis ulcers treated with a novel poly-N-acetyl glucosamine-derived membrane. Case Reports. 2012;2012:bcr0320126091.
  54. Sterne JAC SJ, Page MJ, Elbers RG, Blencowe NS, Boutron I, Cates CJ, Cheng H-Y, Corbett MS, Eldridge SM, Hernán MA, Hopewell S, Hróbjartsson A, Junqueira DR, Jüni P, Kirkham JJ, Lasserson T, Li T, McAleenan A, Reeves BC, Shepperd S, Shrier I, Stewart LA, Tilling K, White IR, Whiting PF, Higgins JPT. . RoB 2: a revised tool for assessing risk of bias in randomised trials. . BMJ. 2019:366: l4898.
  55. Higgins JPT SJ, Page MJ, Elbers RG, Sterne JAC. . Chapter 8: Assessing risk of bias in a randomized trial.Cochrane Handbook for Systematic Reviews of Interventions version 6.4 (updated August 2023). Available from www.training.cochrane.org/handbook. Published 2023. Accessed10/10/23.
  56. DiDomenico LA, Orgill DP, Galiano RD, et al. Aseptically Processed Placental Membrane Improves Healing of Diabetic Foot Ulcerations: Prospective, Randomized Clinical Trial. Plast Reconstr Surg Glob Open. 2016;4(10):e1095.
  57. DiDomenico LA, Orgill DP, Galiano RD, et al. Use of an aseptically processed, dehydrated human amnion and chorion membrane improves likelihood and rate of healing in chronic diabetic foot ulcers: A prospective, randomised, multi-centre clinical trial in 80 patients. Int Wound J. 2018;15(6):950-957.
  58. Falanga V, Margolis D, Alvarez O, et al. Rapid healing of venous ulcers and lack of clinical rejection with an allogeneic cultured human skin equivalent. Human Skin Equivalent Investigators Group. Arch Dermatol. 1998;134(3):293-300.
  59. Bianchi C, Tettelbach W, Istwan N, et al. Variations in study outcomes relative to intention-to-treat and per-protocol data analysis techniques in the evaluation of efficacy for treatment of venous leg ulcers with dehydrated human amnion/chorion membrane allograft. Int Wound J. 2019;16(3):761-767.
  60. Zelen CM, Orgill DP, Serena TE, et al. An aseptically processed, acellular, reticular, allogenic human dermis improves healing in diabetic foot ulcers: A prospective, randomised, controlled, multicentre follow-up trial. Int Wound J. 2018;15(5):731-739.
  61. Huang W, Chen Y, Wang N, Yin G, Wei C, Xu W. The efficacy and safety of acellular matrix therapy for diabetic foot ulcers: a meta-analysis of randomized clinical trials. Journal of Diabetes Research. 2020;2020.
  62. Landsman A, Rosines E, Houck A, et al. Characterization of a cryopreserved split-thickness human skin allograft–TheraSkin. Advances in Skin & Wound Care. 2016;29(9):399-406.
  63. Lambert N, Vinke E, Barrett T, Regulski M. Application of Amniotic Membrane Allografts in Advanced Venous Leg Ulcer: A Case Study and Literature Review. 2022.
  64. Rodríguez I AA, Massey C, et al. . Novel bioengineered collagen with Manuka honey and hydroxyapatite sheet for the treatment of lower extremity chronic wounds in an urban hospital wound care setting. . Wounds 2023;35(1):E35-E38.
  65. Rodriguez IA SA, Weinstein R, et al. . Preliminary Clinical Evaluation Using a Novel Bioengineered Wound Product to Treat Lower Extremity Ulcers. The International Journal of Lower Extremity Wounds 2020;1(22):139-145.
  66. Sledge I, Maislin D, Bernarducci D, Snyder R, Serena TE. Use of a dual-layer amniotic membrane in the treatment of diabetic foot ulcers: an observational study. J Wound Care. 2020;29(Sup9):S8-S12.
  67. Singh R, Chacharkar M. Dried gamma-irradiated amniotic membrane as dressing in burn wound care. Journal of Tissue Viability. 2011;20(2):49-54.
  68. Kraemer BA, Geiger SE, Deigni OA, Watson JT. Management of Open Lower Extremity Wounds With Concomitant Fracture Using a Porcine Urinary Bladder Matrix. Wounds: a Compendium of Clinical Research and Practice. 2016;28(11):387-394.
  69. Geiger SE, Deigni OA, Watson JT, Kraemer BA. Management of Open Distal Lower Extremity Wounds With Exposed Tendons Using Porcine Urinary Bladder Matrix. Wounds: a Compendium of Clinical Research and Practice. 2016;28(9):306-316.
  70. Ditmars FS, Lind RA, Broderick TC, Fagg WS. Safety and efficacy of acellular human amniotic fluid and membrane in the treatment of non-healing wounds in a patient with chronic venous insufficiency. SAGE Open Med Case Rep. 2022;10:2050313X221100882.
  71. Kimmel H, Gittleman H. Retrospective observational analysis of the use of an architecturally unique dermal regeneration template (Derma Pure®) for the treatment of hard-to-heal wounds. International wound journal. 2017;14(4):666-672.
  72. Ganesh P, Puranik S, Abhaya M, Misra P, Guruvigneshwari M, Daniel JI. Connective tissue matrices from placental disc for wound healing: mini-review. Biotechnology Letters. 2023:1-9.
  73. Schwartz J, Koutsoumbelis S, Parikh Z, et al. The use of human amnion/chorion for the enhancement of collagen synthesis and acceleration of wound healing in a diabetic rat model. Regenerative Engineering and Translational Medicine. 2021;7:41-46.
  74. Arif MMA, Fauzi MB, Nordin A, Hiraoka Y, Tabata Y, Yunus MHM. Fabrication of bio-based gelatin sponge for potential use as a functional acellular skin substitute. Polymers. 2020;12(11):2678.
  75. Sivak WN, Bourne DA, Miller MP, Manders EK. Simplified calvarial reconstruction: coverage of bare skull with gammagraft promotes granulation and facilitates skin grafting. Journal of Craniofacial Surgery. 2016;27(7):1808-1809.
  76. Caravaggi C, Grigoletto F, Scuderi N. Wound Bed Preparation With a Dermal Substitute (Hyalomatrix(R) PA) Facilitates Re-epithelialization and Healing: Results of a Multicenter, Prospective, Observational Study on Complex Chronic Ulcers (The FAST Study). Wounds. 2011;23(8):228-235.
  77. Motolese A, Vignati F, Brambilla R, Cerati M, Passi A. Interaction between a regenerative matrix and wound bed in nonhealing ulcers: results with 16 cases. Biomed Res Int. 2013;2013:849321.
  78. Simman R, Mari W, Younes S, Wilson M. Use of Hyaluronic Acid-Based Biological Bilaminar Matrix in Wound Bed Preparation: A Case Series. Eplasty. 2018;18:e10.
  79. Caravaggi C, Sganzaroli A, Pogliaghi I, Cavaiani P, Fabbi M, Ferraresi R. Safety and efficacy of a dermal substitute in the coverage of cancellous bone after surgical debridement for severe diabetic foot ulceration. EWMA Journal. 2009;9(1).
  80. Simman R, Hermans MHE. Managing Wounds with Exposed Bone and Tendon with an Esterified Hyaluronic Acid Matrix (eHAM): A Literature Review and Personal Experience. J Am Coll Clin Wound Spec. 2017;9(1-3):1-9.
  81. Fairbairn NG RM, Redmond RW. . The clinical applications of human amnion in plastic surgery. . J Plast Reconstr Aesthet Surg 2014;67(5):662-675.
  82. Rice AH, Mallory Przbylski D. A Closer Look At Acellular Dermal Matrices For Chronic Diabetic Foot Ulcers. Podiatry Today. 2012;25(11).
  83. Fridman R, Engelhardt J. A pilot study to evaluate the effects of perfusion-decellularized porcine hepatic-derived wound matrix on difficult-to-heal diabetic foot ulcers. Wounds: a Compendium of Clinical Research and Practice. 2017;29(10):317-323.
  84. Fridman R, Rafat P, Van Gils CC, Horn D, Vayser D, Lambert Jr JC. Treatment of Hard-to-heal Diabetic Foot Ulcers With a Hepatic-derived Wound Matrix. Wounds: a compendium of clinical research and practice. 2020;32(9):244-252.
  85. Buck DW. Innovative bioactive glass fiber technology accelerates wound healing and minimizes costs: a case series. Advances in Skin & Wound Care. 2020;33(8):1-6.
  86. J. S. Use of Cryopreserved, Particulate Human Amniotic Membrane and Umbilical Cord (AM/UC) Tissue: A Case Series Study for Application in the Healing of Chronic Wounds. Surg Technol Int. 2014;25:73-78.
  87. Greenwood J, Wagstaff M. The use of biodegradable polyurethane in the development of dermal scaffolds. In: Advances in Polyurethane Biomaterials. Elsevier; 2016:631-662.
  88. Greenwood JE DB. Split skin graft application over an integrating, biodegradable temporizing polymer matrix: immediate and delayed. J Burn Care Res. 2012;33(1):7-19.
  89. Tursi FJ, Donnelly JV, Seiler DR. An Integrative Approach To Healing Diabetic Foot Wounds. Podiatry Today. 2019;32(6).
  90. Caporusso J, Abdo R, Karr J, Smith M, Anaim A. Clinical experience using a dehydrated amnion/chorion membrane construct for the management of wounds. Wounds. 2019;31(4 Suppl):S19-S27.
  91. Yamada S, Yamamoto K, Ikeda T, Yanagiguchi K, Hayashi Y. Potency of fish collagen as a scaffold for regenerative medicine. BioMed research international. 2014;2014.
  92. Panggabean JA, Adiguna SbP, Hardhiyuna M, et al. Cutting Edge Aquatic-Based Collagens in Tissue Engineering. Marine Drugs. 2023;21(2):87.
  93. Koullias GJ. Efficacy of the Application of a Purified Native Collagen With Embedded Antimicrobial Barrier Followed by a Placental Allograft on a Diverse Group of Nonhealing Wounds of Various Etiologies. Wounds: a Compendium of Clinical Research and Practice. 2021;33(1):20-27.
  94. Lintzeris D, Vernon K, Percise H, et al. Effect of a New Purified Collagen Matrix With Polyhexamethylene Biguanide on Recalcitrant Wounds of Various Etiologies: A Case Series. Wounds. 2018;30(3):72-78.
  95. Oropallo AR. Use of native type I collagen matrix plus polyhexamethylene biguanide for chronic wound treatment. Plastic and Reconstructive Surgery Global Open. 2019;7(1).
  96. Durham EL, Howie RN, Hall S, et al. Optimizing bone wound healing using BMP2 with absorbable collagen sponge and Talymed nanofiber scaffold. Journal of translational medicine. 2018;16(1):1-8.
  97. Howie RN, Durham E, Oakes B, et al. Testing a novel nanofibre scaffold for utility in bone tissue regeneration. Journal of tissue engineering and regenerative medicine. 2018;12(10):2055-2066.
  98. Mulder G, Lee DK. Case presentation: xenograft resistance to protease degradation in a vasculitic ulcer. The International Journal of Lower Extremity Wounds. 2009;8(3):157-161.
  99. Lullove EJ. Use of a dehydrated amniotic membrane allograft in the treatment of lower extremity wounds: a retrospective cohort study. Wounds: a Compendium of Clinical Research and Practice. 2017;29(11):346-351.
  100. NICE. Diabetic foot problems: Prevention and management National Institute for Health and Care Excellence. https://www.nice.org.uk. Published 2019. Accessed 12/14/23.

 

Open Meetings
Meeting Date Meeting States Meeting Information
05/16/2024 American Samoa
California - Entire State
California - Northern
California - Southern
Guam
Hawaii
Nevada
Northern Mariana Islands

Teleconference only

N/A
Contractor Advisory Committee (CAC) Meetings
Meeting Date Meeting States Meeting Information
N/A
MAC Meeting Information URLs
N/A
Proposed LCD Posting Date
04/25/2024
Comment Period Start Date
04/25/2024
Comment Period End Date
06/08/2024
Reason for Proposed LCD
  • Provider Education/Guidance
Requestor Information
This request was MAC initiated.
Requestor Name Requestor Letter
View Letter
N/A
Contact for Comments on Proposed LCD
Noridian Healthcare Solutions, LLC JE Part B Contractor Medical Director(s)
Attention: Draft LCD Comments
PO Box 6781
Fargo, ND 58108-6781
policydraft@noridian.com

Coding Information

Bill Type Codes

Code Description

Please accept the License to see the codes.

N/A

Revenue Codes

Code Description

Please accept the License to see the codes.

N/A

CPT/HCPCS Codes

Please accept the License to see the codes.

N/A

ICD-10-CM Codes that Support Medical Necessity

Group 1

Group 1 Paragraph:

N/A

Group 1 Codes:

N/A

N/A

ICD-10-CM Codes that DO NOT Support Medical Necessity

Group 1

Group 1 Paragraph:

N/A

Group 1 Codes:

N/A

N/A

Additional ICD-10 Information

General Information

Associated Information
N/A
Sources of Information
N/A
Bibliography
  1. NICE. Chronic wounds: advanced wound dressings and antimicrobial dressings. National Institute for Health Care Excellence. https://www.nice.org.uk/. Published 2016. Accessed 12/14/23.
  2. Pourmoussa A, Gardner DJ, Johnson MB, Wong AK. An update and review of cell-based wound dressings and their integration into clinical practice. Ann Transl Med. 2016;4(23):457.
  3. O'Donnell TF, Jr., Lau J. A systematic review of randomized controlled trials of wound dressings for chronic venous ulcer. J Vasc Surg. 2006;44(5):1118-1125.
  4. Snyder D, Sullivan N, Margolis D, Schoelles K. Skin substitutes for treating chronic wounds. Technology Assessment Program Project ID No. WNDT0818. (Prepared by the ECRI Institute-Penn Medicine Evidence-based Practice Center under Contract No. HHSA 290-2015-00005-I) Skin Substitutes for Treating Chronic Wounds Web site. https://www.ncbi.nlm.nih.gov/pubmed/32101391

Published 2020. Accessed 12/14/23.

  1. Marston W, Tang J, Kirsner RS, Ennis W. Wound Healing Society 2015 update on guidelines for venous ulcers. J Wound repair. 2016;24(1):136-144.
  2. Frykberg R, Banks J. Challenges in the Treatment of Chronic Wounds. J Advances in wound care. 2015;4(9):560-582. doi:doi:10.1089/wound.2015.0635.
  3. Hingorani A, LaMuraglia GM, Henke P, et al. The management of diabetic foot: A clinical practice guideline by the Society for Vascular Surgery in collaboration with the American Podiatric Medical Association and the Society for Vascular Medicine. J Vasc Surg. 2016;63(2 Suppl):3S-21S.
  4. Frykberg R, Cazzell S, Arroyo-Rivera J, et al. Evaluation of tissue engineering products for the management of neuropathic diabetic foot ulcers: an interim analysis. Journal of wound care. 2016;25(Sup7):S18-S25.
  5. O'Donnell TF, Jr., Passman MA, Marston WA, et al. Management of venous leg ulcers: clinical practice guidelines of the Society for Vascular Surgery (R) and the American Venous Forum. J Vasc Surg. 2014;60(2 Suppl):3S-59S.
  6. Eriksson E, Liu PY, Schultz GS, et al. Chronic wounds: Treatment consensus. Wound repair and regeneration. 2022;30(2):156-171.
  7. Lavery LA, Davis KE, Berriman SJ, et al. WHS guidelines update: diabetic foot ulcer treatment guidelines. 2016;24(1):112-126.
  8. Rayman G, Vas P, Dhatariya K, Driver V, Hartemann A, Londahl M. IWGDF Guideline on interventions to enhance healing of foot ulcers in persons with diabetes. https://iwgdfguidelines.org/wp-content/uploads/2021/03/06-Wound-Healing-Guideline.pdf. Published 2019. Accessed.
  9. (AHRQ). AfHRaQ. Evidence-based Practice Center Technical Brief Protocol. Project Title: Skin substitute graft for Treating Chronic Wounds. https://effectivehealthcare.ahrq.gov/products/skin-substitutes/protocol. Published 2018 (rev 2019). Accessed3/15/2023.
  10. FDA. FDA announces comprehensive regenerative medicine policy framework. U.S. Food and Drug Administration. https://www.fda.gov/news-events/press-announcements/fda-announces-comprehensive-regenerative-medicine-policy-framework. Published 2017. Accessed3/15/23.
  11. Schaper NC vNJ, Apelqvist J, Bus SA, Hinchliffe RJ, Lipsky BA; IWGDF Editorial Board. Practical Guidelines on the prevention and management of diabetic foot disease (IWGDF 2019 update). Diabetes Metab Res Rev. 2020 36:Suppl 1:e3266.
  12. Panel CE. CPT 2024. In: Association AM, ed2024.
  13. Armstrong DG, Tettelbach WH, Chang TJ, et al. Observed Impact of Skin Substitutes in Lower Extremity Diabetic Ulcers: A Retrospective Analysis of a Medicare Limited Database (2015-2018). 2021.
  14. Evans K, PJ K. Overview of treatment of chronic wounds. UpToDate. www.uptodate.com. Updated 7/13/22. Accessed 1/10/23.
  15. Widgerow AD. Deconstructing the stalled wound. Wounds: a compendium of clinical research and practice. 2012;24(3):58-66.
  16. Armstrong DG, Boulton AJM, Bus SA. Diabetic Foot Ulcers and Their Recurrence. New England Journal of Medicine. 2017;376(24):2367-2375.
  17. Ferreira MC, Paggiaro AO, Isaac C, Teixeira Neto N, Santos GBd. Skin substitutes: current concepts and a new classification system. Revista Brasileira de Cirurgia Plástica. 2011;26:696-702.
  18. Davison-Kotler E, Sharma V, Kang NV, Garcia-Gareta E. A Universal Classification System of Skin Substitutes Inspired by Factorial Design. Tissue Eng Part B Rev. 2018;24(4):279-288.
  19. Vecin NM, Kirsner RS. Skin substitutes as treatment for chronic wounds: current and future directions. Frontiers in Medicine. 2023;10.
  20. Koob TJ, Lim JJ, Zabek N, Massee M. Cytokines in single layer amnion allografts compared to multilayer amnion/chorion allografts for wound healing. Journal of Biomedical Materials Research Part B: Applied Biomaterials. 2015;103(5):1133-1140.
  21. Vyas KS, Vasconez HC. Wound healing: biologics, skin substitutes, biomembranes and scaffolds. Paper presented at: Healthcare2014.
  22. Winkler J, Abisoye-Ogunniyan A, Metcalf KJ, Werb Z. Concepts of extracellular matrix remodelling in tumour progression and metastasis. Nature communications. 2020;11(1):5120.
  23. Sorber R, Abularrage, Christopher J. Diabetic foot ulcers: Epidemiology and the role of multidisciplinary care teams. Seminars in vascular surgery. 2021;34(1):47-53.
  24. Santema TB, Poyck PP, Ubbink DT. Systematic review and meta-analysis of skin substitutes in the treatment of diabetic foot ulcers: Highlights of a Cochrane systematic review. Wound Repair Regen. 2016;24(4):737-744.
  25. Jones JE NE, Al-Hity A. Skin grafting for venous leg ulcers. Cochrane Database of Systematic Reviews. 2013;Art. No.: CD001737(1).
  26. Haugh AM, Witt JG, Hauch A, et al. Amnion membrane in diabetic foot wounds: a meta-analysis. Plastic and Reconstructive Surgery Global Open. 2017;5(4).
  27. Luthringer M, Mukherjee T, Arguello-Angarita M, Granick MS, Alvarez OM. Human-derived Acellular Dermal Matrix Grafts for Treatment of Diabetic Foot Ulcers: A Systematic Review and Meta-analysis. Wounds. 2020;32(2):57-65.
  28. Guo X, Mu D, Gao F. Efficacy and safety of acellular dermal matrix in diabetic foot ulcer treatment: a systematic review and meta-analysis. International Journal of Surgery. 2017;40:1-7.
  29. Hankin CS, Knispel J, Lopes M, Bronstone A, Maus E. Clinical and cost efficacy of advanced wound care matrices for venous ulcers. Journal of Managed Care Pharmacy. 2012;18(5):375-384.
  30. Serena TE, Yaakov R, Moore S, et al. A randomized controlled clinical trial of a hypothermically stored amniotic membrane for use in diabetic foot ulcers. Journal of Comparative Effectiveness Research. 2020;9(1):23-34.
  31. McQuilling JP, Vines JB, Mowry KC. In vitro assessment of a novel, hypothermically stored amniotic membrane for use in a chronic wound environment. International wound journal. 2017;14(6):993-1005.
  32. Zelen C, Orgill D, Serena T, et al. A prospective, randomised, controlled, multicentre clinical trial examining healing rates, safety and cost to closure of an acellular reticular allogenic human dermis versus standard of care in the treatment of chronic diabetic foot ulcers. Int Wound J. 2017;14(2):307-315.
  33. Zelen CM, Orgill DP, Serena TE, et al. Human Reticular Acellular Dermal Matrix in the Healing of Chronic Diabetic Foot Ulcerations that Failed Standard Conservative Treatment: A Retrospective Crossover Study. Wounds: a Compendium of Clinical Research and Practice. 2017;29(2):39-45.
  34. Barber FA, Aziz-Jacobo J. Biomechanical testing of commercially available soft-tissue augmentation materials. Arthroscopy: the journal of arthroscopic & related surgery. 2009;25(11):1233-1239.
  35. Agrawal H, Tholpady SS, Capito AE, Drake DB, Katz AJ. Macrophage phenotypes correspond with remodeling outcomes of various acellular dermal matrices. Open Journal of Regenerative Medicine. 2012;1(03):51-59.
  36. Dasgupta A, Orgill D, Galiano RD, et al. A novel reticular dermal graft leverages architectural and biological properties to support wound repair. Plastic and Reconstructive Surgery Global Open. 2016;4(10).
  37. Glat P, Orgill DP, Galiano R, et al. Placental Membrane Provides Improved Healing Efficacy and Lower Cost Versus a Tissue-Engineered Human Skin in the Treatment of Diabetic Foot Ulcerations. Plast Reconstr Surg Glob Open. 2019;7(8):e2371.
  38. DiDomenico LA, Orgill DP, Galiano RD, et al. Aseptically processed placental membrane improves healing of diabetic foot ulcerations: prospective, randomized clinical trial. Plastic and Reconstructive Surgery Global Open. 2016;4(10).
  39. DiDomenico LA, Orgill DP, Galiano RD, et al. Use of an aseptically processed, dehydrated human amnion and chorion membrane improves likelihood and rate of healing in chronic diabetic foot ulcers: a prospective, randomised, multi-centre clinical trial in 80 patients. International wound journal. 2018;15(6):950-957.
  40. Snyder RJ, Shimozaki K, Tallis A, et al. A Prospective, Randomized, Multicenter, Controlled Evaluation of the Use of Dehydrated Amniotic Membrane Allograft Compared to Standard of Care for the Closure of Chronic Diabetic Foot Ulcer. Wounds: a compendium of clinical research and practice. 2016;28(3):70-77.
  41. Veves A, Falanga V, Armstrong DG, Sabolinski ML, Apligraf Diabetic Foot Ulcer S. Graftskin, a human skin equivalent, is effective in the management of noninfected neuropathic diabetic foot ulcers: a prospective randomized multicenter clinical trial. Diabetes Care. 2001;24(2):290-295.
  42. Steinberg JS, Edmonds M, Hurley DP, Jr., King WN. Confirmatory data from EU study supports Apligraf for the treatment of neuropathic diabetic foot ulcers. J Am Podiatr Med Assoc. 2010;100(1):73-77.
  43. Edmonds M, European, Australian Apligraf Diabetic Foot Ulcer Study G. Apligraf in the treatment of neuropathic diabetic foot ulcers. Int J Low Extrem Wounds. 2009;8(1):11-18.
  44. Zelen CM, Serena TE, Gould L, et al. Treatment of chronic diabetic lower extremity ulcers with advanced therapies: a prospective, randomised, controlled, multi-centre comparative study examining clinical efficacy and cost. International wound journal. 2016;13(2):272-282.
  45. Kirsner RS, Sabolinski ML, Parsons NB, Skornicki M, Marston WA. Comparative effectiveness of a bioengineered living cellular construct vs. a dehydrated human amniotic membrane allograft for the treatment of diabetic foot ulcers in a real world setting. Wound Repair Regen. 2015;23(5):737-744.
  46. Sledge I, Maislin D, Bernarducci D, Snyder R, Serena TE. Use of a dual-layer amniotic membrane in the treatment of diabetic foot ulcers: an observational study. Journal of Wound Care. 2020;29(Sup9):S8-S12.
  47. Smiell JM, Treaduvell T, Hahn HD. Real-world Experience with a Decellularized Dehydrated Human Amniotic Membrane Allograft. Wounds. 2015;27(6):158-169.
  48. Letendre S, LaPorta G, O'Donnell E, Dempsey J, Leonard K. Pilot trial of biovance collagen-based wound covering for diabetic ulcers. Advances in Skin & Wound Care. 2009;22(4):161-166.
  49. Walters J, Cazzell S, Pham H, Vayser D, Reyzelman A. Healing rates in a multicenter assessment of a sterile, room temperature, acellular dermal matrix versus conventional care wound management and an active comparator in the treatment of full-thickness diabetic foot ulcers. Eplasty. 2016;16.
  50. Cazzell S, Vayser D, Pham H, et al. A randomized clinical trial of a human acellular dermal matrix demonstrated superior healing rates for chronic diabetic foot ulcers over conventional care and an active acellular dermal matrix comparator. Wound Repair Regen. 2017;25(3):483-497.
  51. Cazzell S, Moyer PM, Samsell B, Dorsch K, McLean J, Moore MA. A prospective, multicenter, single-arm clinical trial for treatment of complex diabetic foot ulcers with deep exposure using acellular dermal matrix. Advances in Skin & Wound Care. 2019;32(9):409.
  52. Marston WA, Hanft J, Norwood P, Pollak R, Dermagraft Diabetic Foot Ulcer Study G. The efficacy and safety of Dermagraft in improving the healing of chronic diabetic foot ulcers: results of a prospective randomized trial. Diabetes Care. 2003;26(6):1701-1705.
  53. Gentzkow GD, Iwasaki SD, Hershon KS, et al. Use of dermagraft, a cultured human dermis, to treat diabetic foot ulcers. Diabetes care. 1996;19(4):350-354.
  54. Sanders L, Landsman AS, Landsman A, et al. A prospective, multicenter, randomized, controlled clinical trial comparing a bioengineered skin substitute to a human skin allograft. Ostomy/wound management. 2014;60(9):26-38.
  55. Tettelbach W, Cazzell S, Sigal F, et al. A multicentre prospective randomised controlled comparative parallel study of dehydrated human umbilical cord (EpiCord) allograft for the treatment of diabetic foot ulcers. International wound journal. 2018;16(1):122-130.
  56. Gordon AJ, Alfonso AR, Nicholson J, Chiu ES. Evidence for Healing Diabetic Foot Ulcers With Biologic Skin Substitutes: A Systematic Review and Meta-Analysis. Ann Plast Surg. 2019;83(4S Suppl 1):S31-S44.
  57. Zelen CM, Serena TE, Denoziere G, Fetterolf DE. A prospective randomised comparative parallel study of amniotic membrane wound graft in the management of diabetic foot ulcers. Int Wound J. 2013;10(5):502-507.
  58. Tettelbach W, Cazzell S, Reyzelman AM, Sigal F, Caporusso JM, Agnew PS. A confirmatory study on the efficacy of dehydrated human amnion/chorion membrane dHACM allograft in the management of diabetic foot ulcers: A prospective, multicentre, randomised, controlled study of 110 patients from 14 wound clinics. Int Wound J. 2019;16(1):19-29.
  59. Paggiaro AO, Menezes AG, Ferrassi AD, De Carvalho VF, Gemperli R. Biological effects of amniotic membrane on diabetic foot wounds: a systematic review. Journal of wound care. 2018;27(2):S19-S25.
  60. NICE. EpiFix for chronic wounds National Institute for Health and Care Excellence. https://www.nice.org.uk

Published 2018. Accessed 9/20/23.

  1. Zelen CM, Gould L, Serena TE, Carter MJ, Keller J, Li WW. A prospective, randomised, controlled, multi-centre comparative effectiveness study of healing using dehydrated human amnion/chorion membrane allograft, bioengineered skin substitute or standard of care for treatment of chronic lower extremity diabetic ulcers. Int Wound J. 2015;12(6):724-732.
  2. Lavery L, Fulmer J, Shebetka K, et al. The efficacy and safety of Grafix®) for the treatment of chronic diabetic foot ulcers: results of a multi-centre, controlled, randomised, blinded, clinical trial. Int Wound J. 2014 5:554-560.
  3. Raspovic KM, Wukich DK, Naiman DQ, et al. Effectiveness of viable cryopreserved placental membranes for management of diabetic foot ulcers in a real world setting. Wound Repair and Regeneration. 2018;26(2):213-220.
  4. Frykberg RG, Gibbons GW, Walters JL, Wukich DK, Milstein FC. A prospective, multicentre, open-label, single-arm clinical trial for treatment of chronic complex diabetic foot wounds with exposed tendon and/or bone: positive clinical outcomes of viable cryopreserved human placental membrane. International wound journal. 2017;14(3):569-577.
  5. Brigido SA, Boc SF, Lopez RC. Effective management of major lower extremity wounds using an acellular regenerative tissue matrix: a pilot study. In. Vol 27: SLACK Incorporated Thorofare, NJ; 2004:S145-S149.
  6. Brigido SA. The use of an acellular dermal regenerative tissue matrix in the treatment of lower extremity wounds: a prospective 16-week pilot study. International wound journal. 2006;3(3):181-187.
  7. Reyzelman A, Crews RT, Moore JC, et al. Clinical effectiveness of an acellular dermal regenerative tissue matrix compared to standard wound management in healing diabetic foot ulcers: a prospective, randomised, multicentre study. International wound journal. 2009;6(3):196-208.
  8. Reyzelman A, Bazarov I. Human acellular dermal wound matrix for treatment of DFU: literature review and analysis. Journal of Wound Care. 2015;24(3):128-134.
  9. Driver VR LL, Reyzelman AM, et al. . A clinical trial of Integra Template for diabetic foot ulcer treatment. Wound Repair Regen 2015 23(6):891-900.
  10. Yao M, Attalla K, Ren Y, French MA, Driver VR. Ease of use, safety, and efficacy of integra bilayer wound matrix in the treatment of diabetic foot ulcers in an outpatient clinical setting: a prospective pilot study. Journal of the American Podiatric Medical Association. 2013;103(4):274-280.
  11. Kirsner RS, Margolis DJ, Baldursson BT, et al. Fish skin grafts compared to human amnion/chorion membrane allografts: a double-blind, prospective, randomized clinical trial of acute wound healing. Wound repair and regeneration. 2020;28(1):75-80.
  12. Lullove EJ, Liden B, Winters C, McEneaney P, Raphael A, JC LI. A Multicenter, Blinded, Randomized Controlled Clinical Trial Evaluating the Effect of Omega-3-Rich Fish Skin in the Treatment of Chronic, Nonresponsive Diabetic Foot Ulcers. Wounds: a Compendium of Clinical Research and Practice. 2021;33(7):169-177.
  13. Esmaeili A, Biazar E, Ebrahimi M, Heidari Keshel S, Kheilnezhad B, Saeedi Landi F. Acellular fish skin for wound healing. International Wound Journal. 2023.
  14. Seth N, Chopra D, Lev-Tov H. Fish skin grafts with omega-3 for treatment of chronic wounds: exploring the role of omega-3 fatty acids in wound healing and a review of clinical healing outcomes. Surg Technol Int. 2022;40:38-46.
  15. Manning SW HD, Shillinglaw WR, et al. Efficacy of a Bioresorbable Matrix in Healing Complex Chronic Wounds: An Open-Label Prospective Pilot Study. Wounds. 2020;32(11):309-318.
  16. Solanki AK, Lali FV, Autefage H, et al. Bioactive glasses and electrospun composites that release cobalt to stimulate the HIF pathway for wound healing applications. Biomaterials research. 2021;25:1-16.
  17. Cannio M, Bellucci D, Roether JA, Boccaccini DN, Cannillo V. Bioactive glass applications: A literature review of human clinical trials. Materials. 2021;14(18):5440.
  18. Naseri S, Lepry WC, Nazhat SN. Bioactive glasses in wound healing: hope or hype? Journal of Materials Chemistry B. 2017;5(31):6167-6174.
  19. Armstrong DG, Orgill DP, Galiano RD, et al. A multi-centre, single-blinded randomised controlled clinical trial evaluating the effect of resorbable glass fibre matrix in the treatment of diabetic foot ulcers. Int Wound J. 2022;19(4):791-801.
  20. Marston WA, Lantis 2nd JC, Wu SC, et al. An open-label trial of cryopreserved human umbilical cord in the treatment of complex diabetic foot ulcers complicated by osteomyelitis. Wound Repair and Regeneration. 2019;27(6):680-686.
  21. Marston WA, Lantis JC, Wu SC, et al. One-year safety, healing and amputation rates of Wagner 3-4 diabetic foot ulcers treated with cryopreserved umbilical cord (TTAX01). Wound Repair and Regeneration. 2020;28(4):526-531.
  22. Pacaccio DJ, Cazzell SM, Halperin GJ, et al. Human placental membrane as a wound cover for chronic diabetic foot ulcers: a prospective, postmarket, CLOSURE study. Journal of Wound Care. 2018;27(Sup7):S28-S37.
  23. Cazzell SM, Lange DL, Dickerson JE, Jr., Slade HB. The Management of Diabetic Foot Ulcers with Porcine Small Intestine Submucosa Tri-Layer Matrix: A Randomized Controlled Trial. Adv Wound Care (New Rochelle). 2015;4(12):711-718.
  24. Lantis JC, Snyder R, Reyzelman AM, et al. Fetal bovine acellular dermal matrix for the closure of diabetic foot ulcers: a prospective randomised controlled trial. J Wound Care. 2021;30(Sup7):S18-S27.
  25. Kavros SJ, Dutra T, Gonzalez-Cruz R, et al. The use of PriMatrix, a fetal bovine acellular dermal matrix, in healing chronic diabetic foot ulcers: a prospective multicenter study. Advances in skin & wound care. 2014;27(8):356-362.
  26. Strauss NH, Brietstein RJ. Fetal Bovine Dermal Repair Scaffold Used for the Treatment of Difficult-to-Heal Complex Wounds. Wounds: a Compendium of Clinical Research and Practice. 2012;24(11):327-334.
  27. Karr JC. Retrospective comparison of diabetic foot ulcer and venous stasis ulcer healing outcome between a dermal repair scaffold (PriMatrix) and a bilayered living cell therapy (Apligraf). Advances in skin & wound care. 2011;24(3):119-125.
  28. Lullove E. Acellular fetal bovine dermal matrix in the treatment of nonhealing wounds in patients with complex comorbidities. Journal of the American Podiatric Medical Association. 2012;102(3):233-239.
  29. Bain MA, Koullias GJ, Morse K, Wendling S, Sabolinski ML. Type I collagen matrix plus polyhexamethylene biguanide antimicrobial for the treatment of cutaneous wounds. Journal of Comparative Effectiveness Research. 2020;9(10):691-703.
  30. MacEwan MR, MacEwan S, Kovacs TR, Batts J. What Makes the Optimal Wound Healing Material? A Review of Current Science and Introduction of a Synthetic Nanofabricated Wound Care Scaffold. Cureus. 2017;9(10):e1736.
  31. Regulski MJ, MacEwan MR. Implantable Nanomedical Scaffold Facilitates Healing of Chronic Lower Extremity Wounds. Wounds. 2018;30(8):E77-E80.
  32. Armstrong DG, Galiano RD, Orgill DP, et al. Multi-centre prospective randomised controlled clinical trial to evaluate a bioactive split thickness skin allograft vs standard of care in the treatment of diabetic foot ulcers. International Wound Journal. 2022;19(4):932-944.
  33. DiDomenico L, Landsman AR, Emch KJ, Landsman A. A prospective comparison of diabetic foot ulcers treated with either a cryopreserved skin allograft or a bioengineered skin substitute. Wounds. 2011;23(7):184-189.
  34. Gurtner GC, Garcia AD, Bakewell K, Alarcon JB. A retrospective matched-cohort study of 3994 lower extremity wounds of multiple etiologies across 644 institutions comparing a bioactive human skin allograft, TheraSkin, plus standard of care, to standard of care alone. International Wound Journal. 2020;17(1):55-64.
  35. Barbul A GG, Gordon H, Bakewell K, Carter MJ. Matched-cohort study comparing bioactive human split-thickness skin allograft plus standard of care to standard of care alone in the treatment of diabetic ulcers: A retrospective analysis across 470 institutions. Wound Repair Regen. 2020 28(1):81-89.
  36. Serena TE, Orgill DP, Armstrong DG, et al. A Multicenter Randomized Controlled Clinical Trial Evaluating Two Application Regimens of Dehydrated Human Amniotic Membrane and Standard of Care vs Standard of Care Alone in the Treatment of Venous Leg Ulcers. Plastic and Reconstructive Surgery. 2022.
  37. Falanga V. Apligraf treatment of venous ulcers and other chronic wounds. J Dermatol. 1998;25(12):812-817.
  38. Falanga V, Sabolinski M. A bilayered living skin construct (APLIGRAF) accelerates complete closure of hard-to-heal venous ulcers. Wound Repair Regen. 1999;7(4):201-207.
  39. Towler MA, Rush EW, Richardson MK, Williams CL. Randomized, Prospective, Blinded-Enrollment, Head-To-Head Venous Leg Ulcer Healing Trial Comparing Living, Bioengineered Skin Graft Substitute (Apligraf) with Living, Cryopreserved, Human Skin Allograft (TheraSkin). Clin Podiatr Med Surg. 2018;35(3):357-365.
  40. Cazzell S. A Randomized Controlled Trial Comparing a Human Acellular Dermal Matrix Versus Conventional Care for the Treatment of Venous Leg Ulcers. Wounds. 2019;31(3):68-74.
  41. Harding K SM, Cardinal M. . A prospective, multicentre, randomised controlled study of human fibroblast-derived dermal substitute (Dermagraft) in patients with venous leg ulcers. . Int Wound J. 2013;10(2):132-137.
  42. Serena TE, Carter MJ, Le LT, Sabo MJ, DiMarco DT, EpiFix VLUSG. A multicenter, randomized, controlled clinical trial evaluating the use of dehydrated human amnion/chorion membrane allografts and multilayer compression therapy vs. multilayer compression therapy alone in the treatment of venous leg ulcers. Wound Repair Regen. 2014;22(6):688-693.
  43. Bianchi C, Cazzell S, Vayser D, et al. A multicentre randomised controlled trial evaluating the efficacy of dehydrated human amnion/chorion membrane (EpiFix((R)) ) allograft for the treatment of venous leg ulcers. Int Wound J. 2018;15(1):114-122.
  44. Landsman A, Roukis TS, DeFronzo DJ, Agnew P, Petranto RD, Surprenant M. Living cells or collagen matrix: which is more beneficial in the treatment of diabetic foot ulcers? Wounds: a compendium of clinical research and practice. 2008;20(5):111-116.
  45. Niezgoda JA, Van Gils CC, Frykberg RG, Hodde JP. Randomized clinical trial comparing OASIS Wound Matrix to Regranex Gel for diabetic ulcers. Adv Skin Wound Care. 2005;18(5 Pt 1):258-266.
  46. Romanelli M, Dini V, Bertone MS. Randomized comparison of OASIS wound matrix versus moist wound dressing in the treatment of difficult-to-heal wounds of mixed arterial/venous etiology. Advances in skin & wound care. 2010;23(1):34-38.
  47. Mostow EN, Haraway GD, Dalsing M, Hodde JP, King D, Group OVUS. Effectiveness of an extracellular matrix graft (OASIS Wound Matrix) in the treatment of chronic leg ulcers: a randomized clinical trial. Journal of vascular surgery. 2005;41(5):837-843.
  48. Marston WA, Sabolinski ML, Parsons NB, Kirsner RS. Comparative effectiveness of a bilayered living cellular construct and a porcine collagen wound dressing in the treatment of venous leg ulcers. Wound repair and regeneration. 2014;22(3):334-340.
  49. Tchanque-Fossuo CN, Dahle SE, Lev-Tov H, et al. Cellular versus acellular matrix devices in the treatment of diabetic foot ulcers: Interim results of a comparative efficacy randomized controlled trial. J Tissue Eng Regen Med. 2019;13(8):1430-1437.
  50. Romanelli M, Dini V, Bertone M, Barbanera S, Brilli C. OASIS® wound matrix versus Hyaloskin® in the treatment of difficult-to-heal wounds of mixed arterial/venous aetiology. International wound journal. 2007;4(1):3-7.
  51. Demling RH, Niezgoda JA, Haraway GD, Mostow E. Small intestinal submucosa wound matrix and full-thickness venous ulcers: preliminary results. Wounds. 2004;16(1):18-22.
  52. Kelechi TJ, Mueller M, Hankin CS, Bronstone A, Samies J, Bonham PA. A randomized, investigator-blinded, controlled pilot study to evaluate the safety and efficacy of a poly-N-acetyl glucosamine–derived membrane material in patients with venous leg ulcers. Journal of the American Academy of Dermatology. 2012;66(6):e209-e215.
  53. Maus EA. Successful treatment of two refractory venous stasis ulcers treated with a novel poly-N-acetyl glucosamine-derived membrane. Case Reports. 2012;2012:bcr0320126091.
  54. Sterne JAC SJ, Page MJ, Elbers RG, Blencowe NS, Boutron I, Cates CJ, Cheng H-Y, Corbett MS, Eldridge SM, Hernán MA, Hopewell S, Hróbjartsson A, Junqueira DR, Jüni P, Kirkham JJ, Lasserson T, Li T, McAleenan A, Reeves BC, Shepperd S, Shrier I, Stewart LA, Tilling K, White IR, Whiting PF, Higgins JPT. . RoB 2: a revised tool for assessing risk of bias in randomised trials. . BMJ. 2019:366: l4898.
  55. Higgins JPT SJ, Page MJ, Elbers RG, Sterne JAC. . Chapter 8: Assessing risk of bias in a randomized trial.Cochrane Handbook for Systematic Reviews of Interventions version 6.4 (updated August 2023). Available from www.training.cochrane.org/handbook. Published 2023. Accessed10/10/23.
  56. DiDomenico LA, Orgill DP, Galiano RD, et al. Aseptically Processed Placental Membrane Improves Healing of Diabetic Foot Ulcerations: Prospective, Randomized Clinical Trial. Plast Reconstr Surg Glob Open. 2016;4(10):e1095.
  57. DiDomenico LA, Orgill DP, Galiano RD, et al. Use of an aseptically processed, dehydrated human amnion and chorion membrane improves likelihood and rate of healing in chronic diabetic foot ulcers: A prospective, randomised, multi-centre clinical trial in 80 patients. Int Wound J. 2018;15(6):950-957.
  58. Falanga V, Margolis D, Alvarez O, et al. Rapid healing of venous ulcers and lack of clinical rejection with an allogeneic cultured human skin equivalent. Human Skin Equivalent Investigators Group. Arch Dermatol. 1998;134(3):293-300.
  59. Bianchi C, Tettelbach W, Istwan N, et al. Variations in study outcomes relative to intention-to-treat and per-protocol data analysis techniques in the evaluation of efficacy for treatment of venous leg ulcers with dehydrated human amnion/chorion membrane allograft. Int Wound J. 2019;16(3):761-767.
  60. Zelen CM, Orgill DP, Serena TE, et al. An aseptically processed, acellular, reticular, allogenic human dermis improves healing in diabetic foot ulcers: A prospective, randomised, controlled, multicentre follow-up trial. Int Wound J. 2018;15(5):731-739.
  61. Huang W, Chen Y, Wang N, Yin G, Wei C, Xu W. The efficacy and safety of acellular matrix therapy for diabetic foot ulcers: a meta-analysis of randomized clinical trials. Journal of Diabetes Research. 2020;2020.
  62. Landsman A, Rosines E, Houck A, et al. Characterization of a cryopreserved split-thickness human skin allograft–TheraSkin. Advances in Skin & Wound Care. 2016;29(9):399-406.
  63. Lambert N, Vinke E, Barrett T, Regulski M. Application of Amniotic Membrane Allografts in Advanced Venous Leg Ulcer: A Case Study and Literature Review. 2022.
  64. Rodríguez I AA, Massey C, et al. . Novel bioengineered collagen with Manuka honey and hydroxyapatite sheet for the treatment of lower extremity chronic wounds in an urban hospital wound care setting. . Wounds 2023;35(1):E35-E38.
  65. Rodriguez IA SA, Weinstein R, et al. . Preliminary Clinical Evaluation Using a Novel Bioengineered Wound Product to Treat Lower Extremity Ulcers. The International Journal of Lower Extremity Wounds 2020;1(22):139-145.
  66. Sledge I, Maislin D, Bernarducci D, Snyder R, Serena TE. Use of a dual-layer amniotic membrane in the treatment of diabetic foot ulcers: an observational study. J Wound Care. 2020;29(Sup9):S8-S12.
  67. Singh R, Chacharkar M. Dried gamma-irradiated amniotic membrane as dressing in burn wound care. Journal of Tissue Viability. 2011;20(2):49-54.
  68. Kraemer BA, Geiger SE, Deigni OA, Watson JT. Management of Open Lower Extremity Wounds With Concomitant Fracture Using a Porcine Urinary Bladder Matrix. Wounds: a Compendium of Clinical Research and Practice. 2016;28(11):387-394.
  69. Geiger SE, Deigni OA, Watson JT, Kraemer BA. Management of Open Distal Lower Extremity Wounds With Exposed Tendons Using Porcine Urinary Bladder Matrix. Wounds: a Compendium of Clinical Research and Practice. 2016;28(9):306-316.
  70. Ditmars FS, Lind RA, Broderick TC, Fagg WS. Safety and efficacy of acellular human amniotic fluid and membrane in the treatment of non-healing wounds in a patient with chronic venous insufficiency. SAGE Open Med Case Rep. 2022;10:2050313X221100882.
  71. Kimmel H, Gittleman H. Retrospective observational analysis of the use of an architecturally unique dermal regeneration template (Derma Pure®) for the treatment of hard-to-heal wounds. International wound journal. 2017;14(4):666-672.
  72. Ganesh P, Puranik S, Abhaya M, Misra P, Guruvigneshwari M, Daniel JI. Connective tissue matrices from placental disc for wound healing: mini-review. Biotechnology Letters. 2023:1-9.
  73. Schwartz J, Koutsoumbelis S, Parikh Z, et al. The use of human amnion/chorion for the enhancement of collagen synthesis and acceleration of wound healing in a diabetic rat model. Regenerative Engineering and Translational Medicine. 2021;7:41-46.
  74. Arif MMA, Fauzi MB, Nordin A, Hiraoka Y, Tabata Y, Yunus MHM. Fabrication of bio-based gelatin sponge for potential use as a functional acellular skin substitute. Polymers. 2020;12(11):2678.
  75. Sivak WN, Bourne DA, Miller MP, Manders EK. Simplified calvarial reconstruction: coverage of bare skull with gammagraft promotes granulation and facilitates skin grafting. Journal of Craniofacial Surgery. 2016;27(7):1808-1809.
  76. Caravaggi C, Grigoletto F, Scuderi N. Wound Bed Preparation With a Dermal Substitute (Hyalomatrix(R) PA) Facilitates Re-epithelialization and Healing: Results of a Multicenter, Prospective, Observational Study on Complex Chronic Ulcers (The FAST Study). Wounds. 2011;23(8):228-235.
  77. Motolese A, Vignati F, Brambilla R, Cerati M, Passi A. Interaction between a regenerative matrix and wound bed in nonhealing ulcers: results with 16 cases. Biomed Res Int. 2013;2013:849321.
  78. Simman R, Mari W, Younes S, Wilson M. Use of Hyaluronic Acid-Based Biological Bilaminar Matrix in Wound Bed Preparation: A Case Series. Eplasty. 2018;18:e10.
  79. Caravaggi C, Sganzaroli A, Pogliaghi I, Cavaiani P, Fabbi M, Ferraresi R. Safety and efficacy of a dermal substitute in the coverage of cancellous bone after surgical debridement for severe diabetic foot ulceration. EWMA Journal. 2009;9(1).
  80. Simman R, Hermans MHE. Managing Wounds with Exposed Bone and Tendon with an Esterified Hyaluronic Acid Matrix (eHAM): A Literature Review and Personal Experience. J Am Coll Clin Wound Spec. 2017;9(1-3):1-9.
  81. Fairbairn NG RM, Redmond RW. . The clinical applications of human amnion in plastic surgery. . J Plast Reconstr Aesthet Surg 2014;67(5):662-675.
  82. Rice AH, Mallory Przbylski D. A Closer Look At Acellular Dermal Matrices For Chronic Diabetic Foot Ulcers. Podiatry Today. 2012;25(11).
  83. Fridman R, Engelhardt J. A pilot study to evaluate the effects of perfusion-decellularized porcine hepatic-derived wound matrix on difficult-to-heal diabetic foot ulcers. Wounds: a Compendium of Clinical Research and Practice. 2017;29(10):317-323.
  84. Fridman R, Rafat P, Van Gils CC, Horn D, Vayser D, Lambert Jr JC. Treatment of Hard-to-heal Diabetic Foot Ulcers With a Hepatic-derived Wound Matrix. Wounds: a compendium of clinical research and practice. 2020;32(9):244-252.
  85. Buck DW. Innovative bioactive glass fiber technology accelerates wound healing and minimizes costs: a case series. Advances in Skin & Wound Care. 2020;33(8):1-6.
  86. J. S. Use of Cryopreserved, Particulate Human Amniotic Membrane and Umbilical Cord (AM/UC) Tissue: A Case Series Study for Application in the Healing of Chronic Wounds. Surg Technol Int. 2014;25:73-78.
  87. Greenwood J, Wagstaff M. The use of biodegradable polyurethane in the development of dermal scaffolds. In: Advances in Polyurethane Biomaterials. Elsevier; 2016:631-662.
  88. Greenwood JE DB. Split skin graft application over an integrating, biodegradable temporizing polymer matrix: immediate and delayed. J Burn Care Res. 2012;33(1):7-19.
  89. Tursi FJ, Donnelly JV, Seiler DR. An Integrative Approach To Healing Diabetic Foot Wounds. Podiatry Today. 2019;32(6).
  90. Caporusso J, Abdo R, Karr J, Smith M, Anaim A. Clinical experience using a dehydrated amnion/chorion membrane construct for the management of wounds. Wounds. 2019;31(4 Suppl):S19-S27.
  91. Yamada S, Yamamoto K, Ikeda T, Yanagiguchi K, Hayashi Y. Potency of fish collagen as a scaffold for regenerative medicine. BioMed research international. 2014;2014.
  92. Panggabean JA, Adiguna SbP, Hardhiyuna M, et al. Cutting Edge Aquatic-Based Collagens in Tissue Engineering. Marine Drugs. 2023;21(2):87.
  93. Koullias GJ. Efficacy of the Application of a Purified Native Collagen With Embedded Antimicrobial Barrier Followed by a Placental Allograft on a Diverse Group of Nonhealing Wounds of Various Etiologies. Wounds: a Compendium of Clinical Research and Practice. 2021;33(1):20-27.
  94. Lintzeris D, Vernon K, Percise H, et al. Effect of a New Purified Collagen Matrix With Polyhexamethylene Biguanide on Recalcitrant Wounds of Various Etiologies: A Case Series. Wounds. 2018;30(3):72-78.
  95. Oropallo AR. Use of native type I collagen matrix plus polyhexamethylene biguanide for chronic wound treatment. Plastic and Reconstructive Surgery Global Open. 2019;7(1).
  96. Durham EL, Howie RN, Hall S, et al. Optimizing bone wound healing using BMP2 with absorbable collagen sponge and Talymed nanofiber scaffold. Journal of translational medicine. 2018;16(1):1-8.
  97. Howie RN, Durham E, Oakes B, et al. Testing a novel nanofibre scaffold for utility in bone tissue regeneration. Journal of tissue engineering and regenerative medicine. 2018;12(10):2055-2066.
  98. Mulder G, Lee DK. Case presentation: xenograft resistance to protease degradation in a vasculitic ulcer. The International Journal of Lower Extremity Wounds. 2009;8(3):157-161.
  99. Lullove EJ. Use of a dehydrated amniotic membrane allograft in the treatment of lower extremity wounds: a retrospective cohort study. Wounds: a Compendium of Clinical Research and Practice. 2017;29(11):346-351.
  100. NICE. Diabetic foot problems: Prevention and management National Institute for Health and Care Excellence. https://www.nice.org.uk. Published 2019. Accessed 12/14/23.

 

Revision History Information

Revision History Date Revision History Number Revision History Explanation Reasons for Change
N/A

Associated Documents

Attachments
N/A
Related National Coverage Documents
N/A
Public Versions
Updated On Effective Dates Status
04/20/2024 N/A - N/A Superseded You are here

Keywords

N/A

Read the LCD Disclaimer