Scalp Cooling for the Prevention of Chemotherapy-Induced Alopecia

Title XVIII of the Social Security Act, §1862(a)(1)(A) allows coverage and payment for only those services that are considered to be reasonable and necessary for the diagnosis or treatment of illness or injury or to improve the functioning of a malformed body member.

CMS Internet-Only Manual, Pub. 100-03, Medicare National Coverage Determinations (NCD) Manual, Chapter 1, Part 2, §110.6 Scalp Hypothermia During Chemotherapy to Prevent Hair Loss shall not be construed to prevent coverage.

The use of a scalp hypothermia device that has been approved by the United States (U.S.) Food and Drug Administration (FDA) for the prevention of chemotherapy-induced alopecia (CIA) shall be considered reasonable and necessary for patients with solid tumors.

The device is contraindicated for pediatric patients, patients with certain cancers and patients undergoing specific chemotherapy treatments. Usage of the device is contraindicated in:

• Central nervous system malignancies (either primary or metastatic)
• Squamous cell carcinoma and small cell carcinoma of the lung
• Skin cancers including melanoma, squamous cell carcinoma, and Merkel cell carcinoma
• Patients who are scheduled for bone marrow ablation chemotherapy
• Patients who are scheduled to undergo skull irradiation or have previously received skull irradiation
• Patients with a history of scalp metastases, or in whom scalp metastases are suspected
• Patients with cold sensitivity, cold agglutinin disease, cryoglobulinemia, cryofibrinogenemia, and post-traumatic cold dystrophy
• Patients with severe liver or renal disease from any etiology who may not be able to metabolize or clear the metabolites of the chemotherapeutic agent
• Patients with hematologic malignancies (leukemia, non-Hodgkin and other generalized lymphomas)

CIA is a common and well-known side effect of chemotherapy, affecting approximately 65% of patients who undergo chemotherapy for cancer. Total scalp alopecia is most common, but alopecia can also be diffuse or patchy. CIA is most prominent on the scalp, with a predilection for areas with low total hair density, in particular the crown and frontal areas of the scalp, where there is slower hair recovery. CIA is attributed to the cytotoxic effects of chemotherapy drugs on the matrix cells of the hair follicles during hair growth phases.^1,2 Alopecia is usually, although not always, reversible but can be psychologically and socially devastating. CIA has been cited as the most disturbing anticipated side effect by up to 58% of women preparing for chemotherapy, with 8% being at risk for avoiding treatment altogether due to those fears. CIA has been associated with reduced quality of life (QOL), depression, and poor body image, which may endure for months after chemotherapy is completed.³ A prospective, multi-center study was performed in 13 hospitals to look at the effects of CIA on QOL and associated distress.⁴ Breast cancer patients treated with (N=98) and without (N=168) scalp cooling completed questionnaires before chemotherapy, and 3 weeks and 6 months after the last chemotherapy cycle. Scalp cooling was effective in 52% of the cases. Alopecia was considered among the most distressing problems at all 3 moments of measurement. A trend towards higher well-being was found in successfully scalp-cooled patients, as indicated by a general better health-related QOL and better body image, whereas unsuccessfully scalp-cooled patients reported lowest well-being. Recovery generally requires a period of several months to a year, worsening the impact of the disease.

The timing of alopecia depends on the type(s) of systemic therapy agent, dose, and schedule.⁵ For most regimens that are given every 2 to 3 weeks, alopecia starts around 2 to 3 weeks, and hair is completely lost by the end of the second cycle of chemotherapy. High-dose, intermittent, intravenous (IV) chemotherapy regimens are associated with a high incidence of ≥ grade 2 alopecia. Weekly chemotherapy generally results in slower and occasionally incomplete alopecia, and hair may start to grow back during treatment. Of the commonly used IV single cytotoxic agents, those most likely to cause complete alopecia (dose and schedule dependent) include alkylating agents (cyclophosphamide, ifosfamide, busulfan, thiotepa), antitumor antibiotics (dactinomycin, doxorubicin, epirubicin, idarubicin), antimicrotubule agents (paclitaxel, docetaxel, ixabepilone, eribulin), and topoisomerase inhibitors (etoposide, irinotecan).⁶ Alopecia is less common or incomplete with bleomycin, low-dose epirubicin or doxorubicin (especially < 30 mg/m²), oral cyclophosphamide, fluorouracil, gemcitabine, melphalan, methotrexate, mitomycin, mitoxantrone, platinum agents (oxaliplatin, cisplatin, and carboplatin), topotecan, and vinca alkaloids. Antibody-drug conjugates are also associated with variable hair loss (HL), which is agent specific. In addition, diffuse or partial alopecia may occur with a number of targeted agents. A new class of targeted agents, termed cyclin-dependent kinase (CDK) 4/6 inhibitors, has demonstrated marked efficacy in combination with endocrine therapy in patients with metastatic hormone receptor-positive breast cancer. Three agents have FDA-approval: palbociclib, ribociclib, and abemaciclib. Given in combination with aromatase inhibitors, these agents increase all-grade and grade 2 alopecia compared with that observed with endocrine therapy alone. There is approximately a doubling of all-grade alopecia, from 10-16% to 25-33%, and approximately a 1.5% increased incidence of grade 2 alopecia.⁷

Hair regrowth generally begins by 6 months after the last chemotherapy session; however, HL may be permanent in some patients.^8,9 Regrowth to a normal appearance can take up to 1 year. The new hair frequently has different characteristics from the original; 65% of patients experience a graying, curling, or straightening effect, which is likely due to differential effects of chemotherapy on hair follicle melanocytes and inner root sheath epithelia, and these effects often resolve over time. Once CIA occurs, treatment to regrow scalp hair may include topical minoxidil. Minoxidil prolongs the anagen phase and may increase hair follicle size counteracting miniaturization of follicle by androgenic alopecia. Two randomized trials suggest that the effects of topical minoxidil in preventing or treating CIA are limited, at best. In a randomized trial of 48 patients with varying solid tumors receiving doxorubicin-containing regimens, topical minoxidil (2% solution applied twice daily) did not prevent the development of severe alopecia compared with placebo.¹⁰ A second trial in 22 women receiving chemotherapy after surgery for breast cancer also found that treatment with topical minoxidil did not prevent alopecia, but it did shorten the time to maximal regrowth and the time from maximal alopecia to first regrowth, and lengthened the time to maximal alopecia.¹¹

Although permanent alopecia is uncommon after standard-dose chemotherapy, there is now convincing evidence of permanent or prolonged alopecia after standard-dose chemotherapy for breast cancer (particularly with docetaxel and clearly related to both dose per infusion and duration of exposure).⁸

HL is quantifiable via various rating systems. Most commonly used is the Modified Dean’s Alopecia Scale for Hair Loss, which has multiple grades stratified by percentage of HL¹²: grade 0: no HL, grade 1: > 0% to ≤ 25% HL, grade 2: > 25% to ≤ 50% HL, grade 3: > 50% to ≤ 75% HL, and grade 4: > 75% HL. Also utilized is the World Health Organization (WHO) Criteria guidelines for determining degree of alopecia: degree 1: no significant HL, degree 2: minor HL, degree 3: severe HL, and degree 4: total alopecia.¹³

The mechanism of action of scalp hypothermia includes local vasoconstriction of blood vessels, resulting in reduced delivery of chemotherapy to the scalp, decreased follicle cell metabolic rate, and reduced cellular drug uptake. Older studies employ ice packs secured to the scalp with bandages, or ice packs fashioned into caps that fit over the scalp. Commercially available precooled nonautomated caps include Penguin^TM Cold Caps and Chemo Cold Caps^TM (Chemotherapy Cold Caps Inc.). These older technologies can be heavy to wear, require replacement approximately every 20 minutes per treatment session due to thawing, and have been associated with cold thermal burns (e.g., frostbite).¹ These caps are not subject to FDA regulation or prescription, and patients can rent them directly from the manufacturers and take the caps to their chemotherapy sessions.

The National Comprehensive Cancer Network^® (NCCN^®) has updated the Clinical Practice Guidelines in oncology for breast cancer (Version 1.2019) to include scalp cooling as a Category 2A recommendation to reduce the incidence of CIA for patients receiving chemotherapy.¹⁴ Newer technologies for scalp cooling systems are self-contained, with built-in temperature sensors that cool and circulate a glycol-based fluid through channels in a cap, allowing for continuous, uninterrupted cooling throughout the treatment session.¹⁵ These have purported advantages of greater ease of use for clinical personnel and greater comfort for patients. In December 2015, the FDA cleared the DigniCap^® Scalp Cooling System (Dignitana AB, Sweden) for marketing, and the Orbis from Paxman Coolers Ltd. received clearance in 2017.¹ Automated caps include the DigniCap^® (Dignitana Inc.) and Paxman Scalp Cooling System (Paxman Coolers Ltd.). According to its FDA summary, the DigniCap^® computer-controlled system is touchscreen operated and circulates liquid coolant between a tank that refrigerates the coolant and the DigniCap^®, a silicone cap with separate cooling circuits for the front and back of the head. The cap and tank temperature are computer-controlled and automatically regulated. During treatment, a neoprene cap fits over the DigniCap^® to insulate it and keep it in place. Coolant can be chilled to -15°C to 5°C. A new device from Dignitana ("Delta") provides a cap that can be shaped to the individual head (similar to the design of the frozen Penguin^TM cap, but with an automated circulating coolant).¹⁶ According to its FDA summary, the Paxman system is substantially equivalent to the DigniCap^® System. Paxman provides an additional extra-small size cap in addition to small, medium, and large. Each patient has a personal scalp cooling cap, and the systems are designed to treat 1 or 2 patients at a time. A pay-for-use token is scanned at the beginning of the cooling session.¹⁷

Regardless of the specific device that is used, cooling is started approximately 30 minutes before the chemotherapy infusion starts in order to allow gradual cooling of the scalp to the desired temperature. Cooling is maintained for a period of time after the end of the chemotherapy infusion, generally at least 90 minutes and as long as 3 to 4 hours in some cases.^18,19 The duration of post-infusion cooling is determined at least in part by the clearance of high levels of chemotherapy, but also by the severity of the expected alopecia.

The optimal scalp temperature for successful cooling is thought to be 22°C, although data regarding this specific number is quite limited, and it is difficult to accurately measure. Indeed, others attribute therapeutic success to obtaining a subcutaneous scalp temperature below 15°C. However, the caps themselves must be much colder in order to bring the scalp to the desired temperature. The type of cooling device determines the temperature, as manual caps must be much colder when initially applied to the scalp to account for their gradual increase in temperature before a new cap is applied. The automated units are usually set around 0°C. There is currently no consensus in the literature with regard to the best cooling device, duration and frequency of application, or temperature of cooling.^18,20

Contraindications¹⁸ to scalp cooling appear to be nonspecific to a particular device. The use of a cooling cap is contraindicated in all children, and in adults with:

• Central nervous system malignancies (either primary or metastatic)
• Squamous cell carcinoma and small cell carcinoma of the lung
• Skin cancers including melanoma, squamous cell carcinoma, and Merkel cell carcinoma
• Patients who are scheduled for bone marrow ablation chemotherapy
• Patients who are scheduled to undergo skull irradiation or have previously received skull irradiation
• Patients with a history of scalp metastases, or in whom scalp metastases are suspected
• Patients with cold sensitivity, cold agglutinin disease, cryoglobulinemia, cryofibrinogenemia, and post-traumatic cold dystrophy
• Patients with severe liver or renal disease from any etiology who may not be able to metabolize or clear the metabolites of the chemotherapeutic agent
• Patients with hematologic malignancies (leukemia, non-Hodgkin and other generalized lymphomas)

Ultimately, the primary measure of scalp cooling’s efficacy is whether it prevents HL, as compared with controls. Additional considerations are if hair regrowth also occurs more rapidly in those that do lose hair, compared to no scalp cooling. Both the benefits of and minimal-to-modest adverse events (AEs) from scalp cooling have been confirmed in 3 prospective trials evaluating the efficacy of 2 scalp hypothermia devices in women with early-stage breast cancer.

A prospective cohort study was conducted between August 2013 and October 2014, with ongoing annual follow-up for 5 years, at 5 U.S. medical centers. One hundred one women with stage I or II breast cancer receiving adjuvant or neoadjuvant chemotherapy regimens excluding sequential or combination anthracycline and taxane, used the DigniCap^® scalp cooling device and were compared with 16 concurrently treated controls who did not use the cooling device. Alopecia was measured using the Dean Scale, with success defined as alopecia of 50% or less (Dean score 0 to 2 [table 3]) 1 month after the last chemotherapy infusion and was graded by the patients themselves using photographs compared with their own baseline hair. The rate of significant alopecia (>2 on the Dean Scale) was 50% or less in 66.3% of the intervention group compared with none of the control group (p < 0.001). Three of 5 QOL measures were significantly better 1 month after the end of chemotherapy, including perception of HL, feeling upset over HL, and feeling less physically attractive as a result of the disease or its treatment. The primary toxicity was mild headache, and 3 patients stopped cooling due to feeling cold.²¹

From July 2014 to November 2016, 139 consecutive breast cancer patients receiving an anthracycline containing adjuvant chemotherapy were enrolled and received at least 1 treatment with scalp cooling utilizing DigniCap^®. HL was evaluated by patient self-assessment and by the physician according to the Dean's Scale at baseline and after each cycle of chemotherapy. The primary efficacy endpoint was the patient self-assessment HL score evaluated at least 3 weeks after completing chemotherapy. A Dean's Scale score of 0-2 (i.e., HL ≤ 50%) was considered a success. Fifty-six out of 131 evaluated patients successfully prevented HL (43%, 95% confidence interval (CI): 34-51%). Twenty-four patients (32%) discontinued the scalp cooling because of alopecia or scalp cooling-related AEs, 3 patients had missing information on CIA, and 48 patients (64%) had a HL greater than 50% after chemotherapy. No serious AEs were reported.²²

A different trial conducted at 7 sites in the U.S. from December 9, 2013 to September 30, 2016, enrolled 182 patients. Participants were randomized in a 2:1 ratio to scalp cooling (n = 119) utilizing the Paxman scalp cooling device or control (n = 63) with no scalp hypothermia during chemotherapy for breast cancer; 36% received anthracycline-based chemotherapy, while the remainder received a taxane, either alone or in combination with carboplatin, cyclophosphamide, pertuzumab, and/or trastuzumab. Successful hair preservation was defined as less than 50% HL not requiring a wig and was graded by a clinician unaware of treatment assignment at the end of 4 cycles of chemotherapy. The mean (standard deviation [SD]) age of the patients was 52.6 (10.1) years; 36% (n = 51) received anthracycline-based chemotherapy and 64% (n = 91) received taxane-based chemotherapy. Successful hair preservation was found in 48 of 95 women with cooling (50.5%; 95% CI, 40.7%-60.4%) compared with 0 of 47 women in the control group (0%; 95% CI, 0%-7.6%) (success rate difference, 50.5%; 95% CI, 40.5%-60.6%). Only AEs related to device use were collected; 54 AEs were reported in the cooling group, all grades 1 and 2. There were no serious adverse device events. Scalp hypothermia was graded as successful in 50.5% of patients compared with none of the control group (p = 0.0061). AEs were all grade 1 and 2, primarily headache and feeling cold. Seven patients discontinued cooling early, primarily due to feeling cold. There were substantial differences in the success of cooling by drug group. An exploratory post hoc analysis indicated that only 16% of patients receiving anthracycline-based chemotherapy met criteria for success, compared with 59% of those receiving taxanes, although the CIs were very wide.²³

A meta-analysis in 2015 concluded that scalp hypothermia was the only intervention that significantly reduced the risk of CIA (10 studies, involving 818 patients and including 3 randomized trials; relative risk 0.38 compared with no cooling, 95% CI 0.32-0.45). No significant AEs associated with scalp hypothermia were reported in this meta-analysis, although the reported studies did not always track toxicity.²⁴ Two of the authors independently searched PubMed^®, Embase and the Cochrane Library, from June 20, 2013 through August 31, 2013, and selected clinical trials that reported the efficacy of any intervention for prevention of CIA compared with that of controls. Out of 691 articles retrieved, a total of 8 randomized controlled trials (RCTs) and 9 controlled clinical trials (CCTs) involving 1,098 participants (616 interventions and 482 controls), were included in the final analyses. Scalp cooling, scalp compression, a combination of cooling and compression, topical minoxidil and Panicum miliaceum were used as interventions. The participants were mainly breast cancer patients receiving doxorubicin- or epirubicin-containing chemotherapy. Scalp cooling, which is the most popular preventive method, significantly reduced the risk of CIA (relative risk [RR] = 0.38, 95% CI = 0.32-0.45), whereas topical 2% minoxidil and other interventions did not significantly reduce the risk of CIA. No serious AEs associated with scalp cooling were reported.

Another review and meta-analysis looked at 654 patients. There were 10 studies included in the review that met the criteria for eligibility. Six of the studies were performed in Europe and 4 were performed in the U.S. Two of these studies were a multi-center study with the remainder being single-center. All these studies except for 2, used older scalp cooling technology (e.g., frozen caps) rather than the more recent technologies such as DigniCap^® Scalp Cooling System (Dignitana) or Orbis (Paxman). Two studies used the Paxman system. Most patients in all these studies were treated with anthracyclines (doxorubicin, epirubicin or taxanes). For the binary outcome of < 50% versus > 50% alopecia, the use of scalp cooling reduced RR of alopecia by 43% (RR, 0.57; 95% CI, 0.45-0.72; I(2) = 11%; P < 0.00001). For ordinal outcomes (alopecia on a scale of 0-3), use of scalp cooling significantly reduced alopecia (MD, -0.80; 95% CI, -1.19 to -0.41; I(2) = 0%; P < 0.0001). The quality of the evidence was graded as moderate. This systematic review and meta-analysis support the use of scalp cooling to prevent alopecia in patients with solid tumors undergoing chemotherapy.¹⁵

A later meta-analysis of 27 studies (3 randomized trials, 12 cohort, and 12 cross-sectional studies) was performed looking at breast cancer patients undergoing chemotherapy who used a variety of scalp cooling devices. The effectiveness rate of using a scalp cooling device to protect hair was 61% (95% CI: 55 to 67%, I(2) = 88%, P = 0.000). Estimates of adverse reactions that were reported in 4 or more studies included headache (28%), scalp pain (25%), feeling cold (50%), neck pain (22%), and heaviness of the head (53%). Review authors noted that the comparison of scalp cooling studies to attempt to determine which caps and protocols work best is limited by the substantial variability in chemotherapy (e.g., drugs, dosages, number of cycles, and mode of administration) and scalp cooling treatment (e.g., device, procedures, evaluation method, scalp temperatures) among studies. Scalp temperature and duration of application were associated with statistically heterogeneous outcomes. Review authors note that in other studies in the literature, temperatures of 22°C or lower have been associated with better hair retention. However, since every study in their meta-analysis had a different treatment protocol, it is not possible to determine from the meta-analysis which, if any, works best.²⁵

The risk of scalp metastases was a concern when the technology was first used. There were no scalp metastases in 952 patients treated with scalp cooling in the reviewed RCTs or CCTs, but Shah¹ and colleagues noted that the follow-up duration was short, and metastases were not routinely documented. Given the importance of the issue, they reviewed additional literature from other published sources. They noted that a 2006 series of 227 breast cancer patients reported scalp metastases in 2 patients who used scalp cooling (0.88%). A 2009 study of 640 breast cancer patients reported that 6 of 553 scalp cooling patients (1.1%) had scalp metastases, compared with 1 of 87 (1.2%) control group patients (P = 0.40). A 2005 systemic review (SR) included 56 studies and identified 9 reported cases of scalp metastases among approximately 2500 patients. Martín, et al.⁹ followed patients for a median of 8 years and found no scalp metastases in patients with breast cancer who had scalp cooling.

Ross, et al.²⁶ reviewed 40 years of efficacy, safety, and tolerability literature on scalp cooling to prevent CIA. Forty articles were reviewed, with 12 articles demonstrating high levels of evidence and meeting inclusion criteria. Comparative trials, systematic reviews, and 1 large single-arm trial were included. The conclusion was that scalp cooling efficacy is dependent on many factors but demonstrates better hair preservation than no cooling. No increase in scalp metastases or statistically significant difference in overall survival was seen in retrospective safety data when cooling was used. Few patients discontinued cooling early because of adverse experiences. Further, it demonstrates a high level of qualitative consistency among studies, which found that scalp cooling is more effective than no cooling for hair preservation, even though no quantitative conclusion about the size of that benefit is currently possible due to heterogeneity. The overall evidence suggests that there are no major complications related to scalp cooling and that most side effects are tolerable.

Initial data, as well as more recent meta-analysis, support the efficacy and safety of scalp cooling devices for patients with solid tumors who are receiving chemotherapy that is expected to result in significant alopecia. Two such devices, the DigniCap^® and Paxman scalp hypothermia systems, have been used extensively outside of the U.S., and both are now also FDA cleared in the U.S. for this use. Manual caps are also available, although these caps are unregulated, and there are risks associated with their use. Because they are unregulated, their use is not considered reasonable and necessary. Overall, the literature is of moderate quality, limited by heterogeneity of chemotherapy protocols and associated cooling times.

Given the NCCN^® recommendations, the significant deleterious effect that CIA has on QOL, as well as the safety of the devices, the use of devices that have been cleared by the FDA to prevent CIA will be covered as reasonable and necessary. Scalp hypothermia for patients who have the previously described contraindication(s) will not be considered to be reasonable and necessary.

1. Shah VV, Wikramanayake TC, DelCanto GM, et al. Scalp hypothermia as a preventative measure for chemotherapy-induced alopecia: A review of controlled clinical trials. J Eur Acad Dermatol Venereol. 2018;32(5):720-734.
2. Lemieux J, Maunsell E, Provencher L. Chemotherapy-induced alopecia and effects on quality of life among women with breast cancer: A literature review. Psycho-Oncology. 2008;17(4):317-328.
3. Choi EK, Kim IR, Chang O, et al. Impact of chemotherapy-induced alopecia distress on body image, psychosocial well-being, and depression in breast cancer patients. Psycho-Oncology. 2014;23(10):1103-1110.
4. van den Hurk CJ, Mols F, Vingerhoets AJ, Breed WP. Impact of alopecia and scalp cooling on the well-being of breast cancer patients. Psycho-Oncology. 2010;19(7):701-709.
5. Vasconcelos I, Wiesske A, Schoenegg W. Scalp cooling successfully prevents alopecia in breast cancer patients undergoing anthracycline/taxane-based chemotherapy. Breast. 2018;40:1-3.
6. Freites-Martinez A, Shapiro J, Goldfarb S, et al. CME part 1: Hair disorders in cancer patients. J Am Acad Dermatol. 2019;80(5):1179-1196.
7. Hortobagyi GN, Stemmer SM, Burris HA, et al. Ribociclib as first-line therapy for HR-positive, advanced breast cancer. N Engl J Med. 2016;375(18):1738-1748.
8. Kluger N, Jacot W, Frouin E, et al. Permanent scalp alopecia related to breast cancer chemotherapy by sequential fluorouracil/epirubicin/cyclophosphamide (FEC) and docetaxel: A prospective study of 20 patients. Annals of Oncology. 2012;23(11):2879-2884.
9. Martín M, de la Torre-Montero JC, López-Tarruella S, et al. Persistent major alopecia following adjuvant docetaxel for breast cancer: Incidence, characteristics, and prevention with scalp cooling. Breast Cancer Research and Treatment. 2018;171(3):627-634.
10. Rodriguez R, Machiavelli M, Leone B, et al. Minoxidil (Mx) as a prophylaxis of doxorubicin-induced alopecia. Annals of Oncology. 1994;5(8):769-770.
11. Duvic M, Lemak NA, Valero V, et al. A randomized trial of minoxidil in chemotherapy-induced alopecia. J Am Acad Dermatol. 1996;35(1):74-78.
12. Rubio-Gonzalez B, Juhász M, Fortman J, Mesinkovska NA. Pathogenesis and treatment options for chemotherapy-induced alopecia: A systematic review. International Journal of Dermatology. 2018;57(12):1417-1424.
13. Kargar M, Sarvestani RS, Khojasteh HN, Heidari MT. Efficacy of penguin cap as scalp cooling system for prevention of alopecia in patients undergoing chemotherapy. J Adv Nurs. 2011;67(11):2473-2477.
14. Gradishar WJ, Moran MS, Abraham J, et al. Breast cancer, version 4.2021: Featured updates to the NCCN guidelines. J Natl Compr Canc Netw. 2021;19(5):484-494.
15. Rugo HS, Voigt J. Scalp hypothermia for preventing alopecia during chemotherapy. A systematic review and meta-analysis of randomized controlled trials. Clin Breast Cancer. 2018;18(1):19-28.
16. Mustoe MM, Lee CM, Melisko ME, Esserman LJ, Rugo HS. The DigniCap Scalp Cooling System and its use in the treatment of chemotherapy-induced alopecia. Future Oncol. 2018;14(24):2461-2469.
17. Bajpai J, Kagwade S, Chandrasekharan A, et al. Randomised controlled trial of scalp cooling for the prevention of chemotherapy induced alopecia. Breast. 2020;49:187-193.
18. Komen MM, Smorenburg CH, van den Hurk CJ, Nortier JW. Factors influencing the effectiveness of scalp cooling in the prevention of chemotherapy-induced alopecia. Oncologist. 2013;18(7):885-891.
19. van den Hurk CJ, van den Akker-van Marle ME, Breed WP, van de Poll-Franse LV, Nortier JW, Coebergh JW. Cost-effectiveness analysis of scalp cooling to reduce chemotherapy-induced alopecia. Acta Oncologica. 2014;53(1):80-87.
20. Lugtenberg RT, van den Hurk CJ, Smorenburg CH, et al. Comparable effectiveness of 45- and 20-min post-infusion scalp cooling time in preventing paclitaxel-induced alopecia - a randomized controlled trial. Supportive Care in Cancer. 2022;30(8):6641-6648.
21. Rugo HS, Klein P, Melin SA, et al. Association between use of a scalp cooling device and alopecia after chemotherapy for breast cancer. Jama. 2017;317(6):606-614.
22. Munzone E, Bagnardi V, Campennì G, et al. Preventing chemotherapy-induced alopecia: A prospective clinical trial on the efficacy and safety of a scalp-cooling system in early breast cancer patients treated with anthracyclines. Br J Cancer. 2019;121(4):325-331.
23. Nangia J, Wang T, Osborne C, et al. Effect of a scalp cooling device on alopecia in women undergoing chemotherapy for breast cancer: The SCALP randomized clinical trial. Jama. 2017;317(6):596-605.
24. Shin H, Jo SJ, Kim DH, Kwon O, Myung SK. Efficacy of interventions for prevention of chemotherapy-induced alopecia: A systematic review and meta-analysis. Int J Cancer. 2015;136(5):E442-E454.
25. Wang S, Yang T, Shen A, Qiang W, Zhao Z, Zhang F. The scalp cooling therapy for hair loss in breast cancer patients undergoing chemotherapy: A systematic review and meta-analysis. Supportive Care in Cancer. 2021;29(11):6943-6956.
26. Ross M, Fischer-Cartlidge E. Scalp cooling: A literature review of efficacy, safety, and tolerability for chemotherapy-induced alopecia. Clin J Oncol Nurs. 2017;21(2):226-233.

• Scalp Cooling
• Chemotherapy-Induced Alopecia