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DOI: 10.1055/s-0038-1660845
Platelet-Rich Plasma for the Treatment of Androgenic Alopecia: A Systematic Review
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Publication History
Publication Date:
28 June 2018 (online)
Abstract
The use of platelet-rich plasma (PRP) has become increasingly commonplace in facial plastic surgery for the treatment of androgenic alopecia (AGA). However, this treatment remains novel with a range of application techniques and outcomes described in the literature. Herein, the authors systematically review the existing literature on the use and efficacy of PRP for AGA. Systematic review of PubMed, Embase, and Cochrane databases was performed. Case reports were excluded. Twenty-four papers met inclusion criteria for this study: 8 randomized control trials and 16 prospective cohort studies. Twenty-one studies used clinical criteria to diagnose AGA, while three used confirmatory biopsies. PRP was injected with or without the use of a numbing agent, and most studies performed multiple injections (three or more separated by several weeks). Twenty-one studies reported positive outcomes by objective criteria (88%), while three suggested that there was no clinical improvement, although in two of these studies patients still reported increased satisfaction. There were no complications reported other than transient edema/erythema and pain/headache associated with the procedure. The existing literature suggests that PRP is a low-risk intervention to treat AGA associated with good patient satisfaction and objective improvements in outcomes. Further research is needed to optimize preparation and delivery methods as well as standardize measurements of clinical outcomes.
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Androgenetic or androgenic alopecia (AGA) is a disease of progressive hair loss mediated by systemic androgens and other genetic factors. It is the most common type of hair loss across both genders. Estimates of the prevalence of AGA vary, but AGA affects >73% of men and >57% of women by the age of 80 years.[1] [2] As much as 58% of the male population between 30 and 50 years of age have AGA.[3] AGA can lead to significant negative psychosocial effects,[4] and improvement in hair loss has been shown to improve layperson perception of age, attractiveness, successfulness, and approachability.[5]
There is a wide range of clinical treatments for hair loss, including the Food and Drug Administration (FDA)-approved medical treatments of topical minoxidil, oral finasteride, and low-level laser light therapy. Surgical options include follicular unit transplant and follicular unit extraction techniques, which are outpatient procedures with excellent reported outcomes.[6] [7] In addition to these existing medical and surgical options, platelet-rich plasma (PRP) is a new minimally invasive, office-based procedure used to treat hair loss secondary to androgenic causes. PRP contains growth factors extracted from autologous blood after venipuncture. PRP has been used since the early 2000s across medical fields, including ophthalmology, orthopaedics, and cardiac surgery. While PRP preparation systems are regulated by the FDA, PRP as a blood product is exempt from the FDA's traditional regulatory pathway.[8] Nearly all preparation systems were designed to generate PRP to be mixed with bone graft material for orthopaedic applications. All other uses of PRP are currently considered off-label applications.
Uses for PRP in the field of facial plastic and reconstructive surgery include soft tissue augmentation,[9] skin rejuvenation,[10] [11] and wound healing.[12] [13] A recent review by Sand et al in 2017 examined the early body of evidence for PRP in areas of aesthetics, including hair loss and facial rejuvenation. Although it was not a formal systematic review, the article examined 14 recent studies on PRP treatment for AGA and suggested promising outcomes. However, the review highlighted the need for a formal systematic review, because of the variance in how the limited studies varied widely in the procedures conducted and outcomes measured. Herein, we perform an up-to-date systematic review of the literature to examine patient demographics, PRP delivery procedures, and subjective and objective outcomes including third-party assessments, patient satisfaction surveys, hair count, and hair density.
Methods
Search Strategy
A systematic review was performed targeting studies investigating the use of PRP for the treatment of AGA. In October 2017, a literature search was conducted using PubMed, Cochrane, and Embase using Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) recommendations ([Fig. 1]).[14] For PubMed, the initial search included articles that mapped to the medical subject headings “platelet-rich plasma,” or the text word “platelet-rich” was collected into a first group. Next, those that mapped to the medical subject heading “alopecia” or text word “hair” were collected into a second group. These two groups were cross-referenced and limited to those with human subjects and written in the English language. Search terms used were: “Platelet-Rich Plasma” [Mesh] OR “platelet-rich” [tw] AND “Alopecia” [Mesh] OR “Hair” [tw] AND “Humans” [Mesh] AND English [lang].
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Titles and abstracts were screened to identify relevant studies, for which full texts were accessed and reviewed against predetermined inclusion and exclusion criteria (see below). Independent searches were performed by two individuals. The initial computerized search yielded 45 studies of which 11 met the inclusion criteria for this study.
The Cochrane Database of Systematic Reviews was searched for articles with the text words “hair loss” and “platelet,” revealing nine articles, none of which met the inclusion criteria for this study. Embase was also similarly searched for studies with the Emtree-exploded term “thrombocyte-rich plasma” and was mapped with those that have the Emtree-exploded terms “alopecia” or “hair loss.” This search yielded 87 citations in the English language, which were screened by titles, abstracts, and full texts, from which 8 new articles were found. Manual review of bibliographies of accepted papers revealed five additional papers that met inclusion criteria.
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Variables and Inclusion/Exclusion Criteria
Inclusion and exclusion criteria were designed to capture as many studies as possible for review, and no papers were excluded on the basis of quality. Articles identified by the computerized and manual searches were subject to the following inclusion criteria: (1) subjects had hair loss due to AGA, and (2) PRP was administered to treat hair loss. Articles were excluded if they were (1) case reports or case series or (2) if the patients undergoing PRP treatment had recent or concurrent medical or surgical therapies for hair loss including hair transplantation, using Rogaine (minoxidil) or Propecia (finasteride).
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Study Analysis
Variables assessed included overall efficacy of therapy (as reported through patient satisfaction, objective measurements, and third-party evaluations), the efficacy in men compared with women, the number of treatments used, side effects/complications of treatment, procedures for delivering PRP, and complications. Accepted articles were assessed for patient demographics, study design, sample size, outcome measures, and conclusions. Heterogeneity among studies measuring the same outcomes was evaluated using the I 2 statistic (a measure of variation that exists between studies that exceeds that created by random chance). Relatively homogenous study populations have an I 2 value of 0 to 60%, while larger I 2 statistics suggest substantial heterogeneity among studies not amenable to meta-analysis. Where the I 2 statistic was < 60%, data were formally pooled into a meta-analysis. Calculations were made using MedCalc (MedCalc Software) and Microsoft Excel (Microsoft Corp.).
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Results
Titles and abstracts for all identified studies were reviewed, and ultimately, 24 studies were included in the systematic review ([Fig. 1]). Eight studies were randomized clinical trials (RCTs),[7] [8] [9] [10] [11] [12] [13] [14] and 16 were prospective cohort studies.[12] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29]
Patient Demographics
A total of 471 patients were studied, of which 131 (28%) were female ([Table 1]). The mean age of the patients in included studies ranged from 29.6 to 43 years of age, although many studies reported only a range of ages. Other patient demographics such as race and hair color were not included in enough studies to merit reporting. Most studies excluded patients according to preset exclusion criteria that most commonly included (1) use of topical or oral medication within a certain time period of study initiation (e.g., 60 days or 12 months), (2) history of bleeding disorders or recent use of aspirin or nonsteroidal anti-inflammatory medication, (3) history of keloids, and (4) history of immunosuppression or systemic disease, such as human immunodeficiency virus (HIV) or hepatitis. The vast majority of studies diagnosed AGA clinically, while three studies also used incisional punch biopsies to confirm the diagnosis.[30] [31] [32]
Study |
No. of patients (n, % female) |
Age |
Controls (n, half head?) |
Exclusion criteria: A. Recent use of topical/oral medications B. Bleeding disorders, anticoagulation C. Smokers D. Pregnant E. Scalp conditions other than AGA F. Propensity for keloids G. Immunosuppressed of systemic infections or untreated diabetes |
Clinical or biopsy diagnosed AGA |
---|---|---|---|---|---|
Randomized controlled trial |
|||||
Gentile et al[30] |
18, (0, 0%) for non-activated PRP 6 (0, 0%) for activated PRP |
Mean 37.4 for non-activated PRP Mean 40.8 for activated PRP |
Non-activated PRP: Placebo (18, half head) Activated PRP: no control |
A, B, F, G, and advanced hair loss stage 5–7 |
Biopsy |
Tawfik and Osman[34] |
30 (30, 100%) |
Mean 29.3 |
Placebo (30, half head) |
A, B, D, F, G |
Clinical |
Alves et al[35] |
22 (11, 50%) |
Mean 39 |
Placebo (22, half head) |
A, B, C, D, E or history of hair transplant |
Clinical |
Mapar et al[38] |
19 (0, 0%) |
Range 24–45 |
Placebo (19, half head) |
B, E, G or recent aspirin use |
Clinical |
Puig et al[31] |
26 (26, 100%) |
Age 18+ |
Placebo (11) |
A |
Clinical or biopsy |
Gentile et al[32] |
23 (0, 0%) |
Mean 35 |
Placebo (23, half head) |
A, B, F, G |
Biopsy |
Farid et al[33] |
20 (16, 80%) |
Mean 29.6 |
Group treated with minoxidil lotion (20) |
A, D, E, hyperandrogenemia |
Clinical |
Cervelli et al[36] |
10 (0, 0%) |
Mean 33 |
Placebo (10, half head) |
A, F, G |
Biopsy |
Prospective cohort study |
|||||
Anitua et al[15] |
19 (6, 32%) |
Range 27–60, (mean 45 + /− 11) |
– |
A, E |
Clinical |
Jha et al[16] |
20 (unknown, likely 0%) |
Range 18–45 |
Group treated with minoxidil lotion and oral finasteride (20) |
B, F, G, malignancy, HIV/HepB/HepC |
Clinical |
Kachhawa et al[17] |
44 (0, 0%) |
Mean 34 (18–55) |
Placebo (44, half head) |
A, B, G, patients with unrealistic expectations, current infection, malnutrition |
Clinical |
James et al[18] |
5 (0, 0%) |
Range 30–50 |
– |
A, G |
Clinical |
James et al[19] |
10 (2, 20%) |
Range 30–50 |
– |
A, G |
Clinical |
Rodrigues et al[20] |
15 (0, 0%) |
Range 18–50 |
– |
B, G, recent ASA/NSAID use, or history of hair transplant |
Clinical |
Borhan et al[21] |
14 (0, 0%) |
Range 18–60 |
– |
A |
Clinical |
Singhal et al[22] |
10 (2, 20%) |
Range 25–35 |
Placebo |
A, B, D, E, F, G, uncooperative patients |
Clinical |
Gkini et al[23] |
20 (2, 10%) |
Mean: 34 |
– |
A, B, E, F, G, anticoagulation |
Clinical |
Kang et al[12] |
26 (11, 42%) |
Mean 37.2 |
Group treated with interfollicular placental extract injections (13) |
A, F, G |
Clinical |
Khatu et al[24] |
11 (0, 0%) |
Range 20–40 |
– |
B, E, G |
Clinical |
Marwah et al[25] |
10 (0, 0%) |
Unknown |
– |
Not noted |
Clinical |
Sclafani[26] |
15 (6, 20%) |
Mean 43 |
– |
Not noted |
Clinical |
Betsi et al[27] |
42 (8, 19%) |
Range 32–67 |
– |
E, G |
Clinical |
Takikawa et al[28] |
26 (10, 38%) |
Range 28–59 |
Placebo (26, half head). |
Not noted |
Clinical |
Greco et al[29] |
10 (1, 10%) |
Unknown |
Placebo (5) |
Not noted |
Clinical |
Abbreviation: PRP, platelet-rich plasma.
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PRP Delivery Procedures
The delivery procedures of PRP in the different studies are outlined in [Table 2]. The delivery of PRP in the majority of studies was accomplished through injections using small gauge needles (e.g., 30-gauge, insulin syringes). Only two studies formulated PRP into a topical spray, although one used it as an adjunct to injections.[18] [33] A local anesthetic numbing agent was used in at least eight studies and was otherwise not reported in many others. The area of scalp treated varied widely between studies, but the most common areas were the frontal, parietal, and occipital scalp. The majority of studies (14 of 24) used activated PRP, typically via treatment with calcium chloride. Most studies used more than one treatment of PRP per patient: 20 of 24 studies used between 3 and 6 treatments. Three was the most common number of treatments used per patient during the study period, most often with 1 month intervals between each injection.
Study |
Activated PRP? |
Area of scalp treated |
Delivery method |
Total amount of agent used per treatment |
No. of treatments, interval |
Numbing agent |
---|---|---|---|---|---|---|
Randomized controlled trial |
||||||
Gentile et al[30] |
Both non-activated and activated |
Non-activated PRP: Scalp divided into frontal, parietal, vertex and occipital. If patient had frontal-parietal hair loss, PRP injected to the frontal scalp and placebo into the vertex. If the patient had parietal-vertex hair loss, PRP was injected into the parietal scalp and saline into the vertex. Activated PRP: 4 cm2 frontal |
Non-activated PRP: interfollicular injection with Ultim gun, 30 G needle Activated PRP: 25 G needle |
Non-activated: 0.2 mL/cm2 Activated: 0.25 mL/cm2 |
Non-activated: 3, monthly Activated: 1 |
No |
Tawfik and Osman[34] |
Yes |
Unknown |
Insulin syringe |
Unknown, <10 mL |
4, weekly |
Not noted |
Alves et al[35] |
Yes |
Two circular areas (one frontal and one occipital) in both treatment and control half heads Four circular areas were defined and marked centrally with a red permanent tattoo. |
30 G needle |
3 mL |
3, monthly |
No |
Mapar et al[38] |
Yes |
Two square-shaped areas of 2.5 cm × 2.5 cm, at least 3 cm apart from each other were selected on the scalp of each patient as case and control sites |
30 G needle |
1.5 mL |
2, monthly |
Not noted |
Puig et al[31] |
Yes |
10 cm2 area in central scalp |
Subcutaneous injection |
10 mL |
1 |
Yes |
Gentile et al[32] |
No |
Scalp divided into frontal, parietal, vertex and occipital. If patient had frontal-parietal hair loss, PRP injected to the frontal scalp and placebo into the vertex. If the patient had parietal-vertex hair loss, PRP was injected into the parietal scalp and saline into the vertex. |
30 G needle |
9 mL, injected 0.1 mL/cm2 |
3, monthly |
No |
Farid et al[33] |
No |
Imaginary vertical lines along the affected areas of the scalp. |
30 G needle injection, followed by manual dermaroller (0.5-mm needles), the remaining sprayed over the area and dermarolled again |
1 mL injected, 1 mL sprayed |
6, monthly |
Not noted |
Cervelli et al[36] |
Yes |
If patient had hair loss in frontal and parietal region: PRP in frontal area and placebo in parietal If patients had hair loss in parietal and vertex regions, PRP in parietal and placebo in vertex |
Injection |
9 mL |
3, monthly |
No |
Prospective cohort study |
||||||
Anitua et al[15] |
Yes |
Unspecified affected areas |
30 G needle |
3–4 cm3 |
5, 3 monthly then months 4 and 7 |
Not noted |
Jha et al[16] |
No |
Unspecified affected areas |
Injection with insulin syringe followed by microneedling |
Unknown |
3, 3 weeks |
Yes |
Kachhawa et al[17] |
No |
Unspecified affected areas on the left side |
Insulin syringe |
1–2cc |
6, 3 weeks |
Yes |
James et al[18] |
Yes |
Unspecified affected areas |
Insulin syringe |
Linear pattern 1-cm apart |
Every 2–3 weeks for 3 months |
Not noted |
James et al[19] |
Not noted |
Unspecified affected areas |
Twice a day spray |
Unknown |
6, twice monthly |
No |
Rodrigues et al[20] |
Yes |
Unspecified affected areas |
20 subcutaneous injections of 100μL |
Unknown |
4, 15 days |
Not noted |
Borhan et al[21] |
No |
Vertex |
32 G needle, 0.05–0.1 mL per injection |
4–5 mL |
4, 3 weeks between first three injections and 6 weeks for last injection |
Not noted |
Singhal et al[22] |
Yes |
Unspecified affected areas |
Insulin syringe |
8–12 mL |
4, 2 weeks |
Not noted |
Gkini et al[23] |
Yes |
Unspecified affected areas (frontal, parietal, occipital) |
27 G needle in linear pattern at depth of 1.5–2.5 mm |
∼6 mL |
3, 3 week intervals then 6 month booster |
Yes |
Kang et al[14] |
Yes |
Frontal and Parietal areas |
Injection |
4 mL, 0.05–0.1 mL/cm2. |
2, 3 months |
Yes |
Khatu et al[24] |
Yes |
1 cm × 1 cm area over right parietal area in mid-pupillary line |
Multiple small injections in a linear pattern 1 cm apart with insulin syringe |
2–3cc |
4, 2 weeks |
Yes |
Marwah et al[25] |
Not noted |
Unspecified affected areas |
Not noted |
Not noted |
6, weekly |
Not noted |
Sclafani et al[26] |
Yes |
2 cm 2 cm square in the midline |
0.1ml injections intradermally separated by 5–8 mm. |
8–9 mL |
3, monthly |
Not noted |
Betsi et al[27] |
Not noted |
Unspecified affected areas |
32 or 30.5 G needle |
8–12 mL |
5, all within 2 months |
Yes |
Takikawa et al[28] |
Not noted |
Frontal or Parietal sites with lanugo-like hair |
25 G needle |
3 mL |
5, at weeks 0, 2, 4, 6, and 9 |
Not noted |
Greco et al[29] |
Not noted |
Unspecified affected areas |
1-mm microneedling roller, then PRP injections every centimeter, then PRP spray |
10 mL |
1 |
Yes |
Abbreviations: G, gauge; PRP, platelet-rich plasma.
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Outcomes
The outcomes of applying PRP in patients with AGA are outlined in [Table 3]. The shortest follow-up time for studies was 6 weeks, and the longest was 1 year. Twenty-one (88%) of 24 studies reported positive outcomes. Thirteen studies (54%) reported statistically significant improvement in at least one objective outcome. Hair counts or hair densities were described by 16 studies,[15] [17] [20] [21] [23] [24] [26] [28] [30] [31] [32] [33] [34] [35] [36] [37] and of these, 12 found statistically significant improvements in one of these objective outcomes.
Study |
Follow-up time |
Positive interpretation of results? |
One statistically positive outcome? |
Objective outcome measures |
Blinded or independent subjective assessment |
Patient satisfaction surveys |
Complications |
---|---|---|---|---|---|---|---|
Randomized controlled trial |
|||||||
Gentile et al[30] |
Non-activated: 12 weeks Activated: 6 months |
Yes |
Yes |
Non-activated: Hair count,[a] hair density[a] Activated: hair density, follicular unit density (significant for one prep kit but not another) |
– |
– |
– |
Tawfik and Osman[34] |
6 months |
Yes |
Yes |
– |
Yes (mean overall satisfaction 7.0 out of 10) |
Temporary pain and pinpoint bleeding at injection sites. |
|
Alves et al[35] |
6 months |
Yes |
Yes |
Hair count, hair density,[a] anagen hair, Telogen hair, anagen/Telogen ratio, terminal hair density |
– |
– |
Local injection pain |
Mapar et al[38] |
6 months |
No |
No |
Terminal and vellus hair |
– |
– |
– |
Puig et al[31] |
26 weeks |
No |
No |
Hair count, “hair mass index” |
– |
Yes (13.3% vs 0% placebo reported improvement in hair loss, rate of hair loss, hair thickness, and ease of managing/styling hair) |
– |
Gentile et al[32] |
12 months |
Yes |
Yes |
Hair count,[a] hair density,[a] terminal hair density,[a] # of hair follicles,[a] epidermis thickness[a] # of small blood vessels around follicles,[a] # of Ki67+ basal keratinocytes,[a] vellus hair density |
– |
– |
– |
Farid et al[33] |
28 weeks |
Yes |
Yes |
Hair count[a] |
Yes, 45% of patients had improvement |
Yes (50 + /− 19.75 on a visual analog scale for improvement from 0 to 100) |
Pain during injection |
Cervelli et al[36] |
12 months |
Yes |
Yes |
Hair count,[a] hair density,[a] terminal hair density,[a] of hair follicles,[a] epidermis thickness,[a] # of small blood vessels around follicles,[a] # of Ki67+ basal keratinocytes,[a] vellus hair density |
– |
– |
– |
Prospective cohort study |
|||||||
Anitua et al[15] |
12 months |
Yes |
Yes |
Hair density,[a] mean hair diameter,[a] terminal/vellus-like hair ratio,[a] hair shaft thickness among terminal follicles[a] |
– |
Yes (48% satisfied/very satisfied) |
Transient erythema, local edema that disappeared after 24 hours. |
Jha et al[16] |
3 months |
Yes |
No[b] |
Vellus and total hair, hair shaft diameter, reduction in yellow dots |
– |
Yes (satisfaction was at least 75% on a 0 to 100 scale for 90% of patients) |
Mild pain in 7 patients, which subsided on the next day. |
Kachhawa et al[17] |
18 weeks |
Yes |
Yes |
– |
Yes (70% reported increased hair quality/thickness, 55% reported increased hair density) |
Pain that subsided after 4 hours. |
|
James et al[18] |
3 months |
Yes |
No[b] |
None |
– |
– |
– |
James et al[19] |
3 months |
Yes |
No[b] |
None |
– |
– |
– |
Rodrigues et al[20] |
150 days |
Yes |
Yes |
– |
– |
– |
|
Borhan et al[21] |
4 weeks |
Yes |
No[b] |
Percent hair gain, hair density |
Yes, equivocal among three evaluators (2 independent) |
Yes (100% noted improvement in texture, 50% noted growth back, etc.) |
– |
Singhal et al[22] |
12 weeks |
Yes |
No[b] |
Hair pull test |
– |
– |
Mild headache (n = 3) alleviated by paracetamol. |
Gkini et al[23] |
12 months |
Yes |
Yes |
Hair density[a] |
– |
Yes (mean rating of 7.1 on a scale of 1–10). |
Mild pain (100%), scalp sensitivity (60%) during first hair wash |
Kang et al[12] |
6 months |
Yes |
Yes |
Hair count,[a] hair thickness,[a] “two-point scoring method”[a] |
– |
– |
Transient erythema/edema |
Khatu et al[24] |
3 months |
Yes |
No[b] |
Hair count, hair pull test |
– |
Yes (mean rating of 7.0 on a scale of 1–10). |
Minimal pain, redness and pinpoint bleeding. |
Marwah et al[25] |
6 weeks |
Equivocal |
No[b] |
None |
– |
Yes (“all patients were satisfied with the results”) |
– |
Sclafani et al[26] |
6 months |
Yes |
Yes |
“Hair density index”[a] |
– |
Yes (not systematically reported) |
Mild-moderate pain during treatment. |
Betsi et al[27] |
3 months |
Yes |
No[b] |
Hair pull test |
– |
Yes (mean rating of 7.0 on a scale of 1–10) |
Drowsiness and sensible scalp (31%). |
Takikawa et al[28] |
12 weeks |
Yes |
Yes |
Hair count, hair cross-sectional thickness[a] |
– |
– |
Temporary pain at the injection site |
Greco et al[29] |
8 months |
Yes |
No[b] |
Hair shaft diameter |
– |
– |
– |
a Statistically significant.
b No statistical tests performed in this study.
Among studies with the highest level of evidence, six (75%) of eight RCTs reported positive treatment outcomes. All studies were half-head studies with PRP injections compared with saline injections, with the exception of one study by Farid et al that used a separate control group treated with minoxidil. Gentile et al performed a double-blinded RCT with 18 male patients and found that three sessions of non-activated PRP injections spaced 30 days apart increased hair count and density after 12 weeks as compared with controls.[30] Cervelli et al[36] and an older study by Gentile et al[32] found that three treatments of activated PRP given at 1-month intervals improved hair density count and hair density at 3 months follow-up in 10 male patients and 23 male patients, respectively. Similarly, Alves and Grimalt[35] studied 22 patients given three injections of PRP or saline at 1-month intervals; after 6 months, a statistically significant improvement in hair density was identified in treated half-heads. Tawfik and Osman[34] studied 30 female patients given injections weekly for a maximum of four sessions; patients had been followed up for 6 months, and a statistical significant difference was noted between PRP and placebo-treated areas in both hair density and hair thickness.
Three studies did not report positive findings after PRP administration including two RCTs. Mapar et al[38] performed a single-blinded trial of 19 male patients, finding that two injections of PRP administered 1 month apart did not increase the number of terminal and vellus hair after 3 or 6 months. In a double-blinded study of 26 female patients, Puig et al[31] reported no difference in hair counts 26 weeks after a single PRP treatment between treatment and placebo groups. However, subjectively, 26.7% of treated patients reported that their hair was coarser or heavier compared with 18.2% of control patients. Lastly, Marwah et al[25] performed a prospective cohort study administering six PRP treatments on 10 patients, finding clinical improvement by photography in only two (20%) patients. However, all patients were satisfied with their treatments.
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Meta-analysis
Meta-analysis of data was limited by the variety in treatment procedures and outcomes reported by studies. Among the studies with the highest level of data—the eight randomized control trials—four reported a common outcome of hair density at 3 months. However, one study (Gentile et al[30]) used non-activated PRP so it was removed from this subgroup. The remaining three studies had an I 2 statistic of 74% for difference in treatment group hair density compared with difference in control group hair density over 3 months, suggesting significant heterogeneity among studies. Therefore, no meta-analysis was performed.
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Complications
Few studies noted any complications from PRP treatment. Most noted temporary pain during injections[33] [34] and transient edema/erythema at the injection site.[15] [24] No allergic reactions, hematomas, or infections were reported.
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Discussion
Twenty-four studies were included in this systematic review of PRP for AGA. Eight studies were randomized controlled trials, and 16 were prospective cohort studies. Of these 24 articles, 21 reported objectively positive results, suggesting that PRP is a promising new treatment for AGA. The treatment was tolerated well with minimal to no side effects reported. Of the three studies that reported no significant outcomes for the use of PRP in patients with AGA, two notably used fewer injections than the average study reviewed. Puig et al[31] and Mapar et al[38] used one and two treatments per patient, respectively, whereas the vast majority of studies used three or more injections administered monthly.
A meta-analysis was unable to be performed due to significant heterogeneity among the small number of studies that reported the same outcomes. The most consistently reported outcome across studies was hair density after 3 months of treatment, which was used by Gupta and Carviel[39] in their recent meta-analysis of three of the studies included in this systematic review. At the time of that publication, several RCTs had not yet been published, and Gupta et al were able to include only comparisons of treatment versus baseline analyses, finding I 2 statistic of 0% (low heterogeneity of data) and ultimately a standardized mean difference of 0.51 (interpreted as a moderate effect size). Notably the analysis included one RCT,[36] but comparison to controls was not possible as remaining studies were cohort studies.[21] [23] [28] In this updated systematic review, the advantage of including several new studies with a high level of evidence did not translate into a usable meta-analysis statistic.
The limitations of this systematic review are found primarily in the quality of the included studies and the consistency of methods between studies. The 24 articles included in this analysis varied greatly in quality, ranging from brief reports of small patient populations and unclear methods to large double-blinded placebo-controlled half-head trials of up to 30 patients with detailed inclusion and exclusion criteria and well-defined outcomes. Quantitatively, studies varied dramatically in patient enrollment, sex of patients enrolled, and the quality of measured outcomes. Exclusion criteria varied greatly between studies, most notably as related to the how recently patients could use the FDA-approved medications for hair loss (finasteride and minoxidil). There were also several studies that allowed patients to use oral medications during the duration of the study that had to be excluded based on the a priori exclusion and inclusion criteria of this systematic review, to make the data and outcomes more clear for interpretation. For example, Schiavone et al studied 64 consecutive patients treated with a single injection of PRP, and two independent evaluators rated improvement in macrophotographs for over 95% of patients after 6 months; this study could not be included in this systematic review, however, as some patients who were using minoxidil or finasteride were encouraged to continue using their medications.[40]
Treatments with PRP were not uniform across studies. Most studies describe using 10 to 20 mL of blood from a peripheral venipuncture to produce 2 to 5 mL of PRP product using a variety of preparation kits. This was typically injected with a small gauge needle. James et al[18] notably did not inject PRP, but instead used it in a topical spray product. Farid and Abdelmaksoud[33] also employed a spray in addition to injections. Some studies used activated PRP (primarily through exposure to calcium) while a minority used non-activated PRP. Different preparatory methods of PRP as well as different numbers of treatments across varying periods make it difficult to generalize the parameters that promote hair growth using PRP.
Outcomes also varied between studies from those that used wholly qualitative, subjective analyses to those that used a variety of quantitative assessments. Among those with quantitative outcomes (such as hair density and hair count), the methods of counting hair and the intervals of follow-up were not reported uniformly. As a result, we could only attempt to include three studies[32] [35] [36] in the aforementioned meta-analysis, which ultimately showed significant heterogeneity.
This systematic review suggests that PRP may be a promising new treatment for AGA and readily implicates areas of future research. First, the optimum use of PRP in terms of preparation, activation, and treatment regimens is unknown. Dohan Ehrenfest et al describe a classification system of platelet concentrates based on preparatory process and leukocyte and fibrin content: pure platelet-rich plasma (P-PRP), leukocyte- and platelet-rich plasma (L-PRP), pure platelet-rich fibrin (P-PRF), and leukocyte and platelet-rich fibrin (L-PRF).[41] Anitua et al used a P-PRP system.[15] Tawfik et al,[34] Farid et al,[33] Jha et al,[16] Kachhawa et al,[17] Rodrigues et al,[20] Singhal et al,[22] and Khatu et al[24] used L-PRP based on descriptions of their preparations that included the buffy coat in their second step hard spin centrifugation. Gentile et al,[30] Borhan et al,[21] Betsi et al,[27] Gkini et al,[23] and Kang et al[37] referenced L-PRP systems (Regen or SmartPrep), but newer kits could variably generate L-PRP or P-PRP. Sclafani created a platelet-rich fibrin matrix that approximates P-PRF.[26] The remaining articles do not name specific preparatory kits or describe methods that fit easily within this system. Thorough exploration of the preparation processes and systems used may help elucidate the most effective platelet concentrate technology for hair regeneration.
Second, as patients with AGA can be affected from a young age, longer follow-up of patients is required to determine whether this treatment has long-lasting effects or whether repeated injections could be considered. Third, only 28% of patients in this systematic review were female and there remains limited information on potential gender differences in the effect of PRP. Lastly, the basic biological activity of PRP should be further explored. Many growth factors have been identified in PRP including platelet-derived growth factor, transforming growth factor-β, vascular endothelial growth facture, epidermal growth factor, and insulin-like growth factor. These growth factors are present in much higher concentrations (by a factor of five to eight times) in PRP than in whole blood, and PRP has been preliminarily shown to induce the proliferation of dermal papilla cells by upregulating fibroblast growth factor-7 (FGF-7), β-catenin, and extracellular-regulated kinase (ERK)/Akt signaling.[42] The precise biological pathways by which PRP promotes hair restoration remain unverified.
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Conclusion
This is the first systematic review in the facial plastic surgery literature dedicated to the use of PRP for hair restoration in patients with AGA. Out of 24 studies, 21 reported positive outcomes using PRP, with outcome measures ranging from qualitative photographic assessments to quantitative hair counts and hair density evaluations. Further research methodically examining the patient populations that benefit most from this treatment, optimizing preparation and administration procedures and following up long-term outcomes, is needed. PRP appears to be a safe technology with the potential for promoting hair restoration.
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Conflicts of Interest
None.
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References
- 1 Hamilton JB. Patterned loss of hair in man; types and incidence. Ann N Y Acad Sci 1951; 53 (03) 708-728
- 2 Gan DCC, Sinclair RD. Prevalence of male and female pattern hair loss in Maryborough. J Investig Dermatol Symp Proc 2005; 10 (03) 184-189
- 3 Krupa Shankar D, Chakravarthi M, Shilpakar R. Male androgenetic alopecia: population-based study in 1,005 subjects. Int J Trichology 2009; 1 (02) 131-133
- 4 Tabolli S, Sampogna F, di Pietro C, Mannooranparampil TJ, Ribuffo M, Abeni D. Health status, coping strategies, and alexithymia in subjects with androgenetic alopecia: a questionnaire study. Am J Clin Dermatol 2013; 14 (02) 139-145
- 5 Bater KL, Ishii M, Joseph A, Su P, Nellis J, Ishii LE. Perception of hair transplant for androgenetic alopecia. JAMA Facial Plast Surg 2016; 18 (06) 413-418
- 6 Bernstein RM, Rassman WR. Follicular transplantation. Patient evaluation and surgical planning. Dermatol Surg 1997; 23 (09) 771-784 , discussion 801–805
- 7 Harris JA. Follicular unit extraction. Facial Plast Surg Clin North Am 2013; 21 (03) 375-384
- 8 Beitzel K, Allen D, Apostolakos J. , et al. US definitions, current use, and FDA stance on use of platelet-rich plasma in sports medicine. J Knee Surg 2015; 28 (01) 29-34
- 9 Ulusal BG. Platelet-rich plasma and hyaluronic acid - an efficient biostimulation method for face rejuvenation. J Cosmet Dermatol 2017; 16 (01) 112-119
- 10 Asif M, Kanodia S, Singh K. Combined autologous platelet-rich plasma with microneedling verses microneedling with distilled water in the treatment of atrophic acne scars: a concurrent split-face study. J Cosmet Dermatol 2016; 15 (04) 434-443
- 11 Shin M-K, Lee J-H, Lee S-J, Kim N-I. Platelet-rich plasma combined with fractional laser therapy for skin rejuvenation. Dermatol Surg 2012; 38 (04) 623-630
- 12 Kang J-S, Zheng Z, Choi MJ, Lee S-H, Kim D-Y, Cho SB. The effect of CD34+ cell-containing autologous platelet-rich plasma injection on pattern hair loss: a preliminary study. J Eur Acad Dermatol Venereol 2014; 28 (01) 72-79
- 13 Sclafani AP, Azzi J. Platelet preparations for use in facial rejuvenation and wound healing: a critical review of current literature. Aesthetic Plast Surg 2015; 39 (04) 495-505
- 14 Moher D, Shamseer L, Clarke M. , et al; PRISMA-P Group. Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015 statement. Syst Rev 2015; 4: 1-9
- 15 Anitua E, Pino A, Martinez N, Orive G, Berridi D. The effect of plasma rich in growth factors on pattern hair loss: a pilot study. Dermatol Surg 2017; 43 (05) 658-670
- 16 Jha AK, Udayan UK, Roy PK, Amar AKJ, Chaudhary RKP. Original article: Platelet-rich plasma with microneedling in androgenetic alopecia along with dermoscopic pre- and post-treatment evaluation. J Cosmet Dermatol 2017; 17 (09) 313-318
- 17 Kachhawa D, Vats G, Sonare D, Rao P, Khuraiya S, Kataiya R. A spilt head study of efficacy of placebo versus platelet-rich plasma injections in the treatment of androgenic alopecia. J Cutan Aesthet Surg 2017; 10 (02) 86-89
- 18 James R, Chetry R, Subramanian V. , et al. Platelet-rich plasma growth factor concentrated spray (Keratogrow®) as a potential treatment for androgenic alopecia. J Stem Cells 2016; 11 (04) 183-189
- 19 James R, Chetry R, Subramanian V. , et al. Efficacy of activated 3x platelet-rich plasma in the treatment of androgenic alopecia. J Stem Cells 2016; 11 (04) 191-199
- 20 Rodrigues BL, Montalvão SADL, Annichinno-Bizzacchi J. , et al. The therapeutic response of platelet rich plasma (PRP) for androgenetic alopecia showed no correlation with growth factors and platelet number. Blood 2016; 128 (22) 2637-2637
- 21 Borhan R, Gasnier C, Reygagne P. Autologous platelet rich plasma as a treatment of male androgenetic alopecia: study of 14 cases. J Clin Exp Dermatol Res 2015; 6 (04) 1-6
- 22 Singhal P, Agarwal S, Dhot PS, Sayal SK. Efficacy of platelet-rich plasma in treatment of androgenic alopecia. Asian J Transfus Sci 2015; 9 (02) 159-162
- 23 Gkini M-A, Kouskoukis A-E, Tripsianis G, Rigopoulos D, Kouskoukis K. Study of platelet-rich plasma injections in the treatment of androgenetic alopecia through an one-year period. J Cutan Aesthet Surg 2014; 7 (04) 213-219
- 24 Khatu SS, More YE, Gokhale NR, Chavhan DC, Bendsure N. Platelet-rich plasma in androgenic alopecia: myth or an effective tool. J Cutan Aesthet Surg 2014; 7 (02) 107-110
- 25 Marwah M, Godse K, Patil S, Nadkarni N. Is there sufficient research data to use platelet-rich plasma in dermatology?. Int J Trichology 2014; 6 (01) 35-36
- 26 Sclafani AP. Platelet-rich fibrin matrix (PRFM) for androgenetic alopecia. Facial Plast Surg 2014; 30 (02) 219-224
- 27 Betsi E-E, Germain E, Kalbermatten DF, Tremp M, Emmenegger V. Platelet-rich plasma injection is effective and safe for the treatment of alopecia. Eur J Plast Surg 2013; 36 (07) 407-412
- 28 Takikawa M, Nakamura S, Nakamura S. , et al. Enhanced effect of platelet-rich plasma containing a new carrier on hair growth. Dermatol Surg 2011; 37 (12) 1721-1729
- 29 Greco J, Brandt R. The effects of autologous platelet rich plasma and various growth factors on non-transplanted miniaturized hair. Hair Transpl Forum Int 2009; 19: 49-50
- 30 Gentile P, Cole JP, Cole MA. , et al. Evaluation of not-activated and activated PRP in hair loss treatment: role of growth factor and cytokine concentrations obtained by different collection systems. Int J Mol Sci 2017; 18 (02) E408s
- 31 Puig CJ, Reese R, Peters M. Double-blind, placebo-controlled pilot study on the use of platelet-rich plasma in women with female androgenetic alopecia. Dermatol Surg 2016; 42 (11) 1243-1247
- 32 Gentile P, Garcovich S, Bielli A, Scioli MG, Orlandi A, Cervelli V. The effect of platelet-rich plasma in hair regrowth: a randomized placebo-controlled trial. Stem Cells Transl Med 2015; 4 (11) 1317-1323
- 33 Farid CI, Abdelmaksoud RA. Platelet-rich plasma microneedling versus 5% topical minoxidil in the treatment of patterned hair loss. J Egypt Women's Dermatol Soc 2016; 13 (01) 29-36
- 34 Tawfik AA, Osman MAR. The effect of autologous activated platelet-rich plasma injection on female pattern hair loss: a randomized placebo-controlled study. J Cosmet Dermatol 2018; 17 (01) 47-53
- 35 Alves R, Grimalt R. Randomized placebo-controlled, double-blind, half-head study to assess the efficacy of platelet-rich plasma on the treatment of androgenetic alopecia. Dermatol Surg 2016; 42 (04) 491-497
- 36 Cervelli V, Garcovich S, Bielli A. , et al. The effect of autologous activated platelet rich plasma (AA-PRP) injection on pattern hair loss: clinical and histomorphometric evaluation. BioMed Res Int 2014; 2014: 760709
- 37 Kang R, Nimmons GL, Drennan W. , et al. Development and validation of the University of Washington Clinical Assessment of Music Perception test. Ear Hear 2009; 30 (04) 411-418
- 38 Mapar MA, Shahriari S, Haghighizadeh MH. Efficacy of platelet-rich plasma in the treatment of androgenetic (male-patterned) alopecia: a pilot randomized controlled trial. J Cosmet Laser Ther 2016; 18 (08) 452-455
- 39 Gupta AK, Carviel JL. Meta-analysis of efficacy of platelet-rich plasma therapy for androgenetic alopecia. J Dermatolog Treat 2017; 28 (01) 55-58
- 40 Schiavone G, Raskovic D, Greco J, Abeni D. Platelet-rich plasma for androgenetic alopecia: a pilot study. Dermatol Surg 2014; 40 (09) 1010-1019
- 41 Dohan Ehrenfest DM, Rasmusson L, Albrektsson T. Classification of platelet concentrates: from pure platelet-rich plasma (P-PRP) to leucocyte- and platelet-rich fibrin (L-PRF). Trends Biotechnol 2009; 27 (03) 158-167
- 42 Gupta AK, Carviel J. A mechanistic model of platelet-rich plasma treatment for androgenetic alopecia. Dermatol Surg 2016; 42 (12) 1335-1339
Address for correspondence
-
References
- 1 Hamilton JB. Patterned loss of hair in man; types and incidence. Ann N Y Acad Sci 1951; 53 (03) 708-728
- 2 Gan DCC, Sinclair RD. Prevalence of male and female pattern hair loss in Maryborough. J Investig Dermatol Symp Proc 2005; 10 (03) 184-189
- 3 Krupa Shankar D, Chakravarthi M, Shilpakar R. Male androgenetic alopecia: population-based study in 1,005 subjects. Int J Trichology 2009; 1 (02) 131-133
- 4 Tabolli S, Sampogna F, di Pietro C, Mannooranparampil TJ, Ribuffo M, Abeni D. Health status, coping strategies, and alexithymia in subjects with androgenetic alopecia: a questionnaire study. Am J Clin Dermatol 2013; 14 (02) 139-145
- 5 Bater KL, Ishii M, Joseph A, Su P, Nellis J, Ishii LE. Perception of hair transplant for androgenetic alopecia. JAMA Facial Plast Surg 2016; 18 (06) 413-418
- 6 Bernstein RM, Rassman WR. Follicular transplantation. Patient evaluation and surgical planning. Dermatol Surg 1997; 23 (09) 771-784 , discussion 801–805
- 7 Harris JA. Follicular unit extraction. Facial Plast Surg Clin North Am 2013; 21 (03) 375-384
- 8 Beitzel K, Allen D, Apostolakos J. , et al. US definitions, current use, and FDA stance on use of platelet-rich plasma in sports medicine. J Knee Surg 2015; 28 (01) 29-34
- 9 Ulusal BG. Platelet-rich plasma and hyaluronic acid - an efficient biostimulation method for face rejuvenation. J Cosmet Dermatol 2017; 16 (01) 112-119
- 10 Asif M, Kanodia S, Singh K. Combined autologous platelet-rich plasma with microneedling verses microneedling with distilled water in the treatment of atrophic acne scars: a concurrent split-face study. J Cosmet Dermatol 2016; 15 (04) 434-443
- 11 Shin M-K, Lee J-H, Lee S-J, Kim N-I. Platelet-rich plasma combined with fractional laser therapy for skin rejuvenation. Dermatol Surg 2012; 38 (04) 623-630
- 12 Kang J-S, Zheng Z, Choi MJ, Lee S-H, Kim D-Y, Cho SB. The effect of CD34+ cell-containing autologous platelet-rich plasma injection on pattern hair loss: a preliminary study. J Eur Acad Dermatol Venereol 2014; 28 (01) 72-79
- 13 Sclafani AP, Azzi J. Platelet preparations for use in facial rejuvenation and wound healing: a critical review of current literature. Aesthetic Plast Surg 2015; 39 (04) 495-505
- 14 Moher D, Shamseer L, Clarke M. , et al; PRISMA-P Group. Preferred reporting items for systematic review and meta-analysis protocols (PRISMA-P) 2015 statement. Syst Rev 2015; 4: 1-9
- 15 Anitua E, Pino A, Martinez N, Orive G, Berridi D. The effect of plasma rich in growth factors on pattern hair loss: a pilot study. Dermatol Surg 2017; 43 (05) 658-670
- 16 Jha AK, Udayan UK, Roy PK, Amar AKJ, Chaudhary RKP. Original article: Platelet-rich plasma with microneedling in androgenetic alopecia along with dermoscopic pre- and post-treatment evaluation. J Cosmet Dermatol 2017; 17 (09) 313-318
- 17 Kachhawa D, Vats G, Sonare D, Rao P, Khuraiya S, Kataiya R. A spilt head study of efficacy of placebo versus platelet-rich plasma injections in the treatment of androgenic alopecia. J Cutan Aesthet Surg 2017; 10 (02) 86-89
- 18 James R, Chetry R, Subramanian V. , et al. Platelet-rich plasma growth factor concentrated spray (Keratogrow®) as a potential treatment for androgenic alopecia. J Stem Cells 2016; 11 (04) 183-189
- 19 James R, Chetry R, Subramanian V. , et al. Efficacy of activated 3x platelet-rich plasma in the treatment of androgenic alopecia. J Stem Cells 2016; 11 (04) 191-199
- 20 Rodrigues BL, Montalvão SADL, Annichinno-Bizzacchi J. , et al. The therapeutic response of platelet rich plasma (PRP) for androgenetic alopecia showed no correlation with growth factors and platelet number. Blood 2016; 128 (22) 2637-2637
- 21 Borhan R, Gasnier C, Reygagne P. Autologous platelet rich plasma as a treatment of male androgenetic alopecia: study of 14 cases. J Clin Exp Dermatol Res 2015; 6 (04) 1-6
- 22 Singhal P, Agarwal S, Dhot PS, Sayal SK. Efficacy of platelet-rich plasma in treatment of androgenic alopecia. Asian J Transfus Sci 2015; 9 (02) 159-162
- 23 Gkini M-A, Kouskoukis A-E, Tripsianis G, Rigopoulos D, Kouskoukis K. Study of platelet-rich plasma injections in the treatment of androgenetic alopecia through an one-year period. J Cutan Aesthet Surg 2014; 7 (04) 213-219
- 24 Khatu SS, More YE, Gokhale NR, Chavhan DC, Bendsure N. Platelet-rich plasma in androgenic alopecia: myth or an effective tool. J Cutan Aesthet Surg 2014; 7 (02) 107-110
- 25 Marwah M, Godse K, Patil S, Nadkarni N. Is there sufficient research data to use platelet-rich plasma in dermatology?. Int J Trichology 2014; 6 (01) 35-36
- 26 Sclafani AP. Platelet-rich fibrin matrix (PRFM) for androgenetic alopecia. Facial Plast Surg 2014; 30 (02) 219-224
- 27 Betsi E-E, Germain E, Kalbermatten DF, Tremp M, Emmenegger V. Platelet-rich plasma injection is effective and safe for the treatment of alopecia. Eur J Plast Surg 2013; 36 (07) 407-412
- 28 Takikawa M, Nakamura S, Nakamura S. , et al. Enhanced effect of platelet-rich plasma containing a new carrier on hair growth. Dermatol Surg 2011; 37 (12) 1721-1729
- 29 Greco J, Brandt R. The effects of autologous platelet rich plasma and various growth factors on non-transplanted miniaturized hair. Hair Transpl Forum Int 2009; 19: 49-50
- 30 Gentile P, Cole JP, Cole MA. , et al. Evaluation of not-activated and activated PRP in hair loss treatment: role of growth factor and cytokine concentrations obtained by different collection systems. Int J Mol Sci 2017; 18 (02) E408s
- 31 Puig CJ, Reese R, Peters M. Double-blind, placebo-controlled pilot study on the use of platelet-rich plasma in women with female androgenetic alopecia. Dermatol Surg 2016; 42 (11) 1243-1247
- 32 Gentile P, Garcovich S, Bielli A, Scioli MG, Orlandi A, Cervelli V. The effect of platelet-rich plasma in hair regrowth: a randomized placebo-controlled trial. Stem Cells Transl Med 2015; 4 (11) 1317-1323
- 33 Farid CI, Abdelmaksoud RA. Platelet-rich plasma microneedling versus 5% topical minoxidil in the treatment of patterned hair loss. J Egypt Women's Dermatol Soc 2016; 13 (01) 29-36
- 34 Tawfik AA, Osman MAR. The effect of autologous activated platelet-rich plasma injection on female pattern hair loss: a randomized placebo-controlled study. J Cosmet Dermatol 2018; 17 (01) 47-53
- 35 Alves R, Grimalt R. Randomized placebo-controlled, double-blind, half-head study to assess the efficacy of platelet-rich plasma on the treatment of androgenetic alopecia. Dermatol Surg 2016; 42 (04) 491-497
- 36 Cervelli V, Garcovich S, Bielli A. , et al. The effect of autologous activated platelet rich plasma (AA-PRP) injection on pattern hair loss: clinical and histomorphometric evaluation. BioMed Res Int 2014; 2014: 760709
- 37 Kang R, Nimmons GL, Drennan W. , et al. Development and validation of the University of Washington Clinical Assessment of Music Perception test. Ear Hear 2009; 30 (04) 411-418
- 38 Mapar MA, Shahriari S, Haghighizadeh MH. Efficacy of platelet-rich plasma in the treatment of androgenetic (male-patterned) alopecia: a pilot randomized controlled trial. J Cosmet Laser Ther 2016; 18 (08) 452-455
- 39 Gupta AK, Carviel JL. Meta-analysis of efficacy of platelet-rich plasma therapy for androgenetic alopecia. J Dermatolog Treat 2017; 28 (01) 55-58
- 40 Schiavone G, Raskovic D, Greco J, Abeni D. Platelet-rich plasma for androgenetic alopecia: a pilot study. Dermatol Surg 2014; 40 (09) 1010-1019
- 41 Dohan Ehrenfest DM, Rasmusson L, Albrektsson T. Classification of platelet concentrates: from pure platelet-rich plasma (P-PRP) to leucocyte- and platelet-rich fibrin (L-PRF). Trends Biotechnol 2009; 27 (03) 158-167
- 42 Gupta AK, Carviel J. A mechanistic model of platelet-rich plasma treatment for androgenetic alopecia. Dermatol Surg 2016; 42 (12) 1335-1339
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