Can Plant Extracts Help Prevent Hair Loss or Promote Hair Growth? A Review Comparing Their Therapeutic Efficacies, Phytochemical Components, and Modulatory Targets

Abstract

This narrative review aims to examine the therapeutic potential and mechanism of action of plant extracts in preventing and treating alopecia (baldness). We searched and selected research papers on plant extracts related to hair loss, hair growth, or hair regrowth, and comprehensively compared the therapeutic efficacies, phytochemical components, and modulatory targets of plant extracts. These studies showed that various plant extracts increased the survival and proliferation of dermal papilla cells in vitro, enhanced cell proliferation and hair growth in hair follicles ex vivo, and promoted hair growth or regrowth in animal models in vivo. The hair growth-promoting efficacy of several plant extracts was verified in clinical trials. Some phenolic compounds, terpenes and terpenoids, sulfur-containing compounds, and fatty acids were identified as active compounds contained in plant extracts. The pharmacological effects of plant extracts and their active compounds were associated with the promotion of cell survival, cell proliferation, or cell cycle progression, and the upregulation of several growth factors, such as IGF-1, VEGF, HGF, and KGF (FGF-7), leading to the induction and extension of the anagen phase in the hair cycle. Those effects were also associated with the alleviation of oxidative stress, inflammatory response, cellular senescence, or apoptosis, and the downregulation of male hormones and their receptors, preventing the entry into the telogen phase in the hair cycle. Several active plant extracts and phytochemicals stimulated the signaling pathways mediated by protein kinase B (PKB, also called AKT), extracellular signal-regulated kinases (ERK), Wingless and Int-1 (WNT), or sonic hedgehog (SHH), while suppressing other cell signaling pathways mediated by transforming growth factor (TGF)-β or bone morphogenetic protein (BMP). Thus, well-selected plant extracts and their active compounds can have beneficial effects on hair health. It is proposed that the discovery of phytochemicals targeting the aforementioned cellular events and cell signaling pathways will facilitate the development of new targeted therapies for alopecia.

1. Introduction

Hair, a filament-like structure composed of keratin proteins and melanin pigments, grows from the dermis and goes out of the epidermis [1]. Its upper part is called the hair shaft and the lower part is called the hair root [2]. The hair and various cells and matrices around and below it form a mini-organ called a hair follicle [2,3]. The lateral sides of the hair root are surrounded by the inner and outer root sheath cells [4]. The underside of the hair root is bulb-shaped, and the hair root is in contact with the papilla cells of the dermis, which are surrounded by matrix cells (keratinocytes) [5,6]. The capillaries in the subcutaneous tissue beneath the papilla provide the nutrients, oxygen, and growth factors necessary for hair growth. Stem cells reside in the outer root sheath, located in the bulge of the hair follicle [7,8]. Dermal papilla cells release hormones that stimulate the differentiation of stem cells into different cell types via progenitor cells. Matrix cells act as germ cells and differentiate into the inner root sheath and keratin-producing cells. These cells continue dividing, proliferating, differentiating, and keratinizing, leading to hair production and growth. Melanocytes within the layer of matrix cells produce and supply melanin pigments, which are incorporated into the hair.

Hairs contribute to various skin functions, such as physical protection, insulation, sebum dispersal, sensory perception, etc. [9]. Additionally, in human society, hair greatly impacts self-esteem, quality of life, attractiveness, and social interactions [10]. Various factors, such as genetics, immune reactions, hormonal imbalances, inflammation, increased stress, poor nutrition, and medications, can cause hair loss accompanied by anagen to telogen transition [11,12,13,14]. Although hair loss is not a major disease that threatens life or entails serious functional disability, some people are saddened and dissatisfied with hair loss since it affects human appearance [15].

The hair cycle consists of three distinct phases: anagen (growth) phase, catagen (regression, intermediate, or transition) phase, and telogen (resting) phase [7]. The anagen phase lasts 3 to 5 years and more than 80% of human hair is in this phase. The catagen phase lasts about a month and 3% of human hair is in this phase. In the catagen phase, hair growth stops, and the hair bulb recedes toward the surface of the scalp. The telogen phase lasts, on average, 2 to 7 months, and 10 to 20% of human hair is in this phase. In the telogen phase, hairs are loosely attached to the hair follicle while its bulb is dormant. At the end of the telogen phase, when a new hair cycle begins, new hair shafts push out existing hairs, causing them to fall out. This stage is also classified separately as the exogen (shedding) phase [16].

Hair loss types are classified into scarring alopecia, non-scarring alopecia, and structural hair disorders [17]. Scarring alopecia is caused by tissue damage that leads to the irreversible and permanent loss of hair follicles. In non-scarring alopecia, the function of hair follicles is temporally suppressed but may be recoverable using certain treatments, leading to hair regrowth. The fragility of the hair shafts causes structural hair disorders. Non-scarring alopecia includes focal hair loss, diffused hair loss, and patterned hair loss, such as androgenetic alopecia in men (male pattern hair loss), female pattern hair loss, and trichotillomania [18].

Several medicines can treat hair loss in humans [19]. Minoxidil, originally developed as a drug to lower blood pressure by dilating blood vessels, was unexpectedly found to stimulate hair growth, and thus was later developed as a hair growth promoter [20,21,22]. Minoxidil has been described to stimulate cell proliferation, vascular endothelial growth factor (VEGF) expression, and prostaglandin synthesis while inhibiting collagen synthesis in various skin and hair follicle cell types [23]. Finasteride and dutasteride, inhibitors of steroid 5α-reductase enzyme, which converts testosterone into dihydrotestosterone (DHT), were originally developed to treat the symptoms of benign prostatic hyperplasia [24] and are also used to treat male androgenetic alopecia [25]. Finasteride selectively inhibits steroid 5α-reductase type II isozyme and dutasteride inhibits both type I and II isozymes [26]. Various other strategies including cell-based treatments [27] and natural product-based treatments [28] are being attempted to treat hair loss.

Plants have unique survival strategies and synthesize and utilize various metabolites that animals do not have, and these are called phytochemicals [29]. Phytochemicals are broadly classified into phenolic compounds, terpenes/terpenoids, nitrogen-containing compounds, sulfur-containing compounds, etc., and have various physicochemical, biochemical, and biological activities depending on their chemical structures [30]. Plant extracts have been applied to treat human diseases in traditional medicine, and single compounds derived from plants have been developed into medicines or provided a basis for the development of other new drugs [31]. Plant-derived extracts and compounds have been used to protect the skin against environmental factors, such as ultraviolet rays [32] and air pollution [33], and to alleviate several skin conditions, such as inflammation [34] and keloid scar [35]. The biological activity and pharmacological effects of various plant-derived extracts and compounds have also been studied for their potential application in promoting hair health [28,36,37].

Although several medicines already serve good roles in hair loss prevention and hair growth promotion, natural products can provide an alternative option for hair care, offering ease and comfort to people who do not prefer chemically manufactured oral pills or topical agents. The primary purpose of this review is to examine the therapeutic potential of plant extracts in preventing hair loss or promoting hair growth or regrowth. Given the presence of other review papers on similar topics [28,36,37], this review focuses on comparing the therapeutic efficacies, phytochemical components, and modulatory targets of plant extracts evaluated in recent studies. We hope that this review will contribute to understanding the current status and prospects of research in this field and developing new therapeutic strategies for hair loss.

2. Methods

We accessed the PubMed database (https://pubmed.ncbi.nlm.nih.gov/, accessed on 30 April 2024) to search for research articles related to the topic of this narrative review. A preliminary literature search using various keywords, such as ‘hair loss’, ‘hair growth’, ‘hair regrowth’, ‘extract’, ‘plant’, ‘herb’, ‘root’, ‘leaf’, ‘leaves’, ‘stem’, and ‘flower’, and Boolean search commands, such as ‘AND’ and ‘OR’, resulted in hundreds of research articles that were too many to be explored in-depth in a single review paper. We refined the search results by limiting the search ranges for some keywords to title words only to select more highly focused studies. We used the following key terms: (hair loss[Title] OR hair growth[Title] OR hair regrowth[Title]) AND extract[Title] AND (plant OR herb OR root OR leaf OR leaves OR stem OR flower). This search identified 57 research articles written in English. Additionally, we accessed the Web of Science (https://www.webofscience.com/, accessed on 30 April 2024) and Google Scholar (https://scholar.google.com/, accessed on 30 April 2024) databases for an additional literature search, identifying 38 more research articles that examined plant extracts including several marine plants. Most identified research articles are cited and explored in the appropriate chapter(s) according to their contents, excluding a few articles that investigated the extracts of animals or fungi (4 articles), or only pure compounds (2 articles).

Chemical structures of phytochemicals, validated by comparing with the information in the PubChem database (https://pubchem.ncbi.nlm.nih.gov/, accessed on 30 April 2024), were drawn using ACD/ChemSketch 12.0 software (ACD/Labs, Toronto, ON, Canada).

3. Therapeutic Efficacies of Plant Extracts

3.1. Effects of Plant Extracts on Dermal Papilla Cells In Vitro

The fates of dermal papilla cells are closely related to the hair growth cycle. Therefore, the viability and proliferation of dermal papilla cells are useful targets to prevent hair loss and promote hair growth.

Table 1 summarizes the extracts derived from a plant or several plants that have been reported to enhance the proliferation of human follicle dermal papilla cells (HFDPCs) or related cells in vitro. Table 2 summarizes the plant extracts that enhanced cell viability reduced by testosterone or DHT.

Table 1.

Effects of plant extracts on the proliferation of dermal papilla cells in vitro.

Plant Extracts	Cell Types	Assays	Effective Concentrations *	Literature
Ethanol (EtOH) extract of roots of Asiasarum heterotropoides (or Asiasarum sieboldi)	Human follicle dermal papilla cells (HFDPCs)	[3 H]-thymidine incorporation	0.1 μg mL−1	Rho et al., 2005 [38]
70% EtOH extract of Erica multiflora	HFDPCs	3-(4,5-Dimethyl thiazol-2-yl)-2,5-diphenyl tetrazolium (MTT) reduction	500 and 5000 μg mL−1	Kawano et al., 2009 [39]
Water extract of tubers of Aconiti Ciliare	Human immortalized dermal papilla cells (iDPCs)	2-(2-Methoxy-4-nitrophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium (WST-1) reduction	5, 10, and 20 μg mL−1	Park et al., 2012 [40]
50% EtOH extract of florets of Carthamus tinctorius	HFDPCs	MTT reduction	5–1250 μg mL−1	Junlatat and Sripanidkulchai, 2014 [41]
50% methanol (MeOH) extract of Platycarya strobilacea	HFDPCs	CCK-8 assay using 2-(2-Methoxy-4-nitrophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium (WST-8) reduction	9.8, 19.5, 39.1, and 156.3 μg mL−1	Kim et al., 2014 [42]
Extract of red ginseng (Panax ginseng)	HFDPCs	CCK-8 assay	300 μg mL−1	Park et al., 2015 [43]
95% EtOH extract of roots of Rumex japonicus	HFDPCs	MTT reduction	5, 10, 50, and 100 μg mL−1	Lee et al., 2016 [44]
DA-5512 formula (EtOH extract of herbal mixture: Thea sinensis, Emblica officinalis, Pinus densiflora, Pueraria thunbergiana, Tribulus terrestris, and Zingiber officinale)	HFDPCs	Ki-67 staining	100 μg mL−1	Yu et al., 2017 [45]
MeOH extract of Geranium sibiricum	HFDPCs	CCK-8 (WST-8) reduction	19.5 μg mL−1	Boisvert et al., 2017 [46]
Extract of Orthosiphon stamineus	HFDPCs	PrestoBlue assay using resazurin reduction	25, 50, 125, and 250 μg mL−1	Somsukskul et al., 2017 [47]
Water extract of Cinnamomum osmophloeum	HFDPCs	MTT reduction	5000 μg mL−1	Wen et al., 2018 [48]
50% EtOH extract Houttuynia cordata	HFDPCs	Bromodeoxyuridine (BrdU) incorporation	20 and 50 μg mL−1	Kim et al., 2019 [49]
RE-ORGA (hot water extract of herbal mixture: Panax ginseng, Glycine max, Houttuynia cordata, Lycium chinense, Glycyrrhiza uralensis, Citrus unshiu, Zizyphus jujuba, Perilla frutescens, Camellia sinensis, and Cynanchum wilfordii)	HFDPCs	CCK-8 assay	10,000, 50,000, and 100,000 μg mL−1	Kang et al., 2019 [50]
50% EtOH extract of Polygonum multiflorum	HFDPCs	CCK-8 assay	10 and 100 μg mL−1	Shin et al., 2020 [51]
MeOH extract of Salvia plebeia	HFDPCs	CCK-8 assay	15.6, 31.3, and 62.5 μg mL−1	Jin et al., 2020 [52]
50% EtOH extract of Plumbago zeylanica	HFDPCs	Cell counting	0.2 μg mL−1	Yamada et al., 2020 [53]
Phyllotex™ (a herbal formula: Euterpe oleracea, Olea europea, Tabebuia impetiginosa, and Coffea Arabica)	HFDPCs	MTT reduction	60–2000 μg mL−1	Serruya and Maor, 2021 [54]
50% MeOH extract of lotus (Nelumbo nucifera) seeds	HFDPCs	CCK-8 assay	31.25, 62.5, 125, and 250 μg mL−1	Park et al., 2021 [55]
80% MeOH extract of centipedegrass (Eremochloa ophiuroides)	HFDPCs	MTT reduction	6.2, 12.5, 25, and 50 μg mL−1	Ramadhani et al., 2022 [56]
MeOH extract of shallot (Allium ascalonicum)	HFDPCs	Sulforhodamine B (SRB) assay	100 μg mL−1	Ruksiriwanich et al., 2022 [57]
60% EtOH extract of Camellia japonica seed cakes	HFDPCs	MTT reduction	20 μg mL−1	Wang et al., 2022 [58]
Hot water extract of Lycopus lucidus	HFDPCs	CCK-8 assay	50 μg mL−1	Lee et al., 2022 [59]
Hot water extract of mangosteen (Garcinia mangostana) pericarps	HFDPCs	WST-1 reduction	62.5, 125, 250, and 500 μg mL−1	Tan et al., 2022 [60]
70% EtOH extract of fruit shells of Camellia japonica	HFDPCs	Ki-67 staining	10 and 50 μg mL−1	You et al., 2023 [61]
Water extract of banana (Musa paradisiaca) flowers	HFDPCs	MTT reduction	62.5 and 125 μg mL−1	Liang et al., 2023 [62]
20% EtOH extract of Panax ginseng	iDPCs and immortalized human outer root sheath cells (ORSCs)	AlamarBlue assay using resazurin (7-hydroxy-3H-phenoxazin-3-one 10-oxide) reduction	50 and 100 μg mL−1	Iwabuchi et al., 2024 [63]
Extract of leaves of Gynostemma pentaphyllum	HFDPCs	CCK-8 assay	50, 100, 200, and 400 μg mL−1	Liu et al., 2024 [64]
70% EtOH extract of flowers of Silybum marianum	HFDPCs	MTT reduction	50 and 100 μg mL−1	You et al., 2024 [65]

* Concentrations at which the plant extract enhanced cell proliferation compared to the vehicle control.

Table 2.

Effects of plant extracts on the viability of HFDPCs treated with androgens in vitro.

Plant Extracts	Cell Types	Androgens	Assays	Effective Concentrations *	Literature
Extract of Brassica oleracea	HFDPCs	50 μg mL−1 testosterone	MTT reduction	30 and 100 μg mL−1	Luo and Zhang, 2022 [66]
60% EtOH extract of seed cakes of Camellia japonica	HFDPCs	10 μg mL−1 dihydrotestosterone (DHT)	MTT reduction	10 and 20 μg mL−1	Ma et al., 2022 [67]
50% EtOH extract of fruits of Terminalia bellirica	HFDPCs	100 μM testosterone	3-(4,5-Dimethyl thiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2- (4-sulpho phenyl)-2H-tetrazolium inner salt (MTS) reduction	6.25, 12.5, and 25 μg mL−1	Woo et al., 2023 [68]

* Concentrations at which the plant extract enhanced cell viability compared to the model treated with a hormone.

In many studies, cell viability or proliferation was measured using colorimetric assays based on the reduction of dyes, such as 3-(4,5-dimethyl thiazol-2-yl)-2,5-diphenyl tetrazolium (MTT), 3-(4,5-dimethyl thiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulpho phenyl)-2H-tetrazolium (MTS), 2-(2-methoxy-4-nitrophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium (WST-1), 2-(2-methoxy-4-nitrophenyl)-3-(4-nitrophenyl)-5-(2,4-disulfophenyl)-2H-tetrazolium (WST-8), and 7-hydroxy-3H-phenoxazin-3-one 10-oxide (resazurin), which mainly reflect mitochondrial function. Assays based on the incorporation of [³H]-thymidine or bromodeoxyuridine (BrdU) during DNA synthesis in cells were also used to measure cell proliferation in some studies. Ki-67 nuclear protein is associated with ribosomal RNA transcription [69] and its immunostaining has been used to evaluate cell proliferation in some studies.

Table 1 and Table 2 show the effective concentrations of plant extracts that enhanced the proliferation or viability of dermal papilla cells, as reported in previous studies. These data will be helpful in roughly comparing the relative activities of various plant extracts and selecting plant extracts with high application potential. More accurate and reliable information can be obtained through studies that directly measure and compare the activities of various extracts under the same conditions.

It is interesting to observe that male hormones reduced the viability of dermal papilla cells and that several plant extracts restored cell viability [66,67,68]. The camellia (Camellia japonica) extract promoted cell proliferation and alleviated the decline in cell viability caused by androgenic hormones [61,67].

3.2. Effects of Plant Extracts on Hair Follicles Ex Vivo

In several previous studies, the effects of various plant extracts on hair growth, hair cycle, and proliferation of the associated cells were evaluated in experiments ex vivo using hair follicles obtained from human or animal donors, as summarized in Table 3.

Table 3.

Effects of plant extracts on hair follicles ex vivo.

Plant Extracts	Hair Follicles	Hair Growth	Hair Cycle	Cell Proliferation	Literature
Extract of red ginseng (Panax ginseng)	Human hair follicles			The extract (100 mg mL−1) recovered the number of Ki-67-positive hair matrix keratinocytes reduced by DHT.	Park et al., 2015 [43]
Water extract from oriental melon (Cucumis melo) leaves	Human hair follicles	The extract (100 μg mL−1) enhanced the elongation of hair (entire hair length).	The extract (100 μg mL−1) extended the anagen-phase duration.	The extract (100 μg mL−1) increased Ki-67-positive hair bulb keratinocytes.	Pi et al., 2016 [70]
Extract of Orthosiphon stamineus	Human hair follicles	The extract (500 μg mL−1) enhanced the elongation of hair.	The extract (500 μg mL−1) extended the anagen-phase duration.		Somsukskul et al., 2017 [47]
n-Butanol (BuOH) fraction of Perilla frutescens extract	C57BL/6 mice vibrissa hair follicles	The BuOH fraction (2.5 μg mL−1) enhanced hair shaft growth.			Li et al., 2018 [71]
50% aqueous EtOH extract of Houttuynia cordata	Human hair follicles		The extract (20 μg mL−1) extended the anagen-phase duration.		Kim et al., 2019 [49]
Extract of Polygonum multiflorum	Human hair follicles		The extract (20 or 50 μg mL−1) extended the anagen-phase duration.		Shin et al., 2020 [51]
Extract of Brassica oleracea	Male C57BL/6 mice hair follicles (whisker pads)	The extract (10 μg mL−1) recovered the elongation of the hair shaft suppressed by testosterone.			Luo and Zhang, 2022 [66]
Extract of watercress (Nasturtium officinale)	Human hair follicles	The extract (10 mg mL−1) enhanced the elongation of hair.			Hashimoto et al., 2022 [72]
Extract of Panax ginseng	Human hair follicles	The extract (100 μg mL−1) enhanced the elongation of the hair shaft.			Iwabuchi et al., 2024 [63]

Extracts from various plants, such as Cucumis melo, Orthosiphon stamineus, and Panax ginseng, promoted hair shaft growth in organ-cultured hair follicles [47,63,70]. The extract from Cucumis melo promoted the proliferation of keratinocytes in the hair bulb and matrix constituting the hair follicles [70]. Additionally, extracts from some plants, such as Cucumis melo, Houttuynia cordata, and Polygonum multiflorum, prolonged the anagen phase of the hair cycle [49,51,70]. Brassica oleracea and Panax ginseng extracts restored hair shaft growth and proliferation of constituent cells in hair follicles, respectively, which were suppressed by testosterone or DHT [43,66]. The ex vivo experimental results suggest the therapeutic potential of these plant extracts to improve hair growth.

3.3. Effects of Plant Extracts on Hair Growth in Animal Models In Vivo

Table 4 summarizes the effects of various plant extracts on hair growth in animal models. The test substance, animal model, vehicle or formula of the test substance, route and period of administration, measurement items, and comparison data between groups are shown. The list includes the extracts of marine plants, such as Eucheuma cottonii [73] and Sargassum fusiforme [74].

Table 4.

Effects of plant extracts on hair growth in animal models.

Plant Extracts	Animal Models	Vehicle or Formula	Treatments	Hair Growth	Hair Cycle	Literature
Acetone extract of Boehmeria nipononivea	5-week-old male C57BL/6 mice; dorsal hair shaving and applying a depilatory agent	EtOH	Topical application; 20 days	Vehicle control < 2% extract		Shimizu et al., 2000 [75]
MeOH extract of dried roots of Sophora flavescens	7-week-old female C57BL/6 mice; dorsal hair shaving	50% EtOH	Topical application; 30 days	Vehicle control < 1% extract	↑(telogen to anagen)	Roh et al., 2002 [76]
EtOH extract of roots of Asiasarum heterotropoides (or Asiasarum sieboldi)	7-week-old female C57BL/6 mice; dorsal hair shaving	40% EtOH	Topical application; 30 days	Vehicle control < 1% extract		Rho et al., 2005 [38]
	7-week-old female C3H mice; dorsal hair shaving	40% EtOH	Topical application; 45 days	Vehicle control < 1% extract
70% EtOH extract of Erica multiflora	7-week-old male C3H/He mice; dorsal hair shaving	Phosphate-buffered saline (PBS)	Subcutaneous injection; 3 weeks	Vehicle control ≤ 0.05% extract	↑(telogen to anagen)	Kawano et al., 2009 [39]
MeOH extract of Eclipta alba	62-day-old C57BL/6 mice; dorsal hair shaving	50% propylene glycol (PG), 30% EtOH, and 20% water	Topical application; 10 days	Number of hair follicles; vehicle control < 1.6 mg extract < 3.2 mg extract	↑(telogen to anagen)	Datta et al., 2009 [77]
Extract of tobacco (Nicotiana tabacum) leaves microbially biotransformed in cow urine	Male albino Wister rats; dorsal hair shaving and applying a hair remover	Lotion	Topical application; 30 days	Vehicle control ≤ 10% extract ≤ 20% extract ≤ 30% extract ≅ 2% minoxidil		Murkute et al., 2010 [78]
Hot water extract of Polygonum multiflorum fermented with Lactobacillus sp.	6-week-old C57BL6/N mice; dorsal hair shaving	Water containing Lactobacillus sp.	Topical application; 4 weeks	Vehicle control < 4.7 mg extract	↑(telogen to anagen)	Park et al., 2011 [79]
EtOH and aqueous extracts of Eucheuma cottonii	10–12-week-old male Sprague–Dawley rats; dorsal hair shaving	Water	Oral administration; 15 days	Vehicle control < aqueous extract < honey < EtOH extract (100 mg kg−1)		Fard et al., 2011 [73]
Extract of Aconiti Ciliare tubers	7-week-old male C57BL/6 mice; dorsal hair shaving	50% EtOH, 30% water, and 20% PG	Topical application; 35 days	Vehicle control < 2% minoxidil < 1% extract	↑(telogen to anagen)	Park et al., 2012 [40]
Extract of Glycyrrhiza Glabra	Female Wistar albino rats; dorsal hair shaving and applying a depilatory cream	Paraffin oil	Topical application; 30 days	Vehicle control < 2% minoxidil < 2% extract	↑(telogen to anagen)	Upadhyay et al., 2012 [80]
Water extract of Trichosanthes cucumerina leaves	Wistar albino rats; dorsal hair shaving and applying a depilatory cream	Water	Topical application; 30 days	Vehicle control < 0.03% extract ≤ 2% minoxidil		Sandhya et al., 2012 [81]
Extract of Chinese black tea (Camellia sinensis or Camellia taliensis) fermented with Aspergillus sp.	6-week-old male C3H/He mice; dorsal hair shaving	50% PG, 30% EtOH, and 20% water	Topical application; 2 weeks	Vehicle control ≅ 0.05% capsaicin < 3.5% extract < 0.05% capsaicin plus 3.5% extract		Hou et al., 2013 [82]
Hot water extract of Thuja orientalis	6-week-old male C57BL/6N mice; dorsal hair shaving	48.25% PG, 1.75% dimethyl sulfoxide (DMSO), and 50% water	Topical application; 21 days	Vehicle control < 1% minoxidil ≤ 30% extract	↑(telogen to anagen)	Zhang et al., 2013 [83]
Extract from leaves of Rosmarinus officinalis	7-week-old male C57BL/6NCrSlc mice; dorsal hair shaving and topical application of testosterone	80% EtOH	Topical application; 30 days	Testosterone model < model with 2% extract ≤ control without testosterone		Murata et al., 2013 [84]
	7-week-old male C3H/He mice; dorsal hair shaving	80% EtOH	Topical application; 30 days	Vehicle control < 2% extract ≤ 1% minoxidil
Extract of tomato (Lycopersicon esculentum)	6-week-old C57BL/6 mice; dorsal hair shaving	10% EtOH	Topical application; 4 weeks	Vehicle control ≅ 3% ethyl acetate extract) < 3% supercritical CO2 extract < 3% lycopene-enriched extract ≤ 3% minoxidil	↑(telogen to anagen)	Choi et al., 2013 [85]
Supercritical CO2 extract from rice (Oryza sativa) brans	6-week-old female C57BL/6 mice; dorsal hair shaving	10% EtOH	Topical application; 4 weeks	Vehicle control < 3% minoxidil ≅ 3% extract	↑(telogen to anagen)	Choi et al., 2014 [86]
EtOH extract from florets of Carthamus tinctorius	6-week-old female C57BL/6 mice; dorsal hair shaving	50% PG, 20% EtOH, and 30% water	Topical application; 15 days	Non-treated ≅ vehicle control ≤ 0.05 mg mL−1 extract ≤ 0.1 mg mL−1 minoxidil ≅ 0.1 mg mL−1 extract < 0.5 mg mL−1 extract	↑(telogen to anagen)	Junlatat and Sripanidkulchai, 2014 [41]
70% EtOH extract of Chrysanthemum zawadskii	8-week-old female C57BL/6 mice; dorsal hair shaving and applying a depilatory cream	70% EtOH	Topical application; 30 days	Vehicle control < 1.6 g kg−1 BuOH fraction < 0.6 g kg −1 water fraction	↑(telogen to anagen)	Li et al., 2014 [87]
Extract of Platycarya strobilacea	6-week-old male C57BL/6 mice; dorsal hair shaving	DMSO	Topical application; 3 weeks	Vehicle control ≅ 0.1 % extract ≅ 5% minoxidil	↑(telogen to anagen)	Kim et al., 2014 [42]
Extract of Hibiscus syriacus leaves	21-day-old albino rats; dorsal hair shaving and applying a depilatory cream	Liquid paraffin	Topical application; 30 days	Vehicle control < 10% extract	↑(telogen to anagen)	Punasiya et al., 2014 [88]
EtOH extract of Stachytarpheta jamaicensis leaves	Male Sprague–Dawley rats; dorsal hair shaving	Solution	Topical application; 30 days	Vehicle control < 2% extract ≤ 2% minoxidil		Rozianoor et al., 2014 [89]
Extract of red ginseng (Panax ginseng)	7-week-old C57BL/6 mice; dorsal hair shaving	Normal saline	Subcutaneous injection; 7 weeks	Vehicle control < 3% extract ≅ 0.5% minoxidil (topical)	↑(telogen to anagen)	Park et al., 2015 [43]
MeOH extracts of Chrysanthemum zawadskii (CZ) and Polygonum multiflorum (PM)	7-week-old male athymic BALB/c nude mice	67% PG, 30% EtOH, and 3% DMSO	Topical application; 40 days	Vehicle control ≅ 10 mg PM extract per mouse < 10 mg CZ extract per mouse ≅ 2% minoxidil	↑(telogen to anagen)	Begum et al., 2015 [90]
Hot water extract of herbal mixture: Acorus calamus, Morus alba, Glycyrrhiza uralensis, Pinus densiflora, Sophora angustifolia, Ligusticum chuanxiong, and Angelica gigas	7-week-old male C57BL/6 mice; dorsal hair shaving and applying a depilatory cream	Ointment base	Topical application; 18 days	Vehicle control < 5% minoxidil ≤ extract-containing ointment	↑(telogen to anagen)	Park et al., 2015 [91]
Extract of Rumex japonicus roots	7-week-old C57BL/6 mice; dorsal hair shaving	60% MeOH and 40% PBS	Topical application; 25 days	Vehicle control ≤ 0.4% extract ≤ 0.8% extract < 5% minoxidil	↑(telogen to anagen)	Lee et al., 2016 [44]
Water extract of oriental melon (Cucumis melo) leaves	7-week-old female C57BL/6 mice; dorsal hair shaving	Dulbecco’s phosphate-buffered saline	Topical application; 28 days	Vehicle control < 0.3% extract ≅ 5% minoxidil		Pi et al., 2016 [70]
90% EtOH extract of Eclipta alba leaves	Wistar albino rats; dorsal hair shaving and applying a depilatory cream	Water	Topical application; 30 days	Vehicle control < 10% extract ≤ 2% minoxidil		Mondal et al., 2016 [92]
DA-5512 formula (EtOH extract of herbal mixture: Thea sinensis, Emblica officinalis, Pinus densiflora, Pueraria thunbergiana, Tribulus terrestris, and Zingiber officinale)	8-week-old male C57BL/6 mice; dorsal hair shaving and applying a depilatory cream	30% EtOH	Topical application; 14 days	Vehicle control (30% EtOH) < 1% DA-5512 < 3% minoxidil ≅ 5% DA-5512	↑(telogen to anagen)	Yu et al., 2017 [45]
MeOH extract of Geranium sibiricum	6-week-old male C57BL/6 mice; dorsal hair shaving	1% DMSO	Topical application; 3 weeks	Vehicle control ≅ 0.1% extract ≅ 5% minoxidil	↑(telogen to anagen)	Boisvert et al., 2017 [46]
Extract of Trigonella foenum-graecum leaves	Male albino mice; dorsal hair shaving and applying a depilatory cream	65% water, 25% EtOH, and 10% butylene glycol	Topical application; 21 days	Vehicle control < 5% minoxidil ≤ 10% extract		Imtiaz et al., 2017 [93]
Water extract of Cinnamomum osmophloeum	8-week-old male C57BL/6 mice; dorsal hair shaving and applying a calcium thioglycolate solution	Water	Topical spraying; 30 days	Vehicle control < 20% extract ≤ 1% extract ≤ 0.5 mM minoxidil	↑(telogen to anagen)	Wen et al., 2018 [48]
BuOH fraction of Perilla frutescens extract	8-week-old C57BL/6 mice; dorsal hair removal by applying a depilatory cream	67% PG, 30% EtOH, and 3% DMSO	Topical application; 25 days	Vehicle control < 2.5% BuOH fraction ≅ 2.5% minoxidil	↑(telogen to anagen)	Li et al., 2018 [71]
	7-week-old male C57BL/6NCrSlc mice; dorsal hair removal and topical application of testosterone or DHT	70% EtOH	Topical application; 15 days	DHT model < testosterone model < DHT with 2 mg BuOH fraction ≤ testosterone with 2 mg BuOH fraction < control without hormones	↑(telogen to anagen)
Extract of Serenoa repens	6–8-week-old male C57BL/6 mice; dorsal hair shaving and applying a depilatory cream	DMSO	Oral administration; 5 weeks	DHT model < model with 50% extract < model with 0.01% finasteride		Zhu et al., 2018 [94]
Extract of blackcurrant (Ribes nigrum)	12-week-old ovariectomized female Sprague–Dawley rats	AIN-93M diet	Feeding a diet containing 3% extract; 3 months	Number of hair shafts per follicular unit; ovariectomy control < ovariectomy plus 3% extract ≅ sham control without ovariectomy		Nanashima and Horie, 2019 [95]
60% EtOH extract of Vernonia anthelmintica seeds	5–6-week-old male C57BL/6 mice; dorsal hair shaving	0.5% sodium carboxymethylcellulose	Oral administration; 23 days	Chronic restraint stress model < model with 5% minoxidil ≅ model with extract (80 mg kg−1)		Wang et al., 2019 [96]
70% EtOH extract of Camellia sinensis (CS) leaves and Hibiscus tilliaceus (HT) leaves	7–8-week-old male Sprague–Dawley rats; dorsal hair shaving and applying a depilatory cream	Microemulsion	Topical application; 21 days	Vehicle control < 2.5% minoxidil ≤ 7.5% CS extract < 7.5% HT extract		Amin et al., 2019 [97]
EtOH extract of Angelica gigas	6–7-week-old male C57/BL6 mice; dorsal hair shaving	Water	Topical application; 17 days	Vehicle control < 0.15% decursin ≅ 2% extract		Lee et al., 2020 [98]
MeOH extract of Salvia plebeian	6-week-old male C57BL/6 mice; dorsal hair shaving	DMSO	Topical application; 21 days	Vehicle control < 0.1% extract ≅ 3% minoxidil	↑(telogen to anagen)	Jin et al., 2020 [52]
70% EtOH extract of Platycladus orientalis leaves	6-week-old male C57BL/6 mice; dorsal hair shaving	Water	Topical application; 17 days	Vehicle control < 3% extract plus 1% α-terpineol	↑(telogen to anagen)	Ahn et al., 2020 [99]
The extract of Hibiscus rosa-sinensis	Sprague–Dawley rats; dorsal hair shaving and applying a depilatory cream	Liquid paraffin	Topical application; 42 days	Vehicle control < 1% extract		Rose et al., 2020 [100]
96% EtOH extract of Hibiscus rosa-sinensis leaves	Wistar albino rats; dorsal hair shaving	Liquid paraffin	Topical application; 25 days	Vehicle control < 2.5% extract < 5% extract < 10% extract		Putra et al., 2020 [101]
EtOH extract of Blumea eriantha	Male and female Swiss albino mice; dorsal hair shaving	Ag or Fe nanoparticles in 95% EtOH	Topical application; 30 days	Vehicle control < 2% or 5% Fe nanoparticles ≤ 2% or 5% Ag nanoparticles ≤ 2% minoxidil	↑(telogen to anagen)	Chavan et al., 2021 [102]
n-Hexane fraction of the MeOH extract of Leea indica leaves	Male and female Swiss albino mice; dorsal hair shaving and applying a surgical hair removal cream	1% Tween 80 in water	Topical application; 21 days	Vehicle control ≤ 5% minoxidil (100 μL) ≤ 1% extract (10 μL)		Sakib et al., 2021 [103]
EtOH and water extracts of Punica granatum	Male and female Swiss Albino mice; dorsal hair shaving	95% EtOH	Topical application; 30 days	Vehicle control < 2% minoxidil ≤ 3% extract	↑(telogen to anagen)	Bhinge et al., 2021 [104]
Extract of Phyllanthus niruri leaves, Zingiber officinale rhizomes, and Croton tiglium seeds	6–8-month-old male Wistar rats; dorsal hair shaving	80% EtOH, 10% PG, and 10% water	Topical application; 21 days	Vehicle control < 2% finasteride < 2% extract	↑(telogen to anagen)	Madhunithya et al., 2021 [105]
50% MeOH extract of lotus (Nelumbo nucifera) seeds	4-week-old male C57BL/6 mice; dorsal hair shaving	DMSO	Oral administration; 3 weeks	Vehicle control < 3% minoxidil < 0.1% extract	↑(telogen to anagen)	Park et al., 2021 [55]
96% EtOH extract of green tea (Camellia sinensis) leaves and celery (Apium gravelens) leaves	Guinea pigs; dorsal hair shaving	Tonic	Topical application; 28 days	Vehicle control < hair tonic containing 2.5% green tea extract and 7.5% celery extract		Nursiyah et al., 2021 [106]
Extract of mangkokan (Nothopanax scutellarium) leaves	4–5-month-old male New Zealand rabbits; dorsal hair shaving	Lotion	Topical application; 4 weeks	Vehicle control < 2% minoxidil < 10% extract		Rahmi et al., 2021 [107]
Extract of Pinus thunbergii barks	7-week-old male C57BL/6 mice; dorsal hair shaving	Water	Topical application; 17 days	Vehicle control < 1% minoxidil (100 μL) < 2% extract ≅ 4% extract		Her et al., 2022 [108]
Extract of centipedegrass (Eremochloa ophiuroides)	6-week-old female C57BL/6 mice; dorsal hair shaving	50% glycerol, 25% EtOH, and 25% water	Topical application; 14 days	Vehicle control < 1% extract < 5% minoxidil	↑(telogen to anagen)	Ramadhani et al., 2022 [56]
EtOH extract of Blumea eriantha	Male and female albino mice; dorsal hair shaving	95% EtOH	Topical application; 30 days	Control (normal saline) < 1% extract ≤ 1% minoxidil ≤ 3% extract	↑(telogen to anagen)	Bhinge et al., 2022 [109]
60% EtOH extract of camellia (Camellia japonica) seed cakes	7-week-old male C57BL/6J mice; dorsal shaving and applying 6% Na2S solution	Water	Topical application; 21 days	Vehicle control < 10% extract < 5% minoxidil		Wang et al., 2022 [58]
Hot water extract of Lycopus lucidus	Female 7-week-old male C57BL/6 mice; dorsal hair shaving	Diet	Oral feeding; 5 weeks	Control diet < diet supplemented with 0.01% extract		Lee et al., 2022 [59]
Hot water extract of mango (Mangifera Indica) leaves	8-week-old male C57BL/6J mice; dorsal hair shaving and applying a depilatory cream	82.5% water, 12.5% EtOH, and 0.05% jojoba oil	Topical application; 11 days	Vehicle control < 1% extract ≤ 0.3% minoxidil		Jung et al., 2022 [110]
96% EtOH extract of terentang (Campnosperma brevipetiolatum) stem barks	Male rabbits; dorsal hair shaving	Water	Topical application; 21 days	Vehicle control < 0.5% extract < 1% extract < 5% extract ≤ 5% minoxidil		Gunawan et al., 2022 [111]
EtOH extract of sea hibiscus (Hibiscus tileaceus) leaves	Male guinea pigs; dorsal hair shaving	Tonic	Topical application; 3 weeks	Vehicle control < 30% extract ≤ 2% minoxidil		Leny et al., 2022 [112]
Cold vacuum extract of Notocactus ottonis	8-week-old male C57BL/6 mice; dorsal hair shaving	50% PG, 30% EtOH, and 20% water	Topical application; 27 days	Vehicle control < 10% extract ≤ 5% minoxidil		Shibato et al., 2023 [113]
EtOH extract of Terminalia bellirica fruits	7-week-old male C57BL/6 mice; dorsal hair shaving, applying a depilatory cream, and subcutaneous injection of testosterone	Water	Oral administration; 14 days	Testosterone model ≅ model with 2 mg kg−1 finasteride < model with 20 mg kg−1 extract ≅ model with 100 mg kg−1 extract < control without testosterone		Woo et al., 2023 [68]
50% EtOH extract of Cudrania tricuspidata and Sargassum fusiforme	7-week-old female C57BL/6 mice; dorsal hair shaving and applying a depilatory cream	Water	Oral administration; 21 days	Vehicle control < 50 mg kg−1 extract < 60 μg kg−1 minoxidil		Rajan et al., 2023 [74]
			Topical application; 21 days	Vehicle control < 250 mg kg−1 minoxidil < 50 mg kg−1 extract
75% EtOH extract of Carica papaya leaves	Sprague–Dawley rats	Ointment base	Topical application; 30 days	Vehicle control < 2% minoxidil < 5% extract		Dangi et al., 2023 [114]
96% EtOH extract of Capsicum frutescens leaves	Male rabbits; dorsal hair shaving and applying a depilatory cream	Tonic	Topical application; 21 days	Vehicle control < 20% extract ≤ 2% minoxidil		Tendri Adjeng et al., 2023 [115]
70% EtOH extract of Hibiscus rosa-sinensis leaves	White rabbits; dorsal hair shaving	Cream	Topical application; 21 days	Vehicle control < 20% extract ≤ a minoxidil product		Lailiyah, 2023 [116]
Extract of Gynostemma pentaphyllum leaves	4-week-old male C57BL/6 mice; dorsal hair shaving	Water	Topical application; 28 days	Vehicle control ≅ 0.5% extract ≤ 2% minoxidil < 1% extract ≅ 2% extract	↑(telogen to anagen)	Liu et al., 2024 [64]

<, ≤, and ≅ represent big differences, little differences, and no difference, respectively. ↑ represents increases.

Mice and rats have often been used as animal models to evaluate hair growth whereas rabbits or guinea pigs have rarely been used [107,111,112,115,116]. Many studies have used C57BL/6 mice, which have the advantage of being easy to observe with the naked eye due to their dark fur color. Some studies have used different substrains of C57BL/6 mice, such as C57BL/6N [79], C57BL/6NCrSlc [84], and C57BL/6J [58], although this does not mean that a particular substrain is more suitable for hair growth studies. Animals of different colors also have been used in hair growth research without major problems. Previous studies have used C3H mice with brown fur [38,39,82,84], albino mice with white fur [103,109], and albino Wistar rats or Sprague–Dawley rats with white fur [78,95]. These animal models commonly require hair removal in hair growth research, but athymic BALB/c nude mice with natural hair growth defects do not require hair removal, providing an alternative model [90].

When mice are about 7 weeks old, most of the hair on their skin is synchronized in the telogen phase [117], so removing hair from mice at this age can help reduce inter-individual variation in the hair cycle. Hair removal methods include shaving with clippers or applying a kind of hair-removing solution or product followed by wiping to remove [58]. Some previous studies have developed animal models that mimic hormonal hair loss conditions by topical application or subcutaneous injection of testosterone in mice [68,84] or that mimic menopause conditions by ovariectomy in female Sprague–Dawley rats [95]. The chronic restraint stress model has also been used in hair research [96].

The plant extract has been applied topically in many studies, but it has also been administered via subcutaneous injection [39,42] or oral feeding [68,95]. When applying a test substance topically, it is necessary to optimize the vehicle by considering the solubility of the drug, skin irritation, and skin absorption. Typically, propylene glycol, ethanol (EtOH), glycerin, and water have been used alone or in combination as a vehicle. Test substances were administered once a day in most cases, yet there were also cases where they were administered twice a day or once every few days. Many studies used minoxidil as the positive control, while finasteride has also been used [68].

The entire period of test substance administration after hair removal varied depending on the study, from 2 weeks [68,82] to 7 weeks [43], and the measurement of hair growth often continued until the hairs in the hair removal area had grown to the length of the surrounding area. However, in a study that counted the number of hair follicles per unit skin area or hair shafts per follicle, the test substance was administered for 10 days [77] or 3 months [95]. Overall, the test period can vary depending on the test purpose and measurement items.

Various plant extracts promoted hair growth or alleviated the delay in hair growth caused by androgen hormones in animal models. Some plant extracts promoted telogen-to-anagen conversion in the hair cycle. Therefore, many of these extracts have potential applications in preventing and treating human alopecia.

It is difficult to compare the hair growth-promoting efficacy of plant extracts evaluated separately in different studies. However, suppose individual studies include negative or positive controls or multiple test groups administered various doses of the test substance. In that case, it is possible to interpret the reliability of the experimental results and the relative efficacy of the test substance. It is also necessary to conduct follow-up studies by prioritizing plant extracts that showed relatively strong efficacy in reliable studies compared to positive controls.

3.4. Clinical Studies on the Hair Growth Promotion or Suppression Efficacy of Plant Extracts

In clinical trials examining hair loss and hair growth, a combination of instrumental analysis and visual evaluation is used [118,119]. Table 5 summarizes several double-blind, randomized, placebo-controlled trials on human subjects that evaluated the efficacy of a solution, tonic, lotion, cream, or shampoo containing different plant extracts promoting or suppressing hair growth.

Table 5.

Effects of plant extracts on hair growth in clinical trials.

Study Format and Subjects	Plant Extracts	Formulas	Treatments	Outcomes	Literature
Double-blind, randomized, placebo-controlled trial on 44 subjects with male or female pattern alopecia (aged 18 to 60 years)	Extract from Thuja occidentalis seeds	A shampoo containing 0.17% extract	Topical application; twice daily for 16 weeks	The shampoo increased total hair count compared to the placebo group.	Baek et al., 2011 [118]
Double-blind, randomized, placebo-controlled trial on 50 women subjects (aged 18 years or over)	Extract from barks of Stryphnodendron adstringens	A cream containing 6.0% extract	Topical application; twice daily for 6 months	The cream reduced terminal hair growth.	Vicente et al., 2009 [120]
Double-blind, randomized, controlled single-center trial on 50 alopecia patients including 22 women and 28 men (aged 18 years or over, 42.0 ± 11.37 years)	Supercritical CO2 extract of brans of Oryza sativa	A tonic containing 0.5% extract	Topical application; twice a day for 16 weeks	The tonic increased hair diameter and the density of hairs per skin area in male subjects.	Choi et al., 2015 [121]
Double-blind, placebo-controlled, randomized clinical trial on 23 subjects with mild alopecia (aged 20 to 60 years)	DA-5512 formula (EtOH extract of herbal mixture: Thea sinensis, Emblica officinalis, Pinus densiflora, Pueraria thunbergiana, Tribulus terrestris, and Zingiber officinale)	A solution	Topical application on the shaved head skin twice daily for 16 weeks	Hair density, hair shaft diameter, and hair growth rate; placebo (n = 8) < 5% DA-5512 (n = 8) ≅ 3% minoxidil (n = 7).	Yu et al., 2017 [45]
Double-blind, randomized, placebo-controlled study on 30 women (aged 20 to 52 years)	n-Hexane extract of Curcuma aeruginosa	A lotion containing 5% extract	Topical application; twice daily for 12 weeks	The lotion reduced the growth rates of axillary hairs.	Srivilai et al., 2018 [122]
Randomized, placebo-controlled, single-blind, clinical study on 120 subjects with androgenetic alopecia and telogen effluvium (aged 20 to 55 years, 36.9 ± 9.8 years)	A mixture of herbal extracts: Urtica urens, Urtica dioica, Matricaria chamomilla, Achillea millefolium, Ceratonia siliqua, and Equisetum arvense.	A shampoo and a solution	Topical application of active shampoo (3 to 4 min), 3 times a week, and/or active solution (4 to 6 h) daily for 6 months	Effectiveness in preventing and reducing hair loss; placebo shampoo plus placebo solution (n = 30) < active shampoo (n = 30) ≤ active solution (n = 30) ≤ active shampoo plus active solution (n = 30).	Pekmezci et al., 2018 [123]
Double-blind, randomized controlled study on 47 subjects including male and female patients with androgenic alopecia (aged 18 to 54 years)	Extracts of Inula helenium (IH) roots and Caesalpinia sappan (CS) barks	A shampoo containing 0.3% IH root extract and 0.1% CS bark extract	Topical application twice daily for 24 weeks	The treatment group (n = 23) showed a higher hair density and total hair count than the placebo group (n = 24).	Choi et al., 2019 [124]
Randomized, double-blind, placebo-controlled study on 72 patients with mild to moderate vertex balding (aged 37 to 54 years, 46.6 ± 8.5 years)	Extract of Centipeda minima	A tonic	Topical application daily for 24 weeks	The treatment group (n = 34) showed a higher hair count than the placebo group (n= 32).	Kim et al., 2020 [125]
Double-blind, randomized controlled study on 46 male subjects (aged 20 to 55 years)	Extract of watercress (Nasturtium officinale)	A lotion containing 2% extract	Topical application twice daily for 6 months	The treatment group (n = 23) showed a higher hair thickness and hair density than the placebo group (n = 23).	Hashimoto et al., 2022 [72]
Randomized, double-blind, placebo-controlled clinical study on 50 subjects including 7 males and 43 females (aged 20 years or over)	Water extract of banana (Musa paradisiaca) flowers	A sachet containing 16% extract	Oral administration daily for 12 weeks	The sachet uptake increased the hair root diameter and reduced hair loss and scalp redness compared to the placebo group.	Liang et al., 2023 [62]
Randomized, double-blind, placebo-controlled clinical study on 88 subjects including 34 males and 54 females (aged 19 to 60 years, 38.52 ± 7.98 years)	Extract of persimmon (Diospyros kaki) leaves, green tea (Camellia sinensis) leaves, and sophora (Sophora Japonica) fruits	A tablet containing 30% extract	Oral administration twice daily for 24 weeks	The treatment group (n = 44) showed a higher hair density and hair diameter compared with the placebo group (n = 44).	Ham et al., 2023 [126]
Randomized, double-blind, placebo-controlled clinical study on 42 subjects including male and female patients with androgenetic alopecia (aged 18 to 54 years, 46.096 ± 6.60 years)	EtOH extract from flowers of Silybum marianum	A shampoo containing 0.05% extract	Topical application; once a day for 24 weeks	The shampoo increased the hair density and total hair count compared with those in the placebo group.	You et al., 2024 [65]

<, ≤, and ≅ represent big differences, little differences, and no difference, respectively.

Topical application of the products containing Stryphnodendron adstringens bark extract and Curcuma aeruginosa extract reduced the growth of terminal hairs and axillary hairs, respectively, in women [120,122]. In contrast, topical application of the products containing the extract of Thuja occidentalis, Oryza sativa, Curcuma aeruginosa, Centipeda minima, or Silybum marianum increased hair density in all human subjects [65,72,118,121,124,125]. Topical application of a product containing herbal mixture extracts also promoted hair growth and reduced hair loss in human subjects [45,123]. These results suggest that plant extracts may have different effects of enhancing or inhibiting hair growth in various body parts depending on their types, contents, and formulas. Therefore, in developing hair care products using plant extracts, multiple factors must be considered to realize the purpose of use. Some plant extracts have been reported to help increase hair density when taken orally [62,126], so research on the route of administration is also needed.

4. Phytochemical Components and Active Compounds in Plant Extracts

As shown in Table 6, the main phytochemical components and active compounds of plant extracts have been presented in several studies. In this chapter, we will examine these compounds by dividing them into phenolic compounds, terpenes and terpenoids, sulfur-containing compounds, fatty acids, and other compounds.

Table 6.

Main phytochemical components and active compounds in plant extracts.

Plant Extracts	Main Phytochemical Components and Active Compounds	Literature
Acetone extract of Boehmeria nipononivea	α-Linolenic acid, linoleic acid, palmitic acid, elaidic acid, oleic acid, and stearic acid	Shimizu et al., 2000 [75]
MeOH extract of Eclipta alba	Coumestans (e.g., Wedelolactone), flavonoids, triterpenoid glycosides, triterpenoid saponins, and thiophene derivatives	Datta et al., 2009 [77]
Hot water extract of Thuja orientalis	Kaempferol and isoquercetin	Zhang et al., 2013 [83]
Extract of Rosmarinus officinalis leaves	12-Methoxycarnosic acid (a diterpenoid)	Murata et al., 2013 [84]
Extract of tomato (Lycopersicon esculentum)	all-trans-Lycopene and 5-cis-lycopene	Choi et al., 2013 [85]
Supercritical CO2 extract of rice (Oryza sativa) brans	Linoleic acid, policosanol, γ-oryzanol, and γ-tocotrienol	Choi et al., 2014 [86]
50% EtOH extract of Carthamus tinctorius florets	Hydroxysafflor yellow A (a chalcone glycoside)	Junlatat and Sripanidkulchai, 2014 [41]
EtOH extract of Stachytarpheta jamaicensis leaves	Genipin, phytol, α-linolenic acid, palmitic acid, and tridecanoic acid	Rozianoor et al., 2014 [89]
Extract of red ginseng (Panax ginseng)	Ginsenoside Rb1 and ginsenoside Rg3	Park et al., 2015 [43]
Hot water extract of an herbal mixture: Acorus calamus, Morus alba, Glycyrrhiza uralensis, Pinus densiflora, Sophora angustifolia, Ligusticum chuanxiong, and Angelica giga	Asarone and p-coumaric acid	Park et al., 2015 [91]
MeOH extract of Geranium sibiricum	Corilagin and gallic acid	Boisvert et al., 2017 [46]
Water extract of Cinnamomum osmophloeum	Cinnamic aldehyde and cinnamic acid	Wen et al., 2018 [48]
BuOH fraction of Perilla frutescens extract	Rosmarinic acid	Li et al., 2018 [71]
n-Hexane extract of Curcuma aeruginosa	Germacrone and other sesquiterpenoids (e.g., dehydrocurdione, zederone, cucumenone, curcumenol, and furanodiene)	Srivilai et al., 2018 [122]
A mixture of herbal extracts: Urtica urens, Urtica dioica, Matricaria chamomilla, Achillea millefolium, Ceratonia siliqua, and Equisetum arvense	Kaempferol, quercetin, and myricetin	Pekmezci et al., 2018 [123]
Extracts of Inula helenium (IH) roots and Caesalpinia sappan (CS) barks	Costunolide (from IH) and 3-deoxysappanchalcone (from CS)	Choi et al., 2019 [124]
Extract of Centipeda minima	Brevilin A and other sesquiterpene lactones (e.g., arnicolide C, arnicolide D, and microhelenin C)	Kim et al., 2020 [125]
EtOH extract of Angelica gigas	Decursin and decursinol angelate	Lee et al., 2020 [98]
n-Hexane fraction of the MeOH extract of Leea indica leaves	Phthalic acid, palmitic acid, n-octadecane, n-eicosane, n-heptadecane, and farnesol	Sakib et al., 2021 [103]
EtOH and water extract of Punica granatum	Volatile compounds (e.g., maltol and 5-hydroxymethylfurfural)	Bhinge et al., 2021 [104]
MeOH extract of shallot (Allium ascalonicum)	Rosmarinic acid, p-coumaric acid, and quercetin	Ruksiriwanich et al., 2022 [57]
Extract of Brassica oleracea	Sulforaphane and glucoraphanin (a glucosinolate of sulforaphane)	Luo and Zhang, 2022 [66]
EtOH extract of Blumea eriantha	Dimethyl sulfone	Bhinge et al., 2022 [109]
60% EtOH extract of seed cakes of Camellia japonica	Kaempferol-3-O-[2-O-β-D-galactopyranosyl-6-O-α-L-rhamnopyranosyl]-β-D-glucopyranoside and kaempferol-3-O-[2-O-β-D-xylopyranosyl-6-O-α-L-rhamnopyranosyl]-β-D-glucopyranoside	Ma et al., 2022 [67]
Hot water extract of Lycopus lucidus	Rosmarinic acid	Lee et al., 2022 [59]
70% EtOH extract of fruit shells of Camellia japonica	Protocatechuic acid gallic acid	You et al., 2023 [61]
Extract of persimmon (Diospyros kaki) leaves, green tea (Camellia sinensis) leaves, and sophora (Sophora Japonica) fruits	Tannic acids (from persimmon), (−)-epigallocatechin-3-gallate (from green tea), and sophoricoside (from sophora)	Ham et al., 2023 [126]
Extract of Panax ginseng	Ginsenoside Rb1, ginsenoside Rg1, and ginsenoside Re	Iwabuchi et al., 2024 [63]
70% EtOH extract of flowers of Silybum marianum	Apigenin	You et al., 2024 [65]

Active compounds with experimental evidence are indicated with bold letters.

4.1. Phenolic Compounds

The chemical structures of some phenolic compounds are shown in Figure 1. The phenolic compounds include coumarins (e.g., weldelolactone, decursin, and decursinol angeleate), phenolic acids (gallic acid, protocatechuic acid, and phthalic acid), phenylpropanoids (e.g., asarone, p-coumaric acid, cinnamic acid, cinnamic aldehyde, and rosmarinic acid), flavonoids, and tannins (e.g., corilagin). The flavonoid compounds include flavonols (e.g., kaempferol, quercetin, and myricetin), flavones (e.g., apigenin), isoflavones (e.g., genistein), flavanols (e.g., (−)-epigallocatechin gallate), chalcones (e.g., 3-deoxysappanchalcone), and their glycosides (e.g., isoquercetin, sophoricoside, and hydroxysafflor yellow A).

Figure 1.

Chemical structures of phenolic compounds.

Extract of Eclipta alba contains coumestans including wedelolactone as the main phytochemical components alongside flavonoids, triterpenoid glycosides, triterpenoid saponins, and thiophene derivatives [77]. Extract from Angelica gigas contains coumarin compounds, such as decursin and decursinol angelate [98]. The hair growth-promoting effect of decursin was confirmed in male C57/BL6 mice [98]. Decursin reduced the expression of inflammatory cytokines, such as tumor necrosis factor α (TNF-α) and interleukin (IL)-1β, while increasing the expression of anti-inflammatory cytokines IL-4 and IL-13, and an inflammation mediator, high-mobility group box 1 (HMGB1) [98].

Extract from Thuja orientalis contains flavonoids, such as kaempferol and isoquercetin [83]. Extract from Silybum marianum contains apigenin as the main component [65]. Extracts of Diospyros kaki, Camellia sinensis, and Sophora Japonica contain tannic acids, (−)-epigallocatechin-3-gallate, and sophoricoside (an isoflavone genistein glycoside), respectively [126]. Extract of a herbal mixture (Urtica urens, Urtica dioica, Matricaria chamomilla, Achillea millefolium, Ceratonia siliqua, and Equisetum arvense) contains kaempferol, quercetin, and myricetin [123]. Extract from Camellia japonica contains gallic acid, protocatechuic acid, kaempferol-3-O-[2-O-β-D-galactopyranosyl-6-O-α-L-rhamno pyranosyl]-β-D-glucopyranoside, and kaempferol-3-O-[2-O-β-D-xylopyranosyl-6-O-α-L-rhamnopyranosyl]-β-D-glucopyranoside [61,67]. Extract from Carthamus tinctorius contains 212.00 ± 17.56 mg g⁻¹ of hydroxysafflor yellow A, a single chalcone glycoside, as the main phytochemical component [41]. Extract of Caesalpinia sappan contains 3-deoxysappanchalcone [124].

Hot water extract of a herbal mixture (Acorus calamus, Morus alba, Glycyrrhiza uralensis, Pinus densiflora, Sophora angustifolia, Ligusticum chuanxiong, and Angelica giga) contains phenylpropanoid compounds, such as asarone (from Acorus calamus) and p-coumaric acid (from Pinus densiflora), as the main components [91]. Extract of Cinnamomum osmophloeum contains cinnamic aldehyde and cinnamic acid, which are also phenylpropanoid compounds [48].

Extract of Geranium sibiricum contains gallic acid and corilagin (an ellagitannin) [46]. Extracts of Perilla frutescens and Lycopus lucidus contain rosmarinic acid as the main component [59,71], and extract of Allium ascalonicum contains rosmarinic acid, p-coumaric acid, and quercetin [57]. Rosmarinic acid was shown to attenuate cell death caused by testosterone and promote VEGF gene expression in cells [57,59,71]. Of the various phytochemical components in Leea indica extract, phthalic acid and other several compounds have been proposed as potential inhibitors of prostaglandin D₂ synthase based on in silico ligand binding analysis [103].

4.2. Terpenes and Terpenoids

The chemical structures of some terpenes and terpenoids are shown in Figure 2. Terpenes are composed of isoprene (C₅H₈) units and are classified into monoterpenes (C₁₀H₁₆), sesquiterpenes (C₁₅H₂₄), diterpenes (C₂₀H₃₂), triterpenes (C₃₀H₄₈), and tetraterpenes (C₄₀H₆₄). Terpenoids are structurally similar to terpenes but have functional groups with heteroatoms such as oxygen.

Figure 2.

Chemical structures of terpenes and terpenoids.

From the extract of Rosmarinus officinalis, 12-methoxycarnosic acid, a diterpenoid, was isolated as an active compound and this compound enhanced the proliferation of cultured LNCaP cells [84]. Extract of Curcuma aeruginosa contains high amounts of germacrone and other volatile sesquiterpenoids, such as dehydrocurdione, zederone, cucumenone, curcumenol, and furanodiene [122]. Extract of Centipeda minima contains high amounts of brevilin A and several other sesquiterpene lactones, such as arnicolide C, arnicolide D, and microhelenin C [125]. Extract of Stachytarpheta jamaicensi contains genipin (a monoterpene iridoid compound, phytol (a hydrogenated diterpene alcohol), and fatty acids (e.g., α-linolenic acid, palmitic acid, and tridecanoic acid) [89]. Extract of Inula helenium contains costunolide, a sesquiterpene lactone [124].

Panax ginseng extracts contain unique triterpenoid saponins, such as ginsenosides Rb1, Rg1, Rg3, and Re [43,63]. Testosterone suppressed the proliferation of hair matrix keratinocytes in hair follicle explants while upregulating androgen receptors in cultured hDPCs, and all these changes were inhibited by ginsenosides Rb1 and Rg3 [43]. Ginsenosides Rb1, Rg1, and Re enhanced the proliferation of iDPCs while decreasing the mRNA level of BMP4 [63]. A purified extract of Lycopersicon esculentum contains high amounts of tetraterpene carotenoids, such as all-trans-lycopene and 5-cis-lycopene, which are the main active components associated with hair growth-promoting effects [85].

4.3. Sulfur-Containing Compounds, Fatty Acids, and Other Compounds

The chemical structures of some sulfur-containing compounds, fatty acids, and other miscellaneous compounds are shown in Figure 3.

Figure 3.

Chemical structures of sulfur-containing compounds, fatty acids, and other compounds.

Extract of Brassica oleracea contains sulforaphane and glucoraphanin (a glucosinolate of sulforaphane) [66]. These components promoted hair shaft growth in hair follicles derived from C57/BL6 mice [66]. Dimethyl sulfone has been isolated as an active compound from extract of Blumea eriantha, and the isolated compound increased the length of the hair follicle [109].

A fat-soluble extract of Boehmeria nipononivea contains large amounts of α-linolenic acid, linoleic acid, and palmitic acid [75]. When comparing the hair growth-promoting effects of various fatty acids in C57/BL6 mice, α-linolenic acid, elaidic acid, and stearic acid were more effective than others [75].

Extract of Oryza sativa brans contains various primary and secondary metabolites, such as linoleic acid, policosanol, γ-oryzanol, and γ-tocotrienol [86]. As a result of testing hair growth-promoting effects in C57/BL6 mice, linoleic acid was evaluated to be more effective than other compounds [86]. Extract of Punica granatum contains maltol, 5-hydroxymethylfurfural, and other volatile phytoconstituents [104].

5. Modulatory Targets of Plant Extracts

5.1. Antioxidant, Anti-Inflammatory, and Anti-Senescence Effects of Plant Extracts

Oxidative stress induced by external and internal factors is expressed as an increase in prooxidants, a decrease in antioxidants, and an increase in oxidative damage [127]. It acts as a causative mechanism disrupting the homeostasis of the skin, scalp, and hair [128,129]. Reactive oxygen species (ROS), which mediate oxidative stress, can cause an inflammatory response and cellular senescence, hindering hair growth and triggering hair loss [129,130]. Ultraviolet rays and air pollution have been shown to cause oxidative stress in dermal papilla cells and increase cell death [131,132]. Various types of antioxidants have been studied as a defense for scalp and hair [133,134].

As summarized in Table 7, some plant extracts scavenged free radicals in vitro [42,46,55,61,135], reduced intracellular ROS levels [61,65], or enhanced the viability of cells exposed to hydrogen peroxide (H₂O₂) [61,65] or 2,2′-azobis (2-amidinopropane) dihydrochloride (AAPH) radical [54]. Some extracts alleviated inflammatory response determined by the expression levels of inflammatory cytokines, such as tumor necrosis factor-alpha (TNF-α), interleukin (IL)-1β, and IL-6 [59,65,67,98], or cellular senescence determined by the expression level of senescence-associated β-galactosidase (SA-β-gal) [61,65,67] in cells stimulated with phorbol-12-myristate 13-acetate (PMA) plus calcium ionophore A23187 [50], H₂O₂ [59,61,65], or androgen [67]. The anti-inflammatory effects of extracts of Angelica gigas and Pinus thunbergii were shown by the reduced levels of pro-inflammatory cytokines (TNF-α and IL-1β) and increased levels of anti-inflammatory cytokines (IL-4 and IL-13) in the dorsal skin of mice [50,108]. In silico molecular docking analysis of phytochemical components of Leea indica resulted in the identification of several compounds with high ligand efficiencies towards prostaglandin D₂ synthase, implicating their potential anti-inflammatory activity [103].

Table 7.

Antioxidant, anti-inflammatory, and anti-senescence effects of plant extracts.

Plant Extract Sources	Model	Antioxidant, Anti-Inflammatory, and Anti-Senescence Effects	Literature
Platycarya strobilacea	In vitro	The extract had 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical-scavenging capacity.	Kim et al., 2014 [42]
Geranium sibiricum	In vitro	The extract had a DPPH radical-scavenging capacity.	Boisvert et al., 2017 [46]
Panax ginseng, Glycine max, Houttuynia cordata, Lycium chinense, Glycyrrhiza uralensis, Citrus unshiu, Zizyphus jujuba, Perilla frutescens, Camellia sinensis, and Cynanchum wilfordii	Mast cell-1	The extract suppressed the production of tumor necrosis factor-alpha (TNF-α) in cells stimulated with phorbol-12-myristate 13-acetate (PMA) plus calcium ionophore A23187.	Kang et al., 2019 [50]
Angelica gigas	Male C57/BL6 mice	The extract reduced pro-inflammatory cytokines, such as TNF-α and interleukin (IL)-1β, while increasing anti-inflammatory cytokines, such as IL-4 and IL-13, in the dorsal skin.	Lee et al., 2020 [98]
Leea indica	In silico	Molecular docking analysis identified some phytochemicals, such as including phthalic acid, that showed high ligand efficiencies towards prostaglandin D2 synthase.	Sakib et al., 2021 [103]
Euterpe oleracea, Olea europea, Tabebuia impetiginosa, and Coffea Arabica	HFDPCs	The extract enhanced the viability of cells exposed to 2,2’-azobis (2-amidinopropane) dihydrochloride (AAPH) radical.	Serruya and Maor, 2021 [54]
Nelumbo nucifera	In vitro	The extract had a DPPH radical-scavenging capacity.	Park et al., 2021 [55]
Pinus thunbergii	Male C57/BL6 mice	The extract reduced pro-inflammatory cytokines, such as TNF-α and IL-1β, while increasing anti-inflammatory cytokines, such as IL-4 and IL-13, in the dorsal skin.	Her et al., 2022 [108]
Camellia japonica	HFDPCs	The extract suppressed the production of IL-6 and IL-1α in cells stimulated with DHT. It also reduced the expression of senescence-associated β-galactosidase (SA-β-gal) in DHT-treated cells.	Ma et al., 2022 [67]
Lycopus lucidus	HFDPCs	The extract reduced IL-1β levels in cells exposed to hydrogen peroxide (H2O2).	Lee et al., 2022 [59]
Camellia japonica	In vitro	The extract had DPPH radical-scavenging capacity.	You et al., 2023 [61]
	HFDPCs	The extract reduced intracellular reactive oxygen species (ROS) levels and enhanced the viability of cells exposed to H2O2. It reduced SA-β-gal expression in cells exposed to H2O2.
Musa paradisiaca	HFDPCs	The extract reduced intracellular ROS levels exposed to H2O2.	Liang et al., 2023 [62]
Coffea arabica	In vitro	The extract had 2,2’-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid (ABTS) radical and DPPH radical-scavenging capacities.	Muangsanguan et al., 2023 [135]
Silybum marianum	HFDPCs	The extract reduced intracellular ROS levels and enhanced the viability of cells exposed to H2O2. It reduced the expression of SA-β-gal and IL-6 in senescent cells and young cells exposed to H2O2.	You et al., 2024 [65]

5.2. Effects of Plant Extracts on the Apoptotic Cell Death Pathway

Apoptosis is a type of programmed cell death that is executed to remove unnecessary, unhealthy, or unrecoverable cells. In its intrinsic mitochondria-dependent pathway, the ratios of proapoptotic members (e.g., BCL-2-associated X protein (BAX), Bcl-2 homologous antagonist/killer (BAK), and BCL-2 associated agonist of cell death (BAD)) to antiapoptotic members (e.g., B-cell lymphoma 2 (BCL-2), B-cell lymphoma-extra-large (BCL-xL), and myeloid cell leukemia 2 (MCL-2)) of the BCL-2 family increase [136,137]. Incorporating dimers of proapoptotic members into the mitochondrial membrane makes it leaky. Then, cytochrome C is released from the mitochondria and binds to apoptotic protease-activating factor 1 (APAF-1) in the cytoplasm to recruit caspase 9, which in turn activates caspase 3, 6, 7 (called executioner caspases), and other proteases involved in the degradation of cellular components. The extrinsic receptor-dependent apoptosis pathway is mediated by death receptors, such as tumor necrosis factor receptor 1 (TNFR-1) and FAS, and an adaptor, FAS-associated protein with death domain (FADD) [138,139]. The activated receptor and adaptor cooperatively recruit caspase 8, which in turn activates executioner caspases.

As summarized in Table 8, several studies have reported that extracts from several plants, including Panax ginseng, Houttuynia cordata, and Camellia japonica, increased the mRNA or protein level of antiapoptotic BCL-2 [44,49,51,52,67] while decreasing that of proapoptotic BAX [44,49,50,66,67] or BAD [51].

Table 8.

Effects of plant extracts on apoptosis pathway.

Plant Extract Sources	Models	BCL-2	BAX	BAD	Literature
Rumex japonicus	HFDPCs	↑(protein)	↓(protein)		Lee et al., 2016 [44]
Serenoa repens	C57BL/6 mice	↑(protein)	↓(protein)		Zhu et al., 2018 [94]
Houttuynia cordata	HFDPCs	↑(mRNA) ↑(protein)	↓(mRNA)	=(mRNA)	Kim et al., 2019 [49]
Panax ginseng, Glycine max, Houttuynia cordata, Lycium chinense, Glycyrrhiza uralensis, Citrus unshiu, Zizyphus jujuba, Perilla frutescens, Camellia sinensis, and Cynanchum wilfordii	HFDPCs		↓(mRNA) ↓(protein)		Kang et al., 2019 [50]
Polygonum multiflorum	HFDPCs	↑(mRNA)		↓(mRNA)	Shin et al., 2020 [51]
Salvia plebeia	HFDPCs	↑(protein)	=(protein)		Jin et al., 2020 [52]
Brassica oleracea	HFDPCs	=(mRNA)	↓(mRNA)		Luo and Zhang, 2022 [66]
Camellia japonica	HFDPCs	↑(mRNA) ↑(protein)	↓(mRNA)		Ma et al., 2022 [67]

↑, ↓, and = represent increases, decreases, and no changes, respectively. Abbreviations: BCL-2—B-cell lymphoma 2; BAX—BCL-2-associated X protein; BAD—BCL-2-associated agonist of cell death.

5.3. Effects of Plant Extracts on Male Hormones

Table 9 shows the effects of some plant extracts on the expression of male hormones and their receptors in cells and animals. It is recognized that an increase in male hormones is highly correlated with hair loss [140] and studies have reported the effects of plant extracts on the expression of male hormones and their receptors in cell and animal models [43,51,62,67,78]. Steroid 5α-reductase type II catalyzes the transformation of testosterone to DHT in cells, and its inhibitor can have therapeutic potential in treating male pattern hair loss [141]. Extracts of several plants and a herbal mixture have been shown to reduce the expression level of steroid 5α-reductase type II in cells [50,53,57,62,67,110,135]. Further, Sophora flavescens and Rosmarinus officinalis extracts have been shown to inhibit the catalytic activity of steroid 5α-reductase type II in vitro [61,76,84].

Table 9.

Effects of plant extracts on androgens, their receptors, and steroid 5α-reductase type II.

Plant Extract Sources	Models	Testosterone	Androgen Receptor	Steroid 5α-Reductase Type II	Literature
Sophora flavescens	In vitro			↓(activity)	Roh et al., 2002 [76]
Nicotiana tabacum	Male albino Wister rats	↓(protein)			Murkute et al., 2010 [78]
Rosmarinus officinalis	In vitro			↓(activity)	Murata et al., 2013 [84]
Panax ginseng	HFDPCs		↓(mRNA)		Park et al., 2015 [43]
Panax ginseng, Glycine max, Houttuynia cordata, Lycium chinense, Glycyrrhiza uralensis, Citrus unshiu, Zizyphus jujuba, Perilla frutescens, Camellia sinensis, and Cynanchum wilfordii	HFDPCs			↓(protein)	Kang et al., 2019 [50]
Polygonum multiflorum	HFDPCs		↓(protein)		Shin et al., 2020 [51]
Plumbago zeylanica	HFDPCs			↓(protein)	Yamada et al., 2020 [53]
Allium ascalonicum	Prostate cancer cell line Du-145			↓(mRNA)	Ruksiriwanich et al., 2022 [57]
Mangifera indica	HFDPCs			↓(mRNA)	Jung et al., 2022 [110]
Camellia japonica	HFDPCs		↓(mRNA)	↓(mRNA)	Ma et al., 2022 [67]
	In vitro			↓(activity)	You et al., 2023 [61]
Musa paradisiaca	HFDPCs		↓(mRNA)	↓(mRNA)	Liang et al., 2023 [62]
Coffea arabica	HFDPCs			↓(mRNA)	Muangsanguan et al., 2023 [135]

↓ represents decreases.

5.4. Effects of Plant Extracts on Cell Cycle

The cell cycle consists of the gap (G) 1 phase, synthesis (S) phase, G2 phase, mitosis (M) phase, and G0 phase. In the G1 phase, retinoblastoma (Rb) protein sequesters E2F transcription factors and arrests the cell cycle, yet when Rb is hyper-phosphorylated, it releases E2F and the cell cycle enters the S phase [142]. p53 induces the transcription of p21^CIP1 that inhibits CDK-mediated hyper-phosphorylation of Rb, stabilizing the Rb/E2F complex and causing cell cycle arrest [142]. p16^INK4 inhibits CDK4 activity and reduces Rb phosphorylation, suppressing cell cycle progression [143].

Table 10 shows several plant extracts that promoted the cell cycle in HFDPCs. The extracts of Erica multiflora and Camellia japonica increased the percentage of cells in the S or G2/M phase [39,58]. Houttuynia cordata and Camellia japonica extracts induced the cell cycle G1‒S phase transition by upregulating CDK4 or downregulating p16^INK4 or p53 [49,67].

Table 10.

Effects of plant extracts on cell cycle.

Plant Extract Sources	Models	CDKs	p16 INK4	p53	Cell Cycle Phase	Literature
Erica multiflora	HFDPCs				↓(G0/G1), =(S), ↑(G2/M)	Kawano et al., 2009 [39]
Houttuynia cordata	HFDPCs	=(mRNA, CDK1 and CDK2), ↑(mRNA, CDK4)	↓(protein)	=(mRNA)		Kim et al., 2019 [49]
Camellia japonica	HFDPCs			↓(mRNA)		Ma et al., 2022 [67]
	HFDPCs				↓(G0/G1), ↑(S), ↑(G2/M)	Wang et al., 2022 [58]

↑, ↓, and = represent increases, decreases, and no changes, respectively. Abbreviations: CDK—cyclin-dependent kinase; INK—inhibitors of CDK.

5.5. Effects of Plant Extracts on the Expression Levels of Growth Factors

As reported in many previous studies, various growth factors, such as insulin-like growth factor (IGF) [144], VEGF [145], hepatocyte growth factor (HGF) [146], and keratinocyte growth factor (KGF) (also called fibroblast growth factor 7, FGF-7) [147], can affect dermal papilla cell physiology or hair growth.

As summarized in Table 11, various plant extracts have been reported to affect the mRNA or protein levels of several growth factors in HFDPCs and animal models. Plant extracts promoting cell proliferation or hair growth generally increased IGF-1, VEGF, HGF, and KGF (FGF-7) levels, with some exceptions.

Table 11.

Effects of plant extracts on the mRNA and protein levels of several growth factors.

Plant Extract Sources	Models	IGF-1	VEGF	HGF	KGF (FGF-7)	Literature
Sophora flavescens	HFDPCs	↑(mRNA)	=(mRNA)	=(mRNA)	↑(mRNA)	Roh et al., 2002 [76]
Asiasarum heterotropoides	HFDPCs	=(mRNA)	↑(mRNA)	=(mRNA)	=(mRNA)	Rho et al., 2005 [38]
Eclipta alba	C57BL/6 mice				↑(protein)	Datta et al., 2009 [77]
Lycopersicon esculentum	C57BL/6 mice	↑(mRNA)	↑(mRNA)		↑(mRNA)	Choi et al., 2013 [85]
Oryza sativa	C57BL/6 mice	↑(mRNA)	↑(mRNA)		↑(mRNA)	Choi et al., 2014 [86]
Carthamus tinctorius	HFDPCs		↑(mRNA)		↑(mRNA)	Junlatat and Sripanidkulchai, 2014 [41]
Platycarya strobilacea	HFDPCs	↓(mRNA)			=(mRNA)	Kim et al., 2014 [42]
Panax ginseng	HFDPCs	=(mRNA)	=(mRNA)	=(mRNA)		Park et al., 2015 [43]
Acorus calamus, Morus alba, Glycyrrhiza uralensis, Pinus densiflora, Sophora angustifolia, Ligusticum chuanxiong, and Angelica gigas	C57BL/6 mice		↑(mRNA)		↑(mRNA)	Park et al., 2015 [91]
Geranium sibiricum	HFDPCs		↑(mRNA)	↑(mRNA)		Boisvert et al., 2017 [46]
	C57BL/6 mice		↓(mRNA)	↓(mRNA)
Biota orientalis, Eclipta thermalis, Sophora angustifolia, Cnidium monnieri, Ligusticum chuanxiong, and Panax notoginseng	HFDPCs		↑(mRNA)		↑(mRNA)	Zeng et al., 2017 [148]
Cinnamomum osmophloeum	HFDPCs	=(mRNA)	↑(mRNA)	=(mRNA)	↑(mRNA)	Wen et al., 2018 [48]
Houttuynia cordata	HFDPCs	=(protein)	↑(protein)		=(protein)	Kim et al., 2019 [49]
Polygonum multiflorum	HFDPCs		↑(protein)			Shin et al., 2020 [51]
Salvia plebeia	HFDPCs			↑(mRNA)		Jin et al., 2020 [52]
Platycladus orientalis	C57BL/6 mice	↑(protein)	↑(protein)			Ahn et al., 2020 [99]
Nelumbo nucifera	C57BL/6 mice	↑(mRNA)	↑(mRNA)			Park et al., 2021 [55]
Centipeda minima	HFDPCs	↑(protein)	↑(mRNA) ↑(protein)			Kim et al., 2021 [149]
Brassica oleracea	HFDPCs	=(mRNA)	↑(mRNA)		↓(mRNA)	Luo and Zhang, 2022 [66]
Pinus thunbergii	C57BL/6 mice	↑(protein)	↑(protein)			Her et al., 2022 [108]
Eremochloa ophiuroides	HFDPCs	↑(mRNA)	↑(mRNA)			Ramadhani et al., 2022 [56]
Allium ascalonicum	HFDPCs		↑(mRNA)			Ruksiriwanich et al., 2022 [57]
Camellia japonica	HFDPCs	↑(mRNA)	↑(mRNA)	↑(mRNA)		Wang et al., 2022 [58]
Lycopus lucidus	HFDPCs		↑(protein) =(mRNA)			Lee et al., 2022 [59]
	C57BL/6 mice	↑(protein)	↑(protein)
Camellia japonica	HFDPCs		↑(mRNA) ↓(protein)			You et al., 2023 [61]
Coffea arabica	HFDPCs		↑(mRNA)			Muangsanguan et al., 2023 [135]
Cudrania tricuspidata and Sargassum fusiforme	C57BL/6 mice		↑(mRNA)			Rajan et al., 2023 [74]
Silybum marianum	HFDPCs	↑(mRNA)	↑(protein)		↑(mRNA)	You et al., 2024 [65]

↑, ↓, and = represent increases, decreases, and no changes, respectively. Abbreviations: IGF—insulin-like growth factor; VEGF—vascular endothelial growth factor; HGF—hepatocyte growth factor; KGF—keratinocyte growth factor; FGF-7—fibroblast growth factor 7.

5.6. Effects of Plant Extracts on the AKT and Mitogen-Activated Protein Kinase (MAPK) Signaling Pathways

The activation of phosphoinositide 3-kinases (PI3Ks) and the subsequent phosphorylation and activation of protein kinase B (PKB, also called AKT) by 3-phosphoinositide-dependent kinase 1 (PDK1) or other protein kinases promote cell cycle progression and enhance cell survival [150]. AKT-mediated phosphorylation (inactivation) of glycogen synthase kinase 3 beta (GSK3β) prevents phosphorylation and degradation of cyclin D1, promoting G1‒S phase transition [151]. AKT can inhibit apoptosis by phosphorylating and inactivating several proapoptotic proteins, such as BAD and caspase 9 [152].

Mitogen-activated protein kinases (MAPKs) comprising extracellular signal-regulated kinase (ERK), c-Jun N-terminal kinase (JNK), and p38 MAPK play a critical role in cell physiology [153]. An MAPK cascade is defined as a sequential activation of MAPK kinase kinases (e.g., Raf-1), MAPK kinases (e.g., MEK1 and MEK2), and MAPKs (e.g., ERK1 and ERK2) [154]. The activation of the Raf-1/MEK/ERK pathway leads to the transactivation of target gene expression involved in cell proliferation and other cell functions [155].

Table 12 shows the effect of plant extracts on several protein kinases and protein factors involved in controlling cell fates, such as cell survival, proliferation, and death. Plant extracts derived from Panax ginseng, Rumex japonicas, Houttuynia cordata, Salvia plebeian, Eremochloa ophiuroides, and Camellia japonica stimulated the phosphorylation (activation) of AKT in HFDPCs [43,44,49,52,56,58]. The phosphorylation (activation) of ERK was stimulated by extract from Panax ginseng, Rumex japonicas, Houttuynia cordata, Salvia plebeian, Camellia japonica, or Centipeda minima [43,44,49,52,58,149], and a herbal formula [54]. There are few studies on the phosphorylation (activation) of JNK and p38 MAPK in association with the hair growth-promoting effects of plant extracts [44,149].

Table 12.

Effects of plant extracts on the AKT and mitogen-activated protein kinase (MAPK) signaling pathways.

Plant Extract Sources	Models	AKT	ERK	JNK	p38 MAPK	Literature
Panax ginseng	HFDPCs	↑(phospho)	↑(phospho)			Park et al., 2015 [43]
Rumex japonicus	HFDPCs	↑(phospho)	↑(phospho)	=(phospho)	=(phospho)	Lee et al., 2016 [44]
Houttuynia cordata	HFDPCs	↑(phospho)	↑(phospho)			Kim et al., 2019 [49]
Salvia plebeia	HFDPCs	↑(phospho)	↑(phospho)			Jin et al., 2020 [52]
Euterpe oleracea, Olea europea, Tabebuia impetiginosa, and Coffea Arabica	HFDPCs		↑(phospho)			Serruya and Maor, 2021 [54]
Eremochloa ophiuroides	HFDPCs	↑(phospho)				Ramadhani et al., 2022 [56]
Camellia japonica	HFDPCs	↑(phospho)	↑(phospho)			Wang et al., 2022 [58]
Centipeda minima	HFDPCs		↑(phospho)	↑(phospho)	↓(phospho)	Kim et al., 2021 [149]

↑, ↓, and = represent increases, decreases, and no changes, respectively. Abbreviations: AKT—protein kinase B (PKB); ERK—extracellular signal-regulated kinases; JNK—c-Jun N-terminal kinase; p38 MAPK—p38 mitogen-activated protein kinase; phospho—phosphorylation.

5.7. Effects of Plant Extracts on the Wingless and Int-1 (WNT) Signaling Pathways

The canonical and non-canonical WNT signaling pathways are involved in regulating cell proliferation, polarity, or migration [156]. In the canonical WNT pathway mediated by β-catenin, the stability of β-catenin is negatively regulated by its phosphorylation at multiple sites by several protein kinases, such as casein kinase 1 (CK1) and GSK3β [156]. When WNT signaling is activated, GSK3β is inactivated through phosphorylation by several protein kinases, such as AKT, or other mechanisms. Then, β-catenin that has avoided proteasomal degradation enters the nucleus, where it acts as a transcriptional coactivator, interacting with several transcription factors, such as lymphoid enhancer-binding factor 1 (LEF1), and regulates the transcription of various target genes, including cyclin D1 and c-Myc [157]. The target genes also include dickkopf 1 (DKK1), which inhibits the WNT pathway in a negative feedback loop [158]. The DKK1 expression level is associated with hair loss; thus, DKK1 inhibition represents an attractive strategy to promote hair growth in androgenetic alopecia [159,160].

Table 13 summarizes the effects of plant extracts on the WNT signaling pathways involved in cell differentiation. The extracts of several plants have been shown to increase the expression of WNTs [61,64,74,99,149] or decrease the expression of DKK1 [51,61,64,72,110]. Several plant extracts have been shown to increase the phosphorylation (inactivation) of GSK3β, upregulating β-catenin levels [44,52,56,149]. Several other extracts also upregulated β-catenin levels [40,57,64,68,79,83,99]. Gynostemma pentaphyllum extract also upregulated LEF1 [64]. The extracts of Mangifera indica, Camellia japonica, and Terminalia bellirica increased the expression of downstream targets of the WNT pathway, such as c-Myc and cyclin D1 [61,68,110].

Table 13.

Effects of plant extracts on the mediators of the WNT signaling pathways.

Plant Extract Sources	Models	WNTs	DKK1	GSK3β	β-Catenin	LEF1	c-Myc	Cyclin D1	Literature
Polygonum multiflorum	C57BL6/N				↑(protein)				Park et al., 2011 [79]
Aconiti Ciliare	iDPCs				↑(protein)				Park et al., 2012 [40]
Thuja orientalis	C57BL/6N mice				↑(protein)				Zhang et al., 2013 [83]
Rumex japonicus	HFDPCs			↑(phospho)	↑(protein)				Lee et al., 2016 [44]
Polygonum multiflorum	HFDPCs		↓(protein)						Shin et al., 2020 [51]
Salvia plebeia	HFDPCs			↑(phospho)	↓(phospho) ↑(protein)				Jin et al., 2020 [52]
Platycladus orientalis	C57BL/6 mice	WNT3 ↑(protein)			↑(protein)				Ahn et al., 2020 [99]
Centipeda minima	HFDPCs	WNT5a ↑(mRNA)		↑(phospho)	↑(protein)				Kim et al., 2021 [149]
Brassica oleracea	HFDPCs				=(mRNA)				Luo and Zhang, 2022 [66]
Eremochloa ophiuroides	HFDPCs			↑(phospho)	↑(protein)				Ramadhani et al., 2022 [56]
Allium ascalonicum	HFDPCs				↑(mRNA)				Ruksiriwanich et al., 2022 [57]
Mangifera indica	HFDPCs		↓(mRNA)				↑(mRNA)		Jung et al., 2022 [110]
Nasturtium officinale	Human hair follicles		↓(protein)						Hashimoto et al., 2022 [72]
Camellia japonica	HFDPCs	WNT1 ↑(mRNA)	↓(protein)				↑(mRNA)	↑(mRNA)	You et al., 2023 [61]
Terminalia bellirica	C57BL/6 mice				↑(protein)			↑(protein)	Woo et al., 2023 [68]
Cudrania tricuspidata and Sargassum fusiforme	C57BL/6 mice	WNT5a, WNT7b ↑(mRNA)							Rajan et al., 2023 [74]
Gynostemma pentaphyllum	HFDPCs	WNT5a ↑(mRNA) ↑(protein)	↓(mRNA)		↑(mRNA) ↑(protein)	↑(mRNA)			Liu et al., 2024 [64]

↑, ↓, and = represent increases, decreases, and no changes, respectively. Abbreviations: WNT—Wingless and Int-1; DKK1—dickkopf 1; GSK3β—glycogen synthase kinase 3β; LEF1—lymphoid enhancer-binding factor 1.

5.8. Effects of Plant Extracts on the Sonic Hedgehog (SHH) Signaling Pathways

Hedgehog ligands, including sonic hedgehog (SHH), desert hedgehog (DHH), and Indian hedgehog (IHH), are paracrine signaling factors that mediate cell-to-cell communication [161]. The SHH signaling pathway is involved in regulating hair follicle morphogenesis [162]. The interaction between SHH and the transmembrane protein patched (PTC) triggers the release of smoothened (SMO) from suppressing PTC, which leads to the dissociation of glioma-associated oncogene transcription factor (GLI) from a cytosolic complex [163]. GLI proteins enter the nucleus and act as transcription factors regulating the expression of target genes [164].

Table 14 summarizes plant extracts that affected the SHH signaling pathway. Several plant extracts increased SHH protein levels in hair follicles in animal models. The extract of Allium ascalonicum and Coffea arabica promoted gene expression of SHH, SMO, and GLI1 at the cellular level [57,135].

Table 14.

Effects of plant extracts on the mediators of the sonic hedgehog (SHH) signaling pathways.

Plant Extract Sources	Models	SHH	SMO	GLI1	Literature
Eclipta alba	C57BL/6 mice	↑(protein)			Datta et al., 2009 [77]
Polygonum multiflorum	C57BL6/N	↑(protein)			Park et al., 2011 [79]
Thuja orientalis	C57BL/6N mice	↑(protein)			Zhang et al., 2013 [83]
Eremochloa ophiuroides	C57BL/6 mice	↑(protein)			Ramadhani et al., 2022 [56]
Allium ascalonicum	HFDPCs	↑(mRNA)	↑(mRNA)	↑(mRNA)	Ruksiriwanich et al., 2022 [57]
Coffea arabica	HFDPCs	↑(mRNA)	↑(mRNA)	↑(mRNA)	Muangsanguan et al., 2023 [135]

↑ represents increases. Abbreviations: SMO—smoothened; GLI—glioma-associated oncogene transcription factor.

5.9. Effects of Plant Extracts on the Transforming Growth Factor (TGF)-β and Bone Morphogenetic Protein (BMP) Signaling Pathways

TGF-βs and BMPs are members of the TGF-β superfamily. In the canonical TGF-β signaling pathway, binding of TGF-βs to their receptors induces the phosphorylation of small mothers against decapentaplegic (SMAD) 2 and SMAD3 (called receptor-regulated SMADs or R-SMADs) followed by the formation of a trimeric complex with SMAD4 (called a common partner SMAD or co-SMAD), which enters the nucleus and induces the transcription of target genes [165]. The target genes include SMAD7 (called an inhibitory SMAD or I-SMAD), which blocks TGF-β signaling in a negative feedback loop [166]. In the canonical BMP signaling pathway, SMADs 1, 5, and 8 act as R-SMADs, and SMAD 6 acts as an I-SMAD, whereas SAMD4 acts as a co-SMAD [167]. TGFs and BMPs can also trigger the non-canonical signaling pathways mediated by multiple protein kinases independently of SMADs [167,168]. TGF-βs and BMPs are known to negatively affect hair growth by suppressing hair follicle function and causing hair cycle progression into the telogen phase [169,170].

Table 15 summarizes plant extracts that affect the TGF-β and BMP signaling pathways. Many plant extracts decreased the expression of TGF-β1, TGF-β2, BMP4, SMAD2, and SMAD3 in cell and animal models. Exceptionally, the expression of TGF-β2 was increased by Cinnamomum osmophloeum extract [48].

Table 15.

Effects of plant extracts on the TGF-β and BMP signaling pathways.

Plant Extract Sources	Models	TGF-β1	TGF-β2	BMP4	SMAD2	SMAD3	Literature
Asiasarum heterotropoides	HFDPCs	=(mRNA)					Rho et al., 2005 [38]
Eclipta alba	C57BL/6 mice			↓(protein)			Datta et al., 2009 [77]
Lycopersicon esculentum	C57BL/6 mice	=(mRNA)					Choi et al., 2013 [85]
Oryza sativa	C57BL/6 mice	↓(mRNA)					Choi et al., 2014 [86]
Carthamus tinctorius	HFDPCs	↓(mRNA)					Junlatat and Sripanidkulchai, 2014 [41]
Platycarya strobilacea	HFDPCs	=(mRNA)					Kim et al., 2014 [42]
Geranium sibiricum	HFDPCs	=(mRNA)					Boisvert et al., 2017 [46]
	C57BL/6 mice	↓(mRNA)
Cinnamomum osmophloeum	HFDPCs		↑(mRNA)				Wen et al., 2018 [48]
Serenoa repens	C57BL/6 mice		↓(protein)				Zhu et al., 2018 [94]
Panax ginseng, Glycine max, Houttuynia cordata, Lycium chinense, Glycyrrhiza uralensis, Citrus unshiu, Zizyphus jujuba, Perilla frutescens, Camellia sinensis, and Cynanchum wilfordii	HFDPCs	↓(mRNA)					Kang et al., 2019 [50]
Salvia plebeia	HFDPCs	↓(mRNA)			↓(protein)	↓(protein)	Jin et al., 2020 [52]
Euterpe oleracea, Olea europea, Tabebuia impetiginosa, and Coffea Arabica	HFDPCs	↓(protein)					Serruya and Maor, 2021 [54]
Nelumbo nucifera	C57BL/6 mice	↓(mRNA)					Park et al., 2021 [55]
Brassica oleracea	HFDPCs	=(mRNA)					Luo and Zhang, 2022 [66]
Camellia japonica	HFDPCs	↓(mRNA)					Wang et al., 2022 [58]
Acorus calamus, Morus alba, Glycyrrhiza uralensis, Pinus densiflora, Sophora angustifolia, Ligusticum chuanxiong, and Angelica gigas	C57BL/6 mice	↓(mRNA)					Muangsanguan et al., 2023 [135]
Panax ginseng				↓(mRNA)			Iwabuchi et al., 2024 [63]
Gynostemma pentaphyllum	HFDPCs	↓(mRNA) ↓(protein)					Liu et al., 2024 [64]
Silybum marianum	HFDPCs	↓(mRNA)					You et al., 2024 [65]

↑, ↓, and = represent increases, decreases, and no changes, respectively. Abbreviations: TGF—transforming growth factor; BMP—bone morphogenetic factor.

6. Discussion

Research has been actively conducted to develop effective and safe treatments for human hair loss using natural products, especially plant-based materials. As explained in the previous sections, the hair growth-promoting potential of plant extracts has been supported in many in vitro experiments using cells (Table 1 and Table 2), ex vivo experiments using hair follicle explants (Table 3), in vivo experiments using mice or rats (Table 4), and clinical trials in humans (Table 5). Experimental groups treated with certain plant extracts had cell proliferation and hair growth significantly higher than negative control groups and comparable to positive control groups treated with minoxidil or finasteride. These results suggest that a beneficial effect on hair growth is expected when plant extracts are administered appropriately.

While hair follicles are mini-organs in which several types of cells interact and cooperate to produce and grow hair, many studies have evaluated the effects of test substances using single-cell models in which only specific cells, such as dermal papilla cells, are cultured (Table 1 and Table 2). Considering that interactions between various constituent cells are important for the function of hair follicles, it is necessary to develop technologies for co-culturing multiple cells or three-dimensional cultures, and further artificially creating hair follicles. Ex vivo experiments using excised hair follicles help to overcome some of the limitations of cell models, and the effect of test substances on hair growth has been successfully evaluated in several ex vivo studies (Table 3). However, there are limitations in the supply of human tissue.

Various animal models have been used for primary efficacy testing of plant extracts (Table 4). Animal hair removal models have been most often used in hair growth research although these models have the disadvantage of having little similarity to natural human hair loss. It is worth noting that several plant extracts showed hair growth promotion efficacy equivalent to or higher than minoxidil, a positive control. These include extracts from Rumex japonicus [44], Cucumis melo [70], Perilla frutescens [71], Leea indica [103], Blumea eriantha [109], etc.

Animal models in which hair removal is combined with male hormone administration [68,71,84] or ovariectomy [95] have high physiological relevance as models of androgenetic alopecia in men and postmenopausal alopecia in women, respectively. Extracts of Terminalia bellirica, Perilla frutescens, and Rosmarinus officinalis recovered hair growth suppressed by testosterone or DHT [68,71,84]. Extract of Ribes nigrum promoted hair growth in ovariectomized female Sprague–Dawley rats [95].

Athymic animals with a congenital tendency for hair loss provide a model for natural hair loss without needing hair removal [90]. In a study using male athymic BALB/c nude mice, extract of Chrysanthemum zawadskii promoted hair growth more effectively than extract of Polygonum multiflorum [90]. Examining which type of human hair loss is most similar to an animal model is necessary, since it increases the utility of the animal model in hair growth research. An animal model in which hair loss is induced by spatially confined stress may be utilized in studying similar stress-induced alopecia in humans [96].

Although many extracts have shown high potential for hair growth-promoting effects in animal models, only a few have advanced to the level of clinical trials (Table 5). We do not take any position supporting or disputing previously reported clinical trial results. Currently, no matter what the purpose of the use or the route of administration, we do not recommend the human application of any plant extract without its prior confirmed safety. Expansion of clinical trials is necessary to verify the effectiveness and safety of the final product containing plant extracts.

Plants were often extracted using hot water or various organic solvents, such as methanol (MeOH), EtOH, acetone [75], ethyl acetate [85], and n-hexane [122]. Supercritical CO₂ extraction [85,86], cold vacuum extraction [113], and emulsion-assisted extraction methods [125] have also been used to prepare a special type of plant extract. Solvent partition [71,87,103] and chromatography [71,109] have been used to partially purify or isolate pure active compounds from a crude plant extract. Plant extracts have been formulated in a solution [45], tonic [121,125], lotion [122], cream [120], shampoo [65,123], or nanoparticles [102,171] for topical application. Tablets and other types of food products have also been manufactured for oral administration [62,126]. The improvement in quality control and extraction and purification methods to increase the content of active ingredients in plant extracts and the development of optimized formulas and drug carriers to improve the biological availability and delivery of active compounds to the point of action are needed to prompt the development of effective hair care products using plant extracts.

The biological activity of plant extracts enhancing cell proliferation or hair growth has been attributed to their main phytochemical components (Table 6), such as phenolic compounds (Figure 1), terpenes and terpenoids (Figure 2), sulfur-containing compounds, fatty acids, and other compounds (Figure 3). In some studies, the biological activity of single active compounds has been verified at the cellular level or in vivo. Representative examples of compounds with proven activity include decursin [98], rosmarinic acid [57,59,71], 12-methoxycarnosic acid [84], ginsenosides [43,63], sulforaphane, glucoraphanin [66], dimethyl sulfone [109], α-linolenic acid [75], and linoleic acid [86]. The experimental evidence accumulated so far is insufficient to derive the structure–activity relationship, and we look forward to additional research on this task for optimized drug discovery.

Several plant extracts have been shown to prevent alopecia by inducing or prolonging the anagen phase of the hair cycle and inhibiting entry into the telogen phase (Table 3, Table 4 and Table 5). The pharmacological effects of plant extracts that induced and extended the anagen phase in the hair cycle could be associated with the promotion of cell proliferation (Table 1), cell survival (Table 2), or cell cycle progression (Table 10); the upregulation of several growth factors, such as IGF-1, VEGF, HGF, and KGF (FGF-7) (Table 11); and the stimulation of several cell signaling pathways mediated by AKT, ERK, WNT, or SHH (Table 12, Table 13 and Table 14). In addition, the pharmacological effects of plant extracts that prevented the entry into the telogen phase in the hair cycle could be attributed to the alleviation of oxidative stress, inflammatory response, cellular senescence (Table 7), or apoptosis (Table 8); the downregulation of male hormones and their receptors (Table 9); and the suppression of several cell signaling pathways mediated by TGF-β or BMP (Table 15). These findings suggest a potential mechanism of action of plant extracts in promoting hair growth and preventing hair loss, which is schematized in Figure 4.

Figure 4.

The modulatory targets of plant extracts for promoting hair growth and preventing hair loss. Several plant extracts containing various active phytochemicals can initiate or extend the anagen phase of the hair cycle by stimulating the expression of several growth factors; the AKT, ERK, WNT, and SHH signaling pathways; or inducing the cell cycle progression. Some plant extracts can prevent entry into the telogen phase of the hair cycle by inhibiting androgen expression and the TGF-β and BMP signaling pathways or alleviating ROS-mediated oxidative stress, inflammatory response, cellular senescence, and apoptosis. Plant extracts with different mechanisms of action can show differentiated efficacy according to the type of hair loss with different etiology. Black arrows indicate the hair cycle progression associated with hair growth and loss. Sharp red arrows indicate upregulation, stimulation, or promotion, and blunted blue arrows indicate downregulation, inhibition, or suppression by plant extracts.

Because the hair cycle depends on the health and function of various cells in the hair follicles, which are in turn affected by multiple physiological factors, such as hormones and stresses [2,14,172,173,174], it is necessary to analyze in detail the etiology and pathology of alopecia for each patient and develop a customized treatment strategy accordingly. To achieve this, effective medications targeting specific cellular events and cell signaling pathways involved in hair growth and loss are needed. Exploration of plant-based natural products against these modulatory targets will provide a promising opportunity to discover natural remedies or lead compounds for targeted therapies for different types of hair loss.

Overall, research in this field has not only expanded the list of plant extracts and phytochemicals with the potential to promote hair health but has also deepened our understanding of their mechanisms of action. However, there are not many studies that comprehensively explore pharmacological effects, active compounds, and molecular targets of the plant extracts. More integrated and expanded research that reflects the latest knowledge presented in this review is needed to promote the development of improved treatments for alopecia.

7. Conclusions

Accumulated evidence from in vitro, in vivo, and clinical studies suggests that several plant extracts and phytochemicals can help prevent hair loss or promote hair growth and regrowth. Well-selected plant extracts can provide additional or alternative hair loss treatment options to people reluctant to use medicines. In addition, the active compounds can serve as lead compounds for new drug discovery and development. Their effects on the hair cycle were associated with the modulation of cell proliferation, cell survival, cell cycle progression, growth factors, hormones, oxidative stress, inflammatory response, cellular senescence, apoptosis, and several cell signaling pathways mediated by AKT, ERK, WNT, SHH, TGF-β, or BMP. Therefore, it is proposed that the discovery of phytochemicals modulating these targets will lead to the development of new targeted therapies for alopecia.

Author Contributions

Conceptualization, Y.C.B.; investigation, J.Y.C. and Y.C.B.; writing—original draft preparation, J.Y.C. and Y.C.B.; writing—review and editing, M.Y.B.; supervision, Y.C.B. All authors have read and agreed to the published version of the manuscript.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The original contributions presented in this study are included in the article, and further inquiries can be directed to the corresponding author.

Conflicts of Interest

The authors declare no conflicts of interest.

Funding Statement

This research received no funding.