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Review

Date Fruit and Seed in Nutricosmetics

1
Department of Beauty and Cosmetology, Graduate School of Industrial Technology Startup, Chosun University, 309 Pilmun-daero, Dong-gu, Gwangju 61452, Korea
2
Department of Biochemical and Polymer Engineering, Chosun University, 309 Pilmun-daero, Dong-gu, Gwangju 61452, Korea
*
Author to whom correspondence should be addressed.
Contributed equally.
Submission received: 25 May 2021 / Revised: 10 June 2021 / Accepted: 12 June 2021 / Published: 24 June 2021

Abstract

:
Many recent studies in the field of cosmetics have focused on organically sourced substances. Products made from organic materials are safe, high quality, cruelty-free, and more effective than those made from synthetic materials. Many organic compounds are known to be physiologically active in humans and have an extended storage capacity and long-lasting environmental effects. Agro-industrial waste has recently increased substantially, and the disposal of date palm waste, often performed in primitive ways such as burning, is harmful to the environment. Fruit processing industries generate over 10% of the total date seed waste daily, which could be converted into useful food products. Date fruit and seed are rich in sugar, vitamins, fiber, minerals, and phenolic compounds with antioxidant and anti-inflammatory properties that significantly promote human and animal health. This waste is rich in bioactive compounds and essential oils used in many kinds of food, medicine, and cosmetics. Most active cosmetic ingredients come from natural sources such as fruit, fish, and dairy, and recent research shows that date extract and seed oil help to reduce melanin, eczema, acne, and dry patches, while increasing skin moisture and elasticity. This review details the bioactive compounds and nutraceutical properties of date fruit and seed, and their use as cosmetic ingredients.

1. Introduction

The palm tree is a basic food source in the Arabian Peninsula and has been recognized as a significant economic crop for the last 7000 years [1]. Globally, 2000 varieties have been cultivated, and 10% of them have been described according to the fruit characteristics [2]. Saudi Arabia is a major producer of date palm. Exports registered a 27% rise in the middle of 2019 [3], and the demand and production rate have been increasing rapidly. Date fruits are affordable and rich in fiber and energy and are considered as a staple food along with grains, potatoes, and rice. The developmental stages of dates have internationally adopted Arabic names according to their stages of maturity, such as Hababauk, Kimry, Khalal, Rutab, and Tamar (Table 1). The stage of maturity, yield, physical condition, flavor, texture, and nutritive value is affected by agricultural practices and climatic conditions. Moreover, date seeds, leaves, pollen, fruits, and trunks are used to treat a variety of ailments [4]. The fruit comprises a fleshy pericarp and one seed, which constitutes 10–15% of its weight [5]. Date seeds can stay dormant for many years and grow when favorable circumstances resume [6].
The date palm, Phoenix roebelenii, is native to southeastern Asia and grows in tropical and subtropical regions. It is the main crop of the Arabian Peninsula, North Africa, the Middle East, and across Southwest Asia [8]. The total area under date palm cultivation across the world is 1,092,104 ha, with a total production of 9,075,446 t [9]. The lead producers of date palm are Asia and Africa, with a total production share of 57% and 42.2%, respectively [9]. The top 10 date-producing countries are illustrated in Figure 1. Saudi Arabia was the second largest date producer from 2018–2019, with a total production of 1,483,631 t [9]. The wild Indian date palm (P. sylvestris), which is exploited for the sugar in its sap, resembles P. dactylifera (Ajwa) and is cultivated commercially. The Ajwa variety is described as “super date” and is considered to be highly nutritional and therapeutic [10]. Dates are an indispensable source of dietary metals and free amino acids, and have been used to treat chronic illnesses and diseases since ancient times [11]. They have also been found to reduce high blood pressure and oxidative stress, and have been used to treat diabetes, cancer, and atherosclerosis, and to stimulate immunity [12]. In addition, they have a higher antioxidant activity than culinary fruits [13] and contain several bioactive compounds, such as coumaric acids, ferulic acid, cinnamic acid, flavonoids, procyanidins, phenolic compounds, and water-soluble vitamins [14]. These compounds can strengthen bones, promote uterine contractions in pregnant women during childbirth, and prevent anemia [15]. Additionally, Ajwa and other date varieties can prevent cancer, cardiac arrest, and neuron damage, and can also increase fertility [5,16].
The cosmetics industry has been one of the fastest growing industries and is flourishing globally. Using the inedible extracts of fruits and vegetables, instead of disposing them by burning, prevents a severe threat to the environment [17]. Date seeds are a rich source of bioactive compounds and are important ingredients within the cosmetics industry, also serving as food additives [18]. A recent study showed the importance of recycling date waste and that date pit powder can be used as a cosmetic product (eyeliner), which does not exert toxic effects on the eye [19]. Extraction of waxes from date palm leaves could be carried out to obtain compounds of potential value from the biomass of this waste. This could provide new possibilities for natural wax production. The demand for natural waxes is steadily increasing due to customers’ preferences for green, sustainable, and natural cosmetic products [20]. Date fruits and seeds have been reported to possess antiaging properties and overcome wrinkling of the skin in women. Date waste is believed to contain many essential components that strengthen the hair and skin, prevent early graying of hair, stop wrinkle development, and give the skin a fresh look [21]. This review summarizes the current knowledge on the phytochemical components in date seeds and their use in beauty products.

2. Sustainability of Date Palm

Dates contain high levels of sugar and fiber and have high economic value [22]. The worldwide date production, industrialization, and utilization has been continuously increasing over the years, as per the FAO [9]. This has led to a rapid increase in date fruit waste and agro-waste during the period of fruit maturation and harvesting. Storage and conditioning may also increase fruit waste [23]. Moreover, date waste causes serious environmental problems, most notably the emission of gases into the atmosphere, which leads to global warming [24].

2.1. Date Palm Fruit

Palm trees have played an essential role in the Gulf region’s environment due to its wide use in landscaping. Moreover, cultivated palm tree products are also widely used in the diet in this region. The tree consists of different parts, such as the leaflet, rachis, and fibers. The parts never fall naturally and are removed manually. The large leaves are recycled, and the residues are components of biomass that can produce value-added products. More than 30 million palm trees have been reported in the UAE alone, and each palm tree produces an average of 15 new leaves every year. Each leaf has a dry weight of about 3 kg; therefore, the average production of each palm is about 25–30 kg. The surface fibers and additional waste fruit clusters (10–15 kg) create a total of 40 kg of waste/tree, and the annual waste is calculated at 1.2 million tons [25]. The same study also included a rapid thermal gravimetric analysis of date palm (P. dactylifera) leaflet, rachis, and fibers. Each part was decomposed at different temperatures and time. Bio-oil and non-condensable gas were obtained during the pyrolysis process. Among those components, 38.8% was bio-oil, 10.4% was reaction water, 37.2% was bio-coal, and 24.0% was non-condensable gas. The overall energy conversion efficiency was 87.0%, indicating a high potential for converting date palm waste into energy while eliminating the polluting impact on the environment and the cost associated with the disposal of this waste [26].

2.2. Date Seed

The non-edible seed portion is usually discarded after consuming date fruits; they may be scattered and sown in fields. Seed propagation is the easiest and quickest method of propagation and may yield hybrid seedlings. Date fruits consist of the epicarp, a fleshy mesocarp (pulp), and an endocarp consisting of a seed called a kernel or pit [2]. The palm agro-industry and processing industries have generated vast amounts of seed waste and date press cakes. Additionally, a high production rate, improper handling, and lack of scientific knowledge may increase the wastage by more than 30% of the production values [27]. The agricultural wastes consist of cellulose, hemicelluloses, lignin, and other compounds used in many biological processes. Additionally, the agro-waste and industrial waste materials can be used to prepare good-value fertilizers with a compost mixture that comprises 70% of date palm waste [28]. These by-products are currently used for limited purposes, such as animal (camels, cattle, sheep, and poultry) feed [29,30]. Date seeds are the waste products of the date industry, and approximately 1 million tons of date seeds are produced annually [31]. The seed is a source of edible oil and can be used as a functional food ingredient. Date seeds are also a good source of dietary fiber, phenolic compounds, and essential fatty acids.

3. Chemical Composition of Date Fruits

The date palm P. dactylifera is one of the most widely consumed fruits in the world. They are consumed as part of a healthy diet as they are rich in sugar and dietary fibers [2]. Date fruits are also a good source of sugar (70–80% sugar content), which varies according to the species and the stage of maturity of the fruits. The major sugars in most date cultivars are glucose, fructose, and sucrose, which are easily absorbed by the body to provide energy [32]. Several researchers have observed that the total percentage of glucose and fructose is high in the Khalas cultivar [32,33]. Sucrose is the dominant sugar in many cultivars such as Sukkary and Nabtat Ali [34]. The total sugar concentration differs between the earlier growth stage and the ripening stage, and sugar concentration usually increases from the Khalal stage to the date stage. Nevertheless, the ecological factors and the type of cultivar also significantly affect the sugar percentage. The average protein content has been recorded to be 1.22–3.30%, fat 0.11–7.33%, ash 1.43–6.20%, and carbohydrates 65.7–88.02% [35,36,37]. However, the protein content decreases during the non-enzymatic browning and tannin precipitation stage. Date fruits contain all essential and non-essential amino acids, particularly glutamic acid, lysine, alanine, serine, aspartic acid, proline, and glycine. At the same time, the fatty acids (0.2–0.5%) and vitamin contents recorded in date fruits was low [38]. Interestingly, the content of B-complex vitamins was observed to be high in date fruits [39]. Dates contain 1.9–16.95% dietary fiber, out of which insoluble fiber is recorded as 84–94%, and soluble fiber content ranges between 6–16% [36,40,41]. In addition, date fruit contains most of the nutritionally essential minerals, with high levels of potassium, remarkable levels of phosphorus, magnesium, and calcium, as well as low sodium concentrations [42,43] (Table 2). Dietary fiber has important therapeutic effects, and the fiber concentration also depends on the variety and stage of maturity [5,44]. Furthermore, the elemental fluorine and selenium found in date fruit can protect teeth and stimulate immune function in humans. In addition, dates contain 1–2% phenolic antioxidants, tannin-based pigments, and epicatechin oligomers.

4. Chemical Composition of Date Seeds

The average weight of date seeds is 5.6–14.2% of the fruit. They are a good source of phytochemicals such as phenols, sterols, carotenoids, anthocyanins, procyanidins, and flavonoids [46,47]. They are also rich in dietary fiber (67.56–74.20%), with water-insoluble mannan fiber found at a high percentage. The contents of proteins, vitamins, fatty acids, and minerals were reported to be high in the date seed (Table 2). Insoluble dietary fibers (hemicellulose, cellulose, and lignin) are the main components of seed fiber [48]. Date seeds contain many dietary minerals such as potassium, copper, magnesium, calcium, cadmium, chromium, iron, manganese, zinc, nickel, cobalt, calcium, phosphorous, and lead; the potassium levels were reported to be high (229–293 mg/100 g) [38,43,45,49]. The concentration of minerals in dates increases with maturity in some varieties, such as in the Deglat Noor variety. Other studies have found that the mineral concentration decreases when the dates in five other varieties are ripened [46]. The fatty acid content in the seed varies from 53.2–58.8%, which includes eight types of fatty acids [38,43]. They are a good source of unsaturated fatty acids, oleic acid (42.3%), and linoleic acid (13.7%). In contrast, the saturated fatty acids, viz., palmitic acid (9.6%) and lauric acid (21.8%), were reported at minimal concentrations [38,50]. In addition, fruit pulp and seeds contain other fatty acids such as myristic, stearic, and linolenic acids. The predominant fatty acid recorded at a high level was oleic acid, and the levels varied among the species [43]. The advantage of the seed oil is that it has a dark yellowish hue compared to the vegetable oils. Furthermore, it has a high oxidation rate and can be stored for a long time. Therefore, it may be used in cosmetics as a preservative. Oleic acid is used in the cosmetic industry to improve skin permeability through topical applications [51].

5. Value-Added Products from Date Fruits and Seeds

Date industries have been looking towards developing value-added products, as they are highly profitable and may reduce the risk of date deterioration. Boulal et al. (2016) achieved bioethanol production from date palm fruit waste by yeast (Saccharomyces cerevisiae)-mediated fermentation [52,53]. Additionally, other studies have demonstrated that date waste can be used as a substrate to produce citric acid using S. cerevisiae and Aspergillus niger [54]. According to Chauhan et al. (2007), date juice is considered as a suitable medium for lactic acid production by Lactobacillus species (KCP01) [55]. Other studies have reported the production of cellulose and xanthan gum by bacterial fermentation [56,57]. The raw materials are cheap, and the fermentation process requires limited treatment in these cases. The agro-waste and fruit waste bioconstituents were degraded by microorganisms or by enzyme processing to augment value-added products [58]. Date seed is considered to be one of the major sources of waste during harvest and processing. However, roasted and powdered date seeds are used by some rural communities as coffee substitutes, and in coffee-like preparations in Arabian markets [59]. In addition, date fruit extract, paste, and fermented products are used for making dietary supplements, juice concentrate, syrup, yogurt, bread, confectionery, and preservatives [60,61,62,63,64,65,66,67] (Table 3). Date fruits are also used in the production of high-quality fruit wine [68]. Date seeds constitute a surplus of date fruit by-products due to processing, and its exploitation in food and feed provides an economic advantage [2]. Moreover, they are rich in fiber and phenolic compounds, and they show high oxidative stability and sensory acceptability [69,70,71,72]. In addition, fatty acids and oil are derived from date seeds used in cosmetic industries [73,74]. Different kinds of traditional, natural, and man-made materials have been developed from date palm waste, such as mats, screens, baskets, crates, fans, walking sticks, brooms, fishing floats, and fuel.
Moreover, leaf fiber and sheaths are used to prepare packsaddles, rope, coarse cloth, and large hats [75]. Recently, date pits were utilized in bioremediation processes because of their high lignocellulose levels. Additionally, they can be excellent precursors to activated carbon and can be used for heavy-metal remediation of wastewater [76]. Annually, more than 127,000 metric tons of seed oil are extracted from the date pits. The waste and by-products include pigments, dietary fiber, organic acids, sugars, and antibacterial or antifungal compounds, which have shown health-promoting effects in humans [77,78]. Date fruit waste is also considered to have chemoprotective, antioxidant, anti-inflammatory, and anticancer properties [79,80]. Meer et al. (2017) demonstrated that date fruit extract significantly improved skin health [73]. Date seeds contain 6–8% essential oil suitable for usage in the production of moisturizing soaps/creams, shampoos, and other skincare products [81,82]. Moreover, date seed oil has been used in the production of medicine, food, and even cosmetics [74,83].

6. Bioactive Compounds from Date Fruits and Seed

The date fruit and its seeds are highly nutritional and have medicinal properties owing to their bioactive compounds. However, the potential use of date fruits and seeds in the development of pharmaceutical drugs and cosmetic products has not been fully explored. Date fruits and seeds are rich in non-nutritional compounds such as phytochemicals, such as phenolics, anthocyanins, carotenoids, tocopherols, tocotrienols, phytosterols, and dietary fiber [84,85,86,87]. The presence of non-starch polysaccharides, α-tocopherols, β-carotene, ascorbic acid, and selenium-like nutritive bioconstituents has also been reported [84,85]. Fruits are a good source of phenolic compounds, which are biologically active substances containing a benzene hydroxyl ring with a carboxyl group [21]. The fruits contain simple phenolic molecules such as phenolic acids, polyphenols such as flavonoids, and high molecular weight compact polymers (Figure 2). According to Vinson et al. (2005), dried fruits contain extremely high levels of phenolics and, notably, fiber [86]. However, phenolic compounds are essential nutrients of the human diet and show high antioxidant activities [87]. El-Mergawi et al. (2019) demonstrated that the phenolic content and antioxidant activity in the fruits of 17 Saudi Arabian date cultivars were variable [88]. Date seed oil contained a significant phenolic compound and showed diverse pharmacological effects, such as antimutagenic, anticarcinogenic, and anti-inflammatory activities [89,90]. Several phenolic and flavonoid compounds were found in date fruits [91,92,93,94,95,96,97,98,99,100]. Phenolic compounds act as natural antioxidants. They can penetrate the epidermis and dermis and protect the skin from the damaging action of ultraviolet (UV) oxidation and premature skin aging [101,102]. Al-Juhaimi et al. (2018) found gallic acid, syringic acid, and caffeic acid to be the major phenolic acids present in date seeds that could act as pharmaceutical agents [82]. In addition, date seed oil is used in cosmetic formulations such as body creams, shaving soap, and shampoos, as well as in pharmaceutical products [81,103]. Al-Farsi and Lee (2008) showed that date fruits are rich in selenium and contain coenzymes that reduce oxidative stress and infection [5]. In addition, date fruits contain different kinds of flavonoid glycosides such as luteolin, quercetin, and apigenin, which have been found to exist in methylated and sulfated forms. Anthocyanins have been found in fresh fruit, while carotenoids have been found to decrease fruit ripening [47]. However, the metabolites can vary among the cultivars, and both the ecological factors and the fruit ripening stage can affect their quantity and bioactivity [90,103].

7. Bioactive Compounds from Date Seeds

Date seeds are a potentially strong candidate for use as a functional ingredient in human food and animal feed. Moreover, date seed products (seed powder, bread, and extract paste) are safe for human consumption [104]. The seed powder employed as a coffee substitute in coffee drinks may also contain various essential minerals and bioconstituents at optimum levels. The functional ingredient of date seeds has also been used in traditional medicine to relieve toothaches [105]. Phoenix dactylifera has been shown to have immunomodulation activity, and the ability of date seeds to possibly lower the risk of cardiovascular disorders and cancer has been tested to develop a functional food product [106,107]. Although date seeds are considered a by-product, they are probably one of the richest edible sources of polyphenolic compounds. Date seed extract and bioactive constituents are considered to be valuable sources for developing drugs and nutraceuticals, because they have been proven to be highly beneficial to humans [33,108,109].
Nevertheless, the organic extraction procedure can also influence the availability and bioactivity of the compounds [5,110]. The traditional extraction process using organic solvents is harmful and dangerous to humans and the environment. Other studies have reported that supercritical carbon dioxide (SC-CO2) is the optimum method for natural compound extraction out of all the available clean technologies used to extract compounds from date seeds. [37,111]. Several phenolic acids and flavonoids have been reported in date fruits and seeds, which could be considered as an inexpensive source of natural antioxidants. Date seeds are also considered to be a valuable source of other phytochemicals, such as sterols, carotenoids, procyanidins, and anthocyanins. Anthocyanin and flavonoid contents were recorded in high levels in P. dactylifera, which promises to be an exciting source of antioxidant compounds [112]. Additionally, the date seed is a good source of hydroxylated derivatives of benzoic acid (gallic acid, protocatechuic acid, p-hydroxybenzoic acid, and vanillic acid), cinnamic acid derivatives (caffeic acid, coumaric acid, and ferulic acid), quercetin-3-O-glucoside, catechin, procyanidin, tannins, and vitamins such as tocopherol [22,99]. However, the aqueous extract of the date seed is composed of components of polyphenols such as isorhamnetin, caffeoyl hexoside, 5-O-caffeoyl shikimic acid isomers, and hydrocaffeic acid [113,114]. Furthermore, p-hydroxybenzoic acid, protocatechuic acid, and coumaric acids were the major phenolic acids reported in the date seed [5,115]. Nevertheless, other studies have showed that the date seed contains hydroxycinnamic acids, flavanols, epicatechin, and catechin [94] (Figure 2). A list of the bioactive phenolic compounds and their natural sources is provided in Table 4. Commercial production of secondary metabolites from the date seed is still limited, primarily due to the limited availability of information on secondary metabolism and its regulation.

8. Date Seed Oil and Its Commercial Application

Date seeds are potentially suitable for daily intake. They contain 4–14% oil, most of which are saturated (lauric, myristic, and palmitic acids) and unsaturated fatty acids (palmitoleic, oleic, linoleic, and linolenic acids) [93]. However, oleic acid occupies the most significant proportion of oils extracted from dates and seeds. Chemically, oleic acid is also known as omega-9 monounsaturated fatty acid and is abbreviated as C18:1, the most common fatty acid in plants [116]. Date seed oil is considered to be an excellent source of oleic acid compared to bran oil [117]. Moreover, date seed oil exists in liquid form at room temperature and has a bright yellow color with a pleasant odor. Seed oil is an edible oil, and, in recent years, it has been viewed as commercially important, owing to its versatile biological constituents and physicochemical properties. Additionally, oil is one of the most important components of date seed and is primarily used in cosmetics. However, date seed contains several medicinal compounds, such as corticosteroids, which can treat kidney and bladder disorders, inflammation, and infectious diseases. Several studies have reported that the date seed shows anti-inflammatory activity [112,115,118].
Moreover, date seed oil contains all phytochemicals, which could be used for many applications such as food product formulations, pharmaceuticals, and cosmetics. Many studies have reported that date seed oil shows antiproliferative activity and significantly reduces oxidative stress [33,119]. Date seed oil has also been used in cosmetic ingredients, specifically in the formulation of photoprotective cream [96]. Moreover, date seed oil reduces cellular and oxidative rancidity, and protects the skin from UV irritation. Ines et al. (2010) showed that date seed oil at concentrations higher than 30 µg/mL did not show any toxicity to human skin [120]. Lecheb and Benamara formulated a cosmetic cream from the aqueous extract of P. dactylifera fruit seed oil, which showed appreciable fluidity, viscosity, and rheological behavior compared to other cosmetics products [121]. Many other experiments concerning the commercial application and the physicochemical and biochemical properties of date seed oil have also been performed [12,17,24,73] (Figure 2).

9. Cosmetic Applications of Date Fruits and Seeds

Date fruits and seeds are considered to have significant nutritive and pharmacological properties. Moreover, they can be used in various cosmetic and beauty products. A lot of cosmetic products contain high amounts of chemical compounds, which are mostly derived synthetics such as hydroquinone [122]. Hammani et al. (2019) reported that activated carbon derived from date stones worked as a catalyst in the reactivity of hydroquinone [123]. In addition, date stones are used in the production of cosmetics. Thus, nanotechnology-based cosmetic products have been attracting consumers; this approach may be used in the design of a new range of cosmetics [124]. The development of nano-based cosmetic delivery vehicles, activated carbon, single-walled nanotubes, and nano-sized vitamin E has been successfully employed in cosmetics [125]. Natural products have recently been used in cosmetics to treat different skin diseases and protect against UV radiation (Figure 3). UV radiation can cause sunburn, wrinkles, premature aging, and cancer; hence, there is a requirement for a permanent solution for protection from UV radiation and the prevention of its side effects.

9.1. Skin Cosmetics

Date fruits and seeds have great potential for protecting the human skin due to the versatile antioxidant activities and anti-inflammatory properties that they possess. Date fruit and seed waste contain bioactive constituents such as flavonoids, phenolics, and phenolic acids, which play a major role in preventing the generation of free radical species that are the main causative agents of skin damage. Although isolated date seed oil has great potential for protecting the skin, date fruit pulp has shown better potential because of its complex composition. Various physical and psychological stressors, poor nutrition, and UV rays affect the human epidermis; however, natural antioxidants can protect the structural proteins of the skin and reduce skin deterioration [126]. Cosmetic products from natural sources have been found to contain many phytoconstituents, and their demand has increased rapidly in recent years [127]. Consumers’ expectations, modern cultural practices, and awareness are geared towards new formulations and safe products [128]. Middle Eastern countries have extensively studied beauty products; however, there is yet a lack of new scientific formulations of cosmetics [129]. Nevertheless, date seed oil has been shown to have a positive effect on human skin and hair, and a few products (body creams, soaps, hair products, and sunscreens) have been commercialized. The seed oil has high oxidative stability, an extended storage capacity, and can protect the skin from UV radiation and repair it [38,130]. Moreover, date seed oil has shown antiwrinkle properties owing to the presence of phytohormones that can reduce wrinkles and improve skin elasticity [131]. Furthermore, the ascorbic acid and vitamin E in the date extract improve the moisture level of the skin by stimulating dermal fibroblasts and increasing collagen levels; they also significantly correlate with anti-aging [132]. A commitment to sustainability has generated interest in plant extract research for applications in environmental development and the creation of high-quality cosmetics. Therefore, the use of phenolic extracts has become a vital alternative to traditional applications. It is important to study and evaluate the risks of raw materials and the final products to confirm the absence of toxicity in these extracts. Ahmed et al. (2015) experimentally demonstrated that the administration of seed extract was safe, and that the seeds can serve as natural antioxidants and increase the consumers’ quality of life [133]. Ines et al. (2010) reported that date seed oil extract is efficient for the prevention of oxidative damage caused by H2O2 [111]. The same study also showed that seed oil might serve as a natural antioxidant, owing to the phenols and tocopherols that it contains. Several studies have shown that phenolic compounds contribute to fruit preservation by protecting against photo-oxidation and providing resistance against microbial and parasitic infections [132,134] (Figure 3). The presence of a phenol core acts as a valuable sensor for reactive species and reduces lipid peroxidation. Interestingly, phenolic derivatives are vital in the cosmetic industry for developing ecofriendly products, especially therapeutic products rich in natural raw materials, and in the prevention of premature skin aging [126]. The phenolic content and antioxidant capacity of dates have been studied extensively in Middle Eastern countries; however, there has been little work carried out on cosmetic formulations to realize the potential benefits of natural ingredients derived from dates in cosmetic creams [135].

9.2. Hair Cosmetics

Hair and nails are sense organs; they can protect sensitive areas from pollution and help to regulate body temperature. Hair loss can occur as a result of lifestyle changes and a general increase in stress and anxiety. These natural stressors may also affect hair growth and damage the hair color in humans. While nutrient-rich foods may prevent oxidative damage caused by external stress and pollution, plant extracts have been used in hair care to promote hair growth and conditioning, act as cleansing and anti-dandruff agents, and prevent hair loss [136]. The bioactive constituents, such as flavonoids and phenolics, can prevent hair loss and promote hair growth. Flavonoids may increase hair length and follicle size and prolong the stage of development [137]. The compounds of low molecular weight can penetrate the hair and improve the mechanical properties of the cortex, while high molecular weight compounds can protect the hair and prevent degradation. Majeed et al. (2020) reported that coconut water increased hair density and growth in male and female volunteers, and reduced itching sensitivity [138]. Coconut water, which contains flavonoid compounds, may protect the hair follicles. Plant-based antioxidant agents, such as hydroxycinnamic derivatives, are used in cosmetic products to protect the skin and improve hair health. Many plant extracts have been used in hair care to promote hair growth and conditioning, act as cleansing and anti-dandruff agents, and prevent hair loss [136]. Additionally, phenolics and procyanidin flavonoid compounds were reported in P. dactylifera date palm seed [47]. Similarly, cinnamic acid derivatives and water- and lipid-soluble vitamins have been reported in different date varieties [139]. Vitamins B and E are recommended to strengthen hair and nails, and are found in many cosmetics and health products for hair. Vitamin E promotes the growth of scalp skin cells and acts as an ideal hair conditioner. Additionally, Vitamin E protects nails from aging and can be used to maintain the moisture level, giving the nails a distinctively healthy appearance [140].

9.3. Nail Cosmetics

Date seed and fruit extracts are good sources of vitamins B, C, and E [141]. Vitamin C protects the hair and nails from free radicals generated from radiation and pollution. Date seed is also used as an ingredient of eye shadows in traditional cosmetics [142]. It also helps to maintain healthy nails by strengthening the skin, connective tissues, and the walls of blood vessels. A recent study shows that the extract from date seed oil is rich in phytosterols, essential fatty acids, and nutrients needed to maintain a healthy scalp, promote normal hair growth, and support the nutritional functions of sebaceous glands and hair follicles [143] (Figure 3). It is important to note that all synthetic skincare products are made with paraben oil, which may cause allergic reactions and rashes on sensitive skin.

9.4. Other Nutricosmetics

Date seed oils are considered safer than parabens and act as natural preservatives in cosmetic products [144]. According to a previous study [109], date seed oil has been shown to have antiviral and anti-inflammatory activities; these properties may protect the skin from inflammation and enhance wound healing [145]. Moreover, date syrup waste (DSW) extract has shown antimicrobial and antioxidant activity, and is currently used in soap manufacturing [146]. Similarly, other studies have reported that date extract containing fluorine could reduce tooth decay [50]. Date seeds have been used as animal feed or soil fertilizers, and have recently been used in many bakery products [2,91]. Therefore, the approach described in this review may present an eco-friendly and cost-effective way to develop organic cosmetic products in the future.

10. Conclusions

This review provides a relevant literature summary of the nutritional and chemical composition of date fruits and seeds and their use as cosmetic ingredients. Previous research findings on their nutraceutical and pharmaceutical benefits revealed that consumption of date fruits and seeds could help to prevent oxidative stress and enhance the anti-inflammatory activities of the body. The development of value-added products and cosmetics can prevent neurodegenerative, metabolic, or skin disorders. A variety of date cultivars have shown to be effective inhibitors of tyrosinase and α-glucosidase. Therefore, it is important to better understand the mechanism of bioactive constituents and purified compounds that may embody these effects. Chemists and biologists have recognized dates and date seed waste as valuable sources for developing drugs and nutraceuticals because they show many benefits to humans. This review highlights the potential use of date fruits and seeds as valuable new value-added products and cosmetic ingredients. Thus, the use of such waste is essential for increasing the income in this sector through date cultivation and in the use of commercial products for the growth of the cosmetic industry.

Author Contributions

K.L.A. was involved in the writing of the original draft, H.-J.S. provided supervision and validation, and J.R. was involved in reviewing and editing. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Foreign Ministry of Higher Education, Technical and Vocational Training Corporation, Saudi Arabia, grant number “1990/88510 on 7/2019”.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The lead author is hereby acknowledged for her research support through the Research Scholarship Programme (No. 1990/88510 on 7/2019) at the Foreign Ministry of Higher Education, Technical and Vocational Training Corporation, Saudi Arabia. The authors thank the Department of Chemical Engineering in the Graduate School of Chosun University, Republic of Korea.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Top 10 date-producing countries (FAOSTAT, 2018 and 2019).
Figure 1. Top 10 date-producing countries (FAOSTAT, 2018 and 2019).
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Figure 2. Bioactive constituents from date fruit and seed.
Figure 2. Bioactive constituents from date fruit and seed.
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Figure 3. Illustration of the cosmetic applications of date fruits and seeds.
Figure 3. Illustration of the cosmetic applications of date fruits and seeds.
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Table 1. Growth stages of Phoenix dactylifera (Medjool) Al-hajjaj and Ayad, 2018 [7].
Table 1. Growth stages of Phoenix dactylifera (Medjool) Al-hajjaj and Ayad, 2018 [7].
Arabic NameStages (Weeks)Fruit Maturity Characters
Hababauk1 to 5The first stage of development after pollination.
Kimry6 to 16Fruit is small, green, and the moisture content is 85%. The weight and the concentration of tannins is high.
Khalal17 to 20Fruit reaches maximum weight, starts to become yellow or red, and becomes rich in sucrose.
Rutab21 to 24Water content is gradually reduced, and the fruit becomes soft, sweet, and dark. Sucrose is converted into reduced sugars, and the protein, ash, and fat content is decreased.
Tamar25 to 27Final stage of maturity; the fruit is sweet, dark brown and wavy.
Table 2. Nutrient compositions of date fruit and seed (* g/100 g; # mg/100 g).
Table 2. Nutrient compositions of date fruit and seed (* g/100 g; # mg/100 g).
ComponentDate FruitDate SeedReferences
Moisture *9.43–21.538.64–12.25[36,40,41]
Protein *1.22–3.304.81–5.84[36,40,41]
Fat *0.11–7.335.71–8.77[36,37,41]
Ash *1.43–6.200.82–1.14[37,40,41]
Carbohydrate *65.7–88.022.43–4.65[37,38,42]
Dietary fiber *1.9–16.9567.56–74.20[36,37,41]
Magnesium #56–15051.7–58.4[43,45]
Calcium #123–18728.9–38.8[43,45]
Phosphorus #12–2783.6–68.3[43,45]
Potassium #289.6–512229–293[43,45]
Sodium #4.9–8.910.25–10.4[43,45]
Iron #0.3–2.22.30–2.21[43]
Table 3. Value-added food and cosmetic products from date fruits and seeds.
Table 3. Value-added food and cosmetic products from date fruits and seeds.
TypeSourceProducts and ApplicationReferences
Date fruitFruit fiberMuffins—increases total dietary fiber and ash content, improves antioxidant levels[51,61]
Syrup and powders Dairy desserts—natural thickening agent, improves apparent viscosity and antioxidant activities[62]
Syrup (10%)Yogurt—increases sweetness and antioxidant value, high mineral and folate concentrations[63]
Fermented fruit pureeFunctional dietary supplement—increases concentrations of γ-amino butyric acid, conjugated fatty acids, and insoluble dietary fibers[58]
PastePork liver pâté—lowers lipid oxidation and enhances sensory acceptability[64]
Pulp powderBread—increases dietary fiber content[65]
Discarded fruitsHigh-fructose syrup[66]
Immature fruitsDate juice concentrate[67]
Wine Wine[71]
Date seed (pit)PowderPit bread—contains high amounts of phenolics and increased antioxidant activities[69]
Powder (defatted)Bread—increases dietary fiber content[70,71]
ExtractMayonnaise—ensures high oxidative stability and sensory acceptability[72]
ExtractOxidative stability of ground beef—increases total polyphenol content and antioxidant activity and lowers TBARS value[73]
PowderUsed as coffee substitute[59]
OilUsed in ooking, pharmaceutical, and cosmetic applications [51]
Date fruit and seedFatty acid and oilUsed in soap and cosmetic products [74]
Table 4. List of phenolic acids derived from date fruit and seed and their cosmetic applications.
Table 4. List of phenolic acids derived from date fruit and seed and their cosmetic applications.
ComponentsSource and BioactivityReferences
Gallic acidFruit and Seed. Antibacterial and antioxidant. Thermally fluctuating, Galloyl-RGD (linked with a peptide) used as cosmetic ingredient.[81,90,103]
Vanillic acidFruit and seed. Skin lightening and reducing pigmentation.[47,81,90,91]
Protocatechuic acidFruit and Seed. Reduces skin aging process.[81,90,92]
p-Hydroxybenzoic acidFruit and Seed. Increases the shelf life of cosmetics.[83,90,93]
Syringic acidSeed. Fragrance ingredient and surfactant-emulsifying, surfactant-cleansing tool, skin penetration enhancer.[82,94]
Pelargonic acidFruit and Seed. Thermally fluctuating, Galloyl-RGD used as cosmetic ingredient.[81,90]
Syringic acidFruit and Seed. Anti-aging, antioxidant, and works as natural phytochemical in cosmetic products.[90,94]
Cinnamic acidFruit and Seed. UV stabilizer, antioxidant, and antimicrobial agent.[83,90,95]
Caffeic AcidFruit and Seed. Antioxidant.[90,96]
Ferulic acidFruit and Seed. Antioxidant, decreases melanogenesis, improves angiogenesis and stimulates wound healing, delays photoaging and promotes skin tone.[90,97]
CatechinFruit and Seed. Improves collagen arrangement, binding agent.[81,98,99,101]
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Alharbi, K.L.; Raman, J.; Shin, H.-J. Date Fruit and Seed in Nutricosmetics. Cosmetics 2021, 8, 59. https://0-doi-org.brum.beds.ac.uk/10.3390/cosmetics8030059

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Alharbi KL, Raman J, Shin H-J. Date Fruit and Seed in Nutricosmetics. Cosmetics. 2021; 8(3):59. https://0-doi-org.brum.beds.ac.uk/10.3390/cosmetics8030059

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Alharbi, Khlood Lafi, Jegadeesh Raman, and Hyun-Jae Shin. 2021. "Date Fruit and Seed in Nutricosmetics" Cosmetics 8, no. 3: 59. https://0-doi-org.brum.beds.ac.uk/10.3390/cosmetics8030059

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