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2024 Volume 4
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Exploring the potential application of coconut water in healthcare and biotechnology: a review

  • # Authors contributed equally: Zhihua Mu, Binh-Minh Tran, Hang Xu

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  • Coconut (Coconut Nucifera L.) is one of the most important palms worldwide. Coconut water, its liquid endosperm, is a nutrient-rich beverage with a wide range of potential applications as a refreshing beverage, medicine and additives in biotechnology. It is a sterile, isotonic solution containing a variety of sugars, amino acids, vitamins, minerals, and phytohormones which showed a range of biological activities, including antioxidant, antimicrobial, anti-inflammatory, and immunomodulatory effects. It also provided a wide range of secondary metabolites. Coconut water has been used successfully for the tissue culture of many plants, including field crops, ornamentals, and medicinal plants. In this review, we have discussed, the chemical composition and biological properties of coconut water, as well as its potential applications in biotechnology and medicine. It was found that coconut water has therapeutic or preventive effects against many diseases, or has applications in medicine. In addition, in biotechnology such as plant tissue culture, coconut water can be used as an additive to enhance the growth of callus tissue. This review will also highlight the challenges and opportunities for future research on coconut water.
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  • [1]

    Kaur K, Chhikara N, Sharma P, Garg MK, Panghal A. 2019. Coconut meal: Nutraceutical importance and food industry application. Foods and Raw materials 7:419−27

    doi: 10.21603/2308-4057-2019-2-419-427

    CrossRef   Google Scholar

    [2]

    Salum U, Foale M, Biddle J, Bazrafshan A, Adkins S. 2020. Towards the sustainability of the "tree of life": An introduction. In Coconut Biotechnology: Towards the Sustainability of the 'Tree of Life', eds. Adkins S, Foale M, Bourdeix R, Nguyen Q, Biddle J. Cham: Springer. https://doi.org/10.1007/978-3-030-44988-9_1

    [3]

    Ahuja S, Ahuja U, Ahuja S. 2014. Coconut − history, uses, and folklore. Asian Agri-History 18:221−48

    Google Scholar

    [4]

    Zulaikhah ST. 2019. Health benefits of tender coconut water (TCW). International Journal of Pharmaceutical Sciences Research 10:474−80

    Google Scholar

    [5]

    Caladcad JA, Cabahug S, Catamco MR, Villaceran PE, Cosgafa L, et al. 2020. Determining Philippine coconut maturity level using machine learning algorithms based on acoustic signal. Computers and Electronics in Agriculture 172:105327

    doi: 10.1016/j.compag.2020.105327

    CrossRef   Google Scholar

    [6]

    Balasubramaniam K, Atukorala T, Wijesundera S, Hoover AA, De Silva MAT. 1973. Biochemical changes during germination of the coconut (Cocos nucifera). Annals of Botany 37:439−45

    doi: 10.1093/oxfordjournals.aob.a084710

    CrossRef   Google Scholar

    [7]

    Kumar M, Saini SS, Agrawal PK, Roy P, Sircar D. 2021. Nutritional and metabolomics characterization of the coconut water at different nut developmental stages. Journal of Food Composition and Analysis 96:103738

    doi: 10.1016/j.jfca.2020.103738

    CrossRef   Google Scholar

    [8]

    Tuyekar SN, Tawade BS, Singh KS, Wagh VS, Vidhate PK, et al. 2021. An overview on coconut water: as a multipurpose nutrition. Int. J. Pharm. Sci. Rev. Res 68(2):63−70

    doi: 10.47583/ijpsrr.2021.v68i02.010

    CrossRef   Google Scholar

    [9]

    Lemos IDML, Aniceto A, Teodoro AJ. 2023. Coconut water: production, nutritional properties and health benefits. Observató Rio De La Economí A Latinoamericana 21:971−93

    doi: 10.55905/oelv21n2-021

    CrossRef   Google Scholar

    [10]

    Prades A, Dornier M, Diop N, Pain JP. 2012. Coconut water uses, composition and properties: a review. Fruits 67:87−107

    doi: 10.1051/fruits/2012002

    CrossRef   Google Scholar

    [11]

    Medeiros AC, de Paiva VdFL. 2012. Therapeutic use of coconut water. Journal of Surgical and Clinical Research 3:83−91

    doi: 10.20398/jscr.v3i2.3570

    CrossRef   Google Scholar

    [12]

    Costa JR, Monteiro MJ, Tonon RV, Cabral LM, Pastrana L, et al. 2021. Fortification of coconut water with microencapsulated grape pomace extract towards a novel electrolyte beverage: Biological, sensorial and quality aspects. Future Foods 4:100079

    doi: 10.1016/j.fufo.2021.100079

    CrossRef   Google Scholar

    [13]

    Rethinam P, Krishnakumar V. 2022. Value addition in coconut water. In Coconut Water: A Promising Natural Health Drink-Distribution, Processing and Nutritional Benefits. Cham: Springer. pp. 287-384. https://doi.org/10.1007/978-3-031-10713-9_8

    [14]

    Segura-Badilla O, Lazcano-Hernández M, Kammar-García A, Vera-López O, Aguilar-Alonso P, et al. 2020. Use of coconut water (Cocus nucifera L.) for the development of a symbiotic functional drink. Heliyon 6:E03653

    doi: 10.1016/j.heliyon.2020.e03653

    CrossRef   Google Scholar

    [15]

    Li X. 2023. A study on the linguistic landscape of catering store names in Haikou — taking the four main urban districts of Haikou city as an example. Modern Linguistics 11(5):2025

    doi: 10.12677/ML.2023.115275

    CrossRef   Google Scholar

    [16]

    Foale M. 2003. The coconut odyssey: the bounteous possibilities of the tree of life. Australia: Australian Centre for International Agricultural Research

    [17]

    Camargo Prado F, De Dea Lindner J, Inaba J, Thomaz-Soccol V, Kaur Brar S, et al. 2015. Development and evaluation of a fermented coconut water beverage with potential health benefits. Journal of Functional Foods 12:489−97

    doi: 10.1016/j.jff.2014.12.020

    CrossRef   Google Scholar

    [18]

    Burns DT, Johnston EL, Walker MJ. 2020. Authenticity and the potability of coconut water-a critical review. Journal of AOAC International 103:800−06

    doi: 10.1093/jaocint/qsz008

    CrossRef   Google Scholar

    [19]

    Cunha AG, Alves Filho EG, Silva LMA, Ribeiro PRV, Rodrigues THS, et al. 2020. Chemical composition of thermally processed coconut water evaluated by GC–MS, UPLC–HRMS, and NMR. Food Chemistry 324:126874

    doi: 10.1016/j.foodchem.2020.126874

    CrossRef   Google Scholar

    [20]

    Pradera ES, Fernandez E, Calderin O. 1942. Coconut water: a clinical and experimental study. American Journal of Diseases of Children 64:977−95

    doi: 10.1001/archpedi.1942.02010120017002

    CrossRef   Google Scholar

    [21]

    Ismail I, Singh R, Sirisinghe RG. 2007. Rehydration with sodium-enriched coconut water after exercise-induced dehydration. Southeast Asian journal of tropical medicine and public health 38:769−85

    Google Scholar

    [22]

    Yong JWH, Ge L, Ng YF, Tan SN. 2009. The chemical composition and biological properties of coconut (Cocos nucifera L.) water. Molecules 14:5144−64

    doi: 10.3390/molecules14125144

    CrossRef   Google Scholar

    [23]

    Naik M, Sunil CK, Rawson A, Venkatachalapathy N. 2022. Tender coconut water: A review on recent advances in processing and preservation. Food Reviews International 38:1215−36

    doi: 10.1080/87559129.2020.1785489

    CrossRef   Google Scholar

    [24]

    Shubhashree M, Venkateshwarlu G, Doddamani S. 2014. Therapeutic and nutritional values of Narikelodaka (tender coconut water) - A review. Research Journal of Pharmacognosy and Phytochemistry 6:195

    Google Scholar

    [25]

    DebMandal M, Mandal S. 2011. Coconut (Cocos nucifera L.: Arecaceae): in health promotion and disease prevention. Asian Pacific Journal of Tropical Medicine 4:241−47

    doi: 10.1016/S1995-7645(11)60078-3

    CrossRef   Google Scholar

    [26]

    Ediriweera ERHSS. 2003. Medicinal uses of coconut (Cocos nucifera LINN). Cocoinfo Int 10:11−21

    Google Scholar

    [27]

    Rethinam P, Nanda Kumar T. 2001. Tender coconut - an overview. Indian Coconut Journal 32:2−22

    Google Scholar

    [28]

    Joseph D, George J, Mathews MM, Mathew F, Varghese B, et al. 2019. A compilation on anti-diabetic profile of Cocos nucifera. Research Journal of Pharmacy and Technology 12:3791−96

    doi: 10.5958/0974-360X.2019.00649.8

    CrossRef   Google Scholar

    [29]

    Jackson JC, Gordon A, Wizzard G, McCook K, Rolle R. 2004. Changes in chemical composition of coconut (Cocos nucifera) water during maturation of the fruit. Journal of the Science of Food and Agriculture 84:1049−52

    doi: 10.1002/jsfa.1783

    CrossRef   Google Scholar

    [30]

    Alleyne T, Roache S, Thomas C, Shirley A. 2005. The control of hypertension by use of coconut water and mauby: two tropical food drinks. The West Indian Medical Journal 54:3−8

    doi: 10.1590/s0043-31442005000100002

    CrossRef   Google Scholar

    [31]

    Brasileiro LS, Segabinazzi LGTM, Menezes E, Salgueiro CC, Novello G, et al. 2019. Coconut water as an extender component for cooled equine sperm. Journal of equine veterinary science 78:69−73

    doi: 10.1016/j.jevs.2019.03.213

    CrossRef   Google Scholar

    [32]

    Jimoh OA. 2020. Potential of coconut water to enhance fresh semen quality and fertility in rabbits. Tropical animal health and production 52:249−55

    doi: 10.1007/s11250-019-02011-z

    CrossRef   Google Scholar

    [33]

    Anaya K, Podszun M, Franco OL, de Almeida Gadelha CA, Frank J. 2020. The coconut water antimicrobial peptide CnAMP1 is taken up into intestinal cells but does not alter p-glycoprotein expression and activity. Plant Foods for Human Nutrition 75:396−403

    doi: 10.1007/s11130-020-00826-y

    CrossRef   Google Scholar

    [34]

    Suryani S, Purnawati Y, Gemaeka Putri S, Rahmawati R, Akbar Y, et al. 2022. Novel probiotic isolation of coconut water's helpful lactic acid bacteria cure Covid-19 patients. ARRUS Journal of Engineering and Technology 2:1−11

    doi: 10.35877/jetech724

    CrossRef   Google Scholar

    [35]

    Preetha PP, Girija Devi V, Rajamohan T. 2013. Comparative effects of mature coconut water (Cocos nucifera) and glibenclamide on some biochemical parameters in alloxan induced diabetic rats. Revista Brasileira de Farmacognosia 23:481−87

    doi: 10.1590/S0102-695X2013005000027

    CrossRef   Google Scholar

    [36]

    Prathapan A, Rajamohan T. 2011. Antioxidant and antithrombotic activity of tender coconut water in experimental myocardial infarction. Journal of Food Biochemistry 35:1501−7

    doi: 10.1111/j.1745-4514.2010.00471.x

    CrossRef   Google Scholar

    [37]

    Effiong G, Ebong P, Eyong E, Uwah A, Ekong U. 2010. Amelioration of chloramphenicol induced toxicity in rats by coconut water. Journal of Applied Sciences Research 6:331−35

    Google Scholar

    [38]

    Loki AL, Rajamohan T. 2003. Hepatoprotective and antioxidant effect of tender coconut water on carbon tetrachloride induced liver injury in rats. Indian Journal of Biochemistry & Biophysics 40:354−57

    [39]

    Bankar GR, Nayak PG, Bansal P, Paul P, Pai KSR, et al. 2011. Vasorelaxant and antihypertensive effect of Cocos nucifera Linn. endocarp on isolated rat thoracic aorta and DOCA salt-induced hypertensive rats. Journal of Ethnopharmacology 134:50−54

    doi: 10.1016/j.jep.2010.11.047

    CrossRef   Google Scholar

    [40]

    Zulaikhah ST, Wahyuwibowo J. 2019. Effect of tender coconut water to prevent Anemia on Wistar Rats Induced by Lead (Plumbum). Pharmacognosy Journal 11:1325−30

    doi: 10.5530/pj.2019.11.204

    CrossRef   Google Scholar

    [41]

    Zhang X, Peng L, Dai Y, Sheng X, Chen S, et al. 2020. Effects of coconut water on retina in diabetic rats. Evidence-Based Complementary and Alternative Medicine 2020:9450634

    doi: 10.1155/2020/9450634

    CrossRef   Google Scholar

    [42]

    Mohamad NE, Yeap SK, Abu N, Lim KL, Zamberi NR, et al. 2019. In vitro and in vivo antitumour effects of coconut water vinegar on 4T1 breast cancer cells. Food & Nutrition Research 63:1616

    doi: 10.29219/fnr.v63.1616

    CrossRef   Google Scholar

    [43]

    Gandhi M, Aggarwal M, Puri S, Singla S. 2013. Prophylactic effect of coconut water (Cocos nucifera L.) on ethylene glycol induced nephrocalcinosis in male wistar rat. International Brazilian Journal of Urology 39:108−17

    doi: 10.1590/S1677-5538.IBJU.2013.01.14

    CrossRef   Google Scholar

    [44]

    Van Overbeek J, Conklin ME, Blakeslee AF. 1942. Cultivation in vitro of small Datura embryos. American Journal of Botany 29:472−77

    doi: 10.2307/2437313

    CrossRef   Google Scholar

    [45]

    Liu JR, Cantliffe DJ. 1984. Somatic embryogenesis and plant regeneration in tissue cultures of sweet potato (Ipomea batatas Poir.). Plant Cell Reports 3:112−15

    doi: 10.1007/BF02441013

    CrossRef   Google Scholar

    [46]

    Binh LT, Muoi LT, Oanh HTK, Thang TD, Phong DT. 1990. Rapid propagation of agave by in vitro tissue culture. Plant Cell, Tissue and Organ Culture 23:67−70

    doi: 10.1007/BF00116091

    CrossRef   Google Scholar

    [47]

    Murashige T, Skoog F. 1962. A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum 15:473−97

    doi: 10.1111/j.1399-3054.1962.tb08052.x

    CrossRef   Google Scholar

    [48]

    Gamborg OL, Miller RA, Ojima K. 1968. Nutrient requirements of suspension cultures of soybean root cells. Experimental Cell Research 50:151−58

    doi: 10.1016/0014-4827(68)90403-5

    CrossRef   Google Scholar

    [49]

    Reyes Estévez E. 2021. Why coconut water is both a biostimulant and an anti-cancer agent. Horticultural Science programme, Swedish University of Agricultural Sciences. https://stud.jpgilon.slu.se/16482/3/reyes_estevez_e_210226.pdf

    [50]

    Sarathchandra T, Upali P, Wijewardena R. 1988. Studies on the tissue culture of tea (Camellia sinensis (L.) O. Kuntze) 4 somatic embryogenesis in stem and leaf callus cultures. Sri Lanka Journal of Tea Science 57(2):50−54

    Google Scholar

    [51]

    Ajie WKB, Malinda R, Yuniastuti E, Yunus A. 2019. In vitro micropropagation of Raja Bulu banana in medium supplemented with coconut water and NAA. Proc. IOP Conference Series: Earth and Environmental Science 250:012014

    doi: 10.1088/1755-1315/250/1/012014

    CrossRef   Google Scholar

    [52]

    Mythili JB, Rajeev PR, Vinay G, Nayeem A. 2017. Synergistic effect of silver nitrate and coconut water on shoot differentiation and plant regeneration from cultured cotyledons of Capsicum annuum L. Indian Journal of Experimental Biology 55:184−90

    Google Scholar

    [53]

    Al-Khayri JM, Huang FH, Morelock TE, Busharar TA. 1992. Spinach tissue culture improved with coconut water. HortScience 27:357−58

    doi: 10.21273/HORTSCI.27.4.357

    CrossRef   Google Scholar

    [54]

    Afroz A, Chaudhry Z, Rashid U, Khan MR, Ali GM. 2010. Enhanced regeneration in explants of tomato (Lycopersicon esculentum L.) with the treatment of coconut water. African Journal of Biotech nology 9:3634−44

    Google Scholar

    [55]

    Al-Khayri JM. 2010. Somatic embryogenesis of date palm (Phoenix dactylifera L.) improved by coconut water. Biotechnology 9:477−84

    doi: 10.3923/biotech.2010.477.484

    CrossRef   Google Scholar

    [56]

    Agbidinoukoun A, Somakpe E, Houngue J, Houedjissin S, Ahanhanzo C. 2022. Response of haustorium tissues and coconut water in somatic embryos induction for the coconut palm (Cocos nucifera L.) variety PB121. Journal of Advances in Biotechnology 10:6−14

    doi: 10.24297/jbt.v10i.9195

    CrossRef   Google Scholar

    [57]

    Rafique A, Afroz A, Zeeshan N. 2022. Enhanced in-vitro embryogenesis and multiple shoot regeneration of wheat local cvs (Triticum aestivum L.) with coconut water. Journal of Xi'an Shiyou University (Natural Science Edition) 18:251−59

    Google Scholar

    [58]

    Ma Z, Ge L, Lee ASY, Yong JWH, Tan SN, et al. 2008. Simultaneous analysis of different classes of phytohormones in coconut (Cocos nucifera L.) water using high-performance liquid chromatography and liquid chromatography–tandem mass spectrometry after solid-phase extraction. Analytica chimica acta 610:274−81

    doi: 10.1016/j.aca.2008.01.045

    CrossRef   Google Scholar

    [59]

    del Socorro Santos-Díaz M, Elizalde-Rodríguez C, de Lourdes Santos-Díaz M. 2006. Effect of coconut water, darkness and auxins on morphogenesis of Ariocarpus kotschoubeyanus (Cactaceae). Bradleya 2006:83−88

    doi: 10.25223/brad.n24.2006.a8

    CrossRef   Google Scholar

    [60]

    Prando MAS, Chiavazza P, Faggio A, Contessa C. 2014. Effect of coconut water and growth regulator supplements on in vitro propagation of Corylus avellana L. Scientia Horticulturae 171:91−94

    doi: 10.1016/j.scienta.2014.03.052

    CrossRef   Google Scholar

    [61]

    Sembiring R, Hayati M, Kesumawti E. 2021. Potato tuber (Solanum tuberosum L.) formation due to the application of different concentrations of coconut water in in-vitro. IOP Conference Series: Earth and Environmental Science 711:012021

    doi: 10.1088/1755-1315/711/1/012021

    CrossRef   Google Scholar

    [62]

    Kim HJ, Choi MJ, Lee JN, Suh JT, Kim KD, et al. 2020. Improvement of proliferation efficiency of strawberry 'Maehyang'treated by coconut water in tissue culture. Journal of Plant Biotechnology 47:242−47

    doi: 10.5010/JPB.2020.47.3.242

    CrossRef   Google Scholar

    [63]

    Nasib A, Ali K, Khan S. 2008. An optimized and improved method for the in vitro propagation of kiwifruit (Actinidia deliciosa) using coconut water. Pakistan Journal of Botany 40:2355−60

    Google Scholar

    [64]

    Mohammad S, Ali M. 2010. Effect of coconut water on callus growth on Cyamopsis tetragonolobust. Pharmacia 1:25−27

    Google Scholar

    [65]

    Mondal S, Ahirwar MK, Singh MK, Singh R. 2015. Effect of coconut water and ascorbic acid on shoot regeneration in banana variety dwarf Cavendish. The Asian Journal of Horticulture 1:65−69

    doi: 10.5555/20133276823

    CrossRef   Google Scholar

    [66]

    Insani H, Harahap F, Setya Diningrat D. 2018. The effect of coconut water and Benzyl Amino Purine (BAP) addition to the growth of pineapple from Sipahutar North Sumatera in vitro condition. International Journal of Biological Research 6:29−33

    doi: 10.14419/ijbr.v6i2.13697

    CrossRef   Google Scholar

    [67]

    Khatun MM, Roy PK, Razzak MA. 2018. Additive effect of coconut water with various hormones on in vitro regeneration of carnation (Dianthus caryophyllus L.). The Journal of Animal & Plant Sciences 28:589−96

    Google Scholar

    [68]

    Souza RAVd, Braga FT, Setotaw TA, Vieira Neto J, Azevedo PHd, et al. 2013. Effect of coconut water on growth of olive embryos cultured in vitro. Rural Science 43:290−96

    Google Scholar

    [69]

    Inpeuy K, Chaemalee S, Te-chato S. 2011. Cytokinins and coconut water promoted abnormalities in zygotic embryo culture of oil palm. Songklanakarin Journal of Science and Technology 33:653

    Google Scholar

    [70]

    Quynh TP. 2019. Effect of activated charcoal and coconut water on in vitro growth of coconut (Cocos nucifera L.) zygotic embryos. Thesis. International University-Ho Chi Minh, Ho Chi Minh City, Vietnam. http://keep.hcmiu.edu.vn:8080/handle/123456789/3930

    [71]

    Lui XJ, Sriskanda D, Ling WT, Subramaniam S, Chew BL. 2022. The incorporation of coconut water and banana homogenate in the regeneration of fig (Ficus carica L.) cv. Violette de Solliès. Malaysian Applied Biology 51:13−22

    doi: 10.55230/mabjournal.v51i5.2327

    CrossRef   Google Scholar

    [72]

    Muhammad K, Gul Z, Jamal Z, Ahmed M, Khan A, Khan Z. 2015. Effect of coconut water from different fruit maturity stages, as natural substitute for synthetic PGR in in vitro potato micropropagation. International Journal of Biosciences 6:84−92

    doi: 10.12692/ijb/6.2.84-92

    CrossRef   Google Scholar

  • Cite this article

    Mu Z, Tran BM, Xu H, Yang Z, Qamar UZ, et al. 2024. Exploring the potential application of coconut water in healthcare and biotechnology: a review. Beverage Plant Research 4: e018 doi: 10.48130/bpr-0024-0009
    Mu Z, Tran BM, Xu H, Yang Z, Qamar UZ, et al. 2024. Exploring the potential application of coconut water in healthcare and biotechnology: a review. Beverage Plant Research 4: e018 doi: 10.48130/bpr-0024-0009

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REVIEW   Open Access    

Exploring the potential application of coconut water in healthcare and biotechnology: a review

Beverage Plant Research  4 Article number: e018  (2024)  |  Cite this article

Abstract: Coconut (Coconut Nucifera L.) is one of the most important palms worldwide. Coconut water, its liquid endosperm, is a nutrient-rich beverage with a wide range of potential applications as a refreshing beverage, medicine and additives in biotechnology. It is a sterile, isotonic solution containing a variety of sugars, amino acids, vitamins, minerals, and phytohormones which showed a range of biological activities, including antioxidant, antimicrobial, anti-inflammatory, and immunomodulatory effects. It also provided a wide range of secondary metabolites. Coconut water has been used successfully for the tissue culture of many plants, including field crops, ornamentals, and medicinal plants. In this review, we have discussed, the chemical composition and biological properties of coconut water, as well as its potential applications in biotechnology and medicine. It was found that coconut water has therapeutic or preventive effects against many diseases, or has applications in medicine. In addition, in biotechnology such as plant tissue culture, coconut water can be used as an additive to enhance the growth of callus tissue. This review will also highlight the challenges and opportunities for future research on coconut water.

    • Coconut (Cocos Nucifera L.) is one of the most symbolic species in tropical regions, holding significant economic and cultural importance[1]. Due to its versatile applications, it is often referred to as the 'tree of life'. Undoubtedly, one of the key factors that make coconuts so alluring is coconut water[2]. The coconut tree is a symbol representing life and fertility, as it thrives in harsh conditions and continues to yield[3]. As one of the most vital products of the coconut tree, coconut water is regarded as the source of life and a sacred gift. Coconut water, derived from the liquid endosperm of the coconut fruit, it emerges when the fruit is approximately five months old, and it reaches its peak for consumption at around 18 months[4]. At this stage, the coconut water volume is at its maximum, and its sweetness is notably elevated. As the coconut fruit matures, the sensory characteristics of the coconut water undergo changes, its volume reduces gradually, and transforms into solid endosperm (coconut meat)[5]. During coconut germination, the array of nutrients present in coconut water and meat provides the required energy, nutrition, and moisture for sprouting coconuts, while also maintaining a stable internal environment to ensure favorable conditions for coconut survival[6]. When the fruit reaches full maturity at around 12 months, the coconut water acquires a mild carbonated beverage-like flavor[7]. Coconut water also serves as a rich source of antioxidants, electrolytes, and nutrients, comprising a variety of vital nutritional elements, such as vitamins, minerals (potassium, phosphorus, magnesium, calcium), amino acids, glucose, fructose, among others[8]. Consequently, coconut water not only fulfills the roles of hydration and quenching thirst but also contributes to the maintenance of electrolyte balance, reduction of high blood pressure and cardiovascular diseases, defense against free radical damage, and acceleration of food digestion[9]. Current reviews on coconut water have predominantly focused on its applications as a beverage and food additive. Coconut water is indispensable in these areas but its application in other fields is often neglected, as coconut water also finds extensive applications in biotechnology and the health industry. In this review, our main focus has been on the applications of coconut water in the medical and biotechnology fields. This review can provide a comprehensive overview of the existing research, including the potential applications of coconut water in biotechnology and healthcare. This review paper will also highlight gaps in existing research where further investigation is needed. This consolidated information can serve as a valuable resource for coconut industry stakeholders.

    • As a significant beverage and cultural symbol in the tropical world, coconut water holds a great importance in many countries. Coconut water provides refreshment and nutrition to humans in a pure, additive-free manner. It earned global popularity and is known as a natural health drink[10]. Its lower calorie and sugar content have gradually positioned it as an alternative to sugary beverages and other traditional drinks[11]. Coconut water contains various electrolytes such as potassium, sodium, calcium, and magnesium, which assist the body in reestablishing hydration and electrolyte balance[12]. Therefore, whether facing scorching heat or intense workouts, coconut water's rapid electrolyte and hydration replenishment combats dehydration and fatigue[4].

      The importance of coconut water extends beyond its function as a beverage. Coconut water finds its role as a food addictive in culinary endeavors, cocktails, and desserts[13]. Its fresh taste and subtle sweetness enhance the flavors of food and beverages. People utilize coconut water to craft several types of juices, alcoholic concoctions, pastries, imparting a distinctive coconut essence[14], with the Hainanese 'Qing Bu Liang' standing out as an exceptional example[15].

      Furthermore, coconut water bears significant cultural symbolism. In certain regions' traditional cultures, coconut water frequently assumes a prominent role in celebrations, rituals, blessings, and festive occasions[16]. Whether in tropical regions or elsewhere, coconut water has become an integral part of people's pursuit of a healthy lifestyle. With the increasing emphasis on health and natural foods, coconut water continues to attract more attention and appreciation. As coconut water gains popularity in the global market, various processing facilities have employed multiple methods to extract and package coconut water, allowing for long-distance transportation to satisfy people's cravings worldwide[17].

    • Coconut water is comprised of sugars, minerals, vitamins, amino acids, enzymes, volatile aromatic compounds, and various biochemical compounds. The makeup of fresh coconut water is influenced by several factors such as the cultivation region, affecting soil, environmental conditions, and fertilizer usage, as well as the coconut variety, cultivar, and the harvesting stage's maturity[18]. Various analytical techniques have been employed to study the components of coconut water for different purposes, such as examining quality changes during diverse sterilization processes. These techniques include nuclear magnetic resonance (NMR), gas chromatography (GC), and High-Performance Liquid Chromatography (HPLC) coupled with mass spectrometry (MS)[19]. The biochemical structure of coconut water is affected by the stage of maturity and hence the variety[20]. Necessary contents in coconut water which are beneficial for human beings are listed in Table 1.

      Table 1.  Nutritional components in coconut water.

      NutrientBenefitsReference
      Electrolytes (potassium, sodium, magnesium, and calcium)Help regulate fluid balance and muscle function[21]
      Vitamins (C, B1, B2, B3, B5, B6, B9, and B12)Essential for overall health and well-being[22]
      Minerals (iron, manganese, copper, and zinc)Play important roles in metabolism, immunity, and other bodily functions[10]
      Amino acidsBuilding blocks of proteins[7]
      EnzymesHelp with digestion and other metabolic processes[23]
      AntioxidantsProtect cells from damage[4]

      Tender Coconut Water (TCW) is called the 'fluid of life'. It is a highly nutritious beverage derived from palm trees, serving as a natural isotonic drink with similar osmotic pressures closely resembling our body's blood plasma[4]. The rich array of macro and micro nutrients in tender coconut water has the potential to reduce lipid levels and provide protective benefits to both the heart and liver[24]. It has been used worldwide to treat oral rehydration, childhood illnesses, intestinal flu, and cholera[8]. Coconut has been used in traditional Indian medicine for thousands of years to treat a variety of ailments, such as gonorrhea, bronchitis, fever and gingivitis[25]. Ayurvedic medicine (antient India) describes coconut as medicine that increases semen, promotes digestion, and clears the urinary path[26]. In Sri Lanka, where coconut is a staple food, there are many references to its medicinal uses[27]. Coconut water is a better choice than plain water or fruit drinks at relieving symptoms of diseases that cause dehydration[10]. It has a great impact to the health of human race and animals; the beginning of these research was started in 1942. This early research indicated that the biological value of coconut water was determined by proteins, amino acids. Also, the medical application of coconut water, for example, the feasibility of parenteral injection of coconut water and the applications in pediatrics (feeding infants)[20]. Coconut water has been widely used over the past few decades to treat infectious diseases, dysentery, influenza, and other diseases that cause dehydration[10], as listed in Table 2. Most of the experiments were conducted using rats but those positive results clearly indicated the future perspective. Recently, in-vivo and in-vitro research showed that coconut water has the potential to lower blood sugar levels, similar to standard oral diabetes medications. Coconut water could have a significant impact on the treatment of diabetes[28]. Nursing mothers who regularly drink coconut water can help baby's uptake calcium. Coconut water also contains vitamin-C, vitamins-B and B9[10]. The amount of vitamin-C in coconut water decreases as the coconut matures. Vitamin-B9 is important for preventing anemia in pregnancy and mitochondrial toxicity caused by methanol metabolites[29]. Furthermore, coconut water has antioxidant properties, and a mixture of coconut water and mauby bark syrup from Trinidad and Tobago has been shown to reduce hypertension in humans[30]. Coconut water was used as the sperm extender of equine sperm[31] and rabbit sperm[32], which ensures a high pregnancy percentage, and large, healthy litters. Coconut antimicrobial peptide-1, abbreviated as CnAMP1, is classified as an antimicrobial peptide, which is naturally present in green coconut[24]. Antimicrobial peptides are compact proteins that constitute a component of the innate immune system found in various organisms, including plants. Their primary function involves protecting the organism against microbial infections[33]. Interestingly, scientists from Indonesia found that isolated probiotics from coconut water, which could potentially contribute to the recovery of Covid-19 patients. This study suggests that coconut water may have a role in assisting Covid patients[34].

      Table 2.  Clinical applications of coconut water.

      Objects Induction method/dose Result Reference
      Male Sprague-Dawley rats Mature coconut water; 1,000 mg/kg 53.14% reduction of blood glucose level [35]
      Male albino rats (Sprague-Dawley) Tender coconut water (TCW),
      4 mL/100 g/day
      Significantly reduced the oxidative stress induced by isoproterenol and exerted significant antithrombotic effects. [36]
      Male Wistar rats TCW from West African Tall coconut,
      20 ml/kg body weight
      Coconut water reduced the toxicity of chloramphenicol by increasing enzyme level [37]
      Carbon tetrachloride (CCl4)-intoxicated female rats TCW, 2−6 mL/kg TCW significantly lowered the generation of free radical. [38]
      Male Wistar rats Coconut endocarp (CNE), 3.33 mg CNE graetly reduced the systolic blood pressure in rats (from 185 to 145 mmHg). [39]
      White Wistar male rats TCW, 8 mL/200 gr BW rats/day TCW can elevate hematocrit, hemoglobin and erythrocyte levels in rats. [40]
      Adult male Sprague-Dawley rats Coconut water, Intraperitoneal
      injection of (60 mg/kg).
      Coconut water can be protective against diabetic retinopathy by decreasing oxidative stress and anti-inflammatory activities in the retina. [41]
      Mouse breast cancer cell line (4T1) Coconut water and vinegars,
      2.00 mL/kg
      Coconut water vinegar slower the spread of breast cancer by killing cancer cells, and boosting the immune system. [42]
      Male Wistar rats Coconut water, Normal rat diet +
      0.75% EG + 10% Coconut water
      Coconut water prevented kidney stones by stopping crystals from forming and reducing urine crystals. It also protected the kidney damage and prevented oxidative stress caused by free radicals. [43]
      Healthy physically active male Coconut water enriched with sodium (SCW), 3,000 ml/trial SCW did not cause nausea and stomach upset. Coconut is a great alternative to commercial sports drinks for rehydrating. [21]
      COVID-19 patient Lactic acid bacteria from coconut water Extracted probiotics from coconut water, which could potentially contribute to the recovery of Covid-19 patients. [34]
    • Coconut water is a liquid endosperm that provides suitable nutrients and bio-stimulants for the formation, development, and later germination of coconut zygotic embryo. Due to the natural ability to regulate the growth of plant tissue, this special form of endosperm has high potential for the application in plant tissue culture as an additional supplement to promote morphogenesis and rapid proliferation of plant cells and tissues as Fig. 1 indicated.

      Figure 1. 

      Major bioactive compositions in coconut water and their potential benefits for plant tissue culture.

      The application of coconut water in tissue cultures was firstly introduced by Van Overbeek et al., stating that this special additive was critical for the development of immature zygotic embryos of Daruta stramonium[44]. Since then, increasing numbers of studies have been established, adapting the supplementation of coconut liquid endosperm in plant tissue and cell culture[10,45,46]. As a stand-alone culture medium, coconut water can be used as the primary culture medium, providing a suitable environment for the growth of plant tissues. Coconut water's composition is highly varied depending on the coconut's maturity and origin, it may need to be appropriately diluted or supplemented with other components to achieve ideal results. Coconut water can be added as a supplement to other basal media like MS medium[47] or B5 medium[48]. By adding coconut water to the basal medium, researchers can enhance the growth-promoting effects and improve the regeneration capacity of certain plant tissues.

      According to multiple studies to date, the stimulating activities of coconut water are mainly derived from the notable contents of natural phytohormones, mainly auxin and cytokinin[49]. Coconut's liquid endosperm has been found to contain indole-3-acetic acid (IAA), an endogenous auxin involved in a variety of plant growth and development processes[22]. IAA is biosynthesized in the meristematic regions located at the shoot apex and subsequently transported to the root tip in order to promote cell division and elongation. IAA can also drastically affect plant orientation by promoting cell division to one side of the plant in response to sunlight and gravity. In plant tissue culture, IAA and its analogues could also be applied as a stimulus for cell dedifferentiation and reprogramming, leading to the formation of embryogenic callus and later somatic embryos. The presence of this type of hormone in coconut water has led to some research into the potential use of coconut water as a stimulant for callogenesis, somatic embryogenesis, plantlet elongation and rooting. Specifically, a study by Sarathchandra et al.[50] has found that green coconut water alone was capable to induce callus formation from nodal segments of Camellia sinensis, however, the efficiency was significantly lower compared to other treatments with exogenous auxin. Another attempt on Musa paradisiaca revealed that coconut water was highly sufficient in promoting elongation and rooting of shoot tip-derived plantlets with similar rooting efficiency as 1.5 mg·L−1 α-naphthaleneacetic acid (NAA)[51]. Similar results were observed on Capsicum annuum, coconut water alone or in combination with silver nitrate exhibited significantly higher efficiency to obtained rooted plantlets compared to indole-3-acetic acid (IBA)[52]. The addition of coconut water at 10%–20% (v/v) was also found to promote callogenesis and somatic embryogenesis when combining with different exogenous auxins in various plant species, including Spicata oleracea[53], Lycopersicon esculentum[54], Phoenix dactylifera[55], Cocos nucifera[56], and Triticum aestivum[57]. As a result, the auxinic activity of coconut water has been proven to be highly beneficial in combination or replacement for exogenous auxin during micropropagation and tissue culture regeneration.

      Apart from auxin, a diverse composition of different cytokinin compounds such as N6-isopentenyladenine (2-iP), kinetin, zeatin, and their derivatives, has also been identified in coconut water[58]. These naturally occurring hormones, in combination with auxin, create a hormonal balance within plant cells and tissues, which are critical to various aspects of plant development, such as cell division and differentiation, gene activation, tissue organization, embryogenesis, seed germination, and shoot branching. With these specialized activities, coconut water is highly suggested for in-vitro plant cultivation, especially during shoot regeneration and multiplication. In fact, this additive has been noted to be crucial for indirect shoot regeneration in Ariocarpus kotschoubeyanus even in very small amounts (0.05%–0.15%) with 10–14 shoots per explant compared to no shoot formation in the control treatment[59]. In another study, Prando et al. found that coconut water could improve both shoot multiplication and elongation in Corylus avellana[60]. Sembiring et al. also reported an interesting observation that coconut water stimulated not only shoot multiplication and elongation but also the formation of potato tubers in in-vitro conditions[61]. Strawberry micropropagation was also subjected using coconut water with and observed 4-fold increase in shoot multiplication rate compared to the control treatment[62]. In addition to the studies mentioned above, there have been a number of other studies that have shown the benefits of coconut water in tissue culture of various plant species, such as Actinidia deliciosa[63], Cyamopsis tetragonolobust[64], Musa acuminata[65], Ananas comosus[66], Dianthuus caryophyllus[67], and Olea europaea[68]. However, application of coconut water does not always positively influence the development of plant tissue in in-vitro conditions. A study on Elaeis guineensis showed that multiple shoot abnormalities had been recorded from zygotic embryo in culture medium containing 15% coconut water[69], whereas this additive was found to inhibit germination of zygotic embryo Xiem Green Dwarf coconut at any concentration[70]. Thus, it is required to have specific investigation to determine the influence of coconut water in tissue culture for each plant species.

      Other than phytohormones, coconut water is also a great source of nutrients and bioactive compounds[10,22]. Ionic minerals, such as potassium (K+), chloride (Cl), calcium (Ca2+), and magnesium (Mg2+) are commonly found in coconut water[8]. These ionic minerals are the macronutrients which are highly essential for plant cell metabolism. In addition, supplying this highly nutritious additive to culture media could also provide high amounts of carbohydrates, acting as an alternative source of energy and carbon for in-vitro plants to live and continue developing. In fact, a study has shown that the application of 20% coconut water was able to completely replace sucrose in shoot culture of Ficus carica with no significant change in propagation efficiency[71]. Furthermore, this unique type of endosperm could also be utilized to reduce explant browning and promote further morphogenesis during plant tissue culture due to its rich contents of antioxidants and vitamins. This consideration was supported by Inpeuy et al., as coconut water significantly alleviated oxidative stress and reduce browning rate in Elaeis guineensis zygotic embryo explants[69].

      It is essential to understand that the choice of culture medium, including the use of coconut water (Table 3), depends on the specific plant species, tissue type, and research objectives. Different plants have unique requirements for growth, and their optimal culture medium may vary. Additionally, the composition of coconut water is somehow considered as undefined since it can vary based on multiple factors such as coconut's maturity, variety, geographical location, as well as the methods of sterilization and storage[10,22] leading to different outcome in its application during plant tissue culture[55,72]. Thus, standardization and careful preparation of culture medium are essential to obtain the best outcomes for tissue culture in a particular plant species or tissue type with high consistency.

      Table 3.  Application of coconut water in tissue culture of different plant species.

      Plant species Explant Callogenesis
      and embryogenesis
      Shoot regeneration
      and multiplication
      Notable effect of CW Reference
      Daruta stramonium Zygotic embryo _ Tukey's medium + 1% dextrose + 33.3% CW - Critical for the development and germination of zygotic embryo [44]
      Ipomea batatas Leaf MS + 0.5–2.0 mg·L−1 2,4-D + 6% sucrose
      MS + 2.0 mg·L−1 2,4-D + 2.0 mg·L−1 kinetin + 20% CW + 6% sucrose
      Hormone-free MS - Supported callus formation and multiplication [10,45,46]
      Agave cantala,
      A. fourcroydes,
      A. sisalana
      Stolon MS + 0.1 mg·L−1 2,4-D + 0.1 mg·L−1 BA + 10% CW + 2% sucrose MS + 0.075 mg·L−1 NAA + 0.1 mg·L−1 IBA + 0.5 mg·L−1 kinetin + 10% CW + 2% sucrose
      Hormone-free MS
      - Supported callus growth and shoot regeneration [10,45,46]
      Camellia sinensis Nodal segment Hormone-free VW + 15% CW + 2% sucrose
      MS + 1 mg·L−1 2,4-D + 1 mg·L−1 kinetin + 6% sucrose
      - Stimulated callogenesis in hormone-free medium [10,45,46]
      Musa paradisiaca Shoot tip N/A MS + 0.5 mg·L−1 NAA + 5% CW - Showed positive effect on shoot multiplication in combination with NAA
      - Sufficiently stimulate rooting with similar result compared to 1.5 mg·L−1 NAA
      - Accelerated the emergence of the first root but reduced shoot length and number of roots at any concentrations higher than 5%
      [10,45,46]
      Capsicum annuum Seed N/A Hormone-free MS + 3% sucrose
      MS + 9.0 μM TDZ + 5.77 μM GA3 + 14.7 μM PAA + 10% CW
      MS + 0.45 μM TDZ + 5.77 μM GA3 + 14.7 μM PAA + 10% CW
      MS + 9.8 μM IBA + 10% CW + 30 μM AgNO3
      - Enhanced shoot formation and elongation
      - Exhibit more efficient rooting effect than IBA
      - Showed synergistic effect with AgNO3 during rooting process
      [10,45,46]
      Spinacia oleracea Young leaf MS + 9.3 μM kinetin + 2.3 μM 2,4-D + 15% CW + 3% sucrose MS + 9.3 μM kinetin + 0.05 μM 2,4-D + 2.9 μM GA3 + 15% CW + 3% sucrose - Promoted callogenesis and shoot regeneration [10,45,46]
      Lycopersicon esculentum Hypocotyl, leaf disk MS + 5 mg·L−1 IAA + 1.5 mg·L−1 kinetin + 12% CW + 3% sucrose MS + 5 mg·L−1 IAA + 1.5 mgl kinetin + 12% CW + 3% sucrose
      MS + 0.1 mg·L−1 IAA + 3% sucrose
      - Improved callogenesis and shoot regeneration
      - Significantly enhanced plantlet survival rate during acclimatization
      [10,45,46]
      Phoenix dactylifera Shoot tip MS + 100 mg·L−1 2,4-D + 3 mg·L−1 2iP + 3% sucrose + 1.5 g·L−1 AC
      MS + 10 mg·L−1 NAA + 30 mg·L−1 2iP + 10–15% CW + 1.5 g·L−1 AC
      Hormone-free MS + 10%–15% CW
      ½ MS + 0.1 mg/l NAA
      - Both co-autoclaved and filtered CW improved callogenesis and somatic embryogenesis
      - Co-autoclaved CW showed slightly higher improvement in callogenesis and somatic embryogenesis
      [10,45,46]
      Cocos nucifera Zygotic embryo Y3 + 700 μM 2,4-D + 15% CW + 5% sucrose + 0.25% AC Y3 + 300–350 μM 2,4-D + 15% CW + 5% sucrose + 0.25% AC - Enhanced callus induction and somatic embryogenesis [10,45,46]
      Triticum aestivum Seed MS + 3 mg·L−1 2,4-D + 20% CW + 30 g·L−1 sucrose MS + 1.5 mg·L−1 BA + 10% CW + 30 g·L−1 sucrose - Enhanced callus induction and shoot regeneration [10,45,46]
      Ariocarpus kotschoubeyanus Epicotyl segment MS + 2 mg·L−1 zeatin + 3% sucrose MS + 1% CW + 3% sucrose
      MS + 3% sucrose + 1% PEG + 1% AC
      ½ MS + 1 mg·L−1 IAA + 3% sucrose + 1% PEG
      - Crucial for shoot regeneration from callus explant even at very small amount [10,45,46]
      Corylus avellana Nodal segment N/A 80% DKW + 2 mg·L−1 BA + 2% glucose + 0.5% AC
      80% DKW + 2 mg·L−1 BA + 0.01 mg·L−1 IAA + 0.5 mg·L−1 GA3 + 20% CW + 3% glucose
      - Improved shoot proliferation and growth [10,45,46]
      Solanum tuberosum Nodal segment N/A MS + 22.5% CW + 30 g·L−1 sucrose - Improved in vitro shoot multiplication and tuber formation [10,45,46]
      Fragaria × ananassa Shoot tip N/A 1/3 MS + 0.5 mg·L−1 BA + 0.1 mg·L−1 IBA + 10% CW + 30 g·L−1 sucrose - Shoot multiplication was 4-fold higher than the control [10,45,46]
      Actinidia deliciosa Seed N/A Hormone-free MS
      MS + 2 mg·L−1 BA + 20% CW
      ½ MS + 0.02 g·L−1 IBA
      - Stimulated the highest rate of shoot multiplication when combined with BA [10,45,46]
      Cyamopsis tetragonolobust Seed N/A Hormone-free MS
      MS + 2 mg·L−1 2,4-D + 20% CW
      ½ MS + 0.02 mg·L−1 IBA
      - Enhanced shoot multiplication [10,45,46]
      Musa acuminata Shoot tip N/A MS + 5 mg·L−1 BA + 3% sucrose
      ½ MS + 1 mg·L−1 NAA + 10% CW + 1.5% sucrose
      - Improved shoot regeneration and growth [10,45,46]
      Ananas comosus In vitro bud N/A MS + 1 mg/l IAA + 4 mg·L−1 BA + 10% CW
      MS + 1 mg·L−1 IAA + 20% CW
      - Efficiently stimulated bud proliferation at the concentration of 10% when combined with IAA and BA.
      - Induced the greatest plantlet growth at the concentration of 20% when added to cytokinin-free medium
      [10,45,46]
      Dianthus caryophyllus Shoot tip, nodal segment N/A MS + 1 mg·L−1BA + 10% CW + 3% sucrose
      ½MS + 1 mg·L−1 NAA + 3% sucrose
      - Enhanced shoot proliferation rate and average length of shoots [10,45,46]
      Olea europaea Zygotic embryo N/A MS + 10% CW + 3% sucrose - Exhibited significant interactive effect between olive genotypes and CW concentration during shoot multiplication.
      - Improved overall proliferation and growth of in vitro shoot at the concentration of 10%
      [10,45,46]
      Elaeis guineensis Zygotic embryo N/A Hormone-free MS
      MS + 0.5 mg·L−1 BA + 0.5 mg·L−1 kinetin + 15% CW + 3% sucrose
      - Significantly reduced explant browning rate
      - Stimulated shoot proliferation when combined with other hormones
      [10,45,46]
      Cocos nucifera Zygotic embryo N/A Y3 + 5 μM BA + 3% sucrose + 0.25% AC
      Y3 + 5 μM BA + 10% CW + 2% sucrose + 0.25% AC
      - Reduced germination rate of zygotic embryo compared to control
      - Promoted post-germination growth off seedlings
      [10,45,46]
      Ficus carica Shoot tip N/A MS + 1 mg·L−1 BA + 20% CW - Replaced sucrose as an alternative carbon and energy source [10,45,46]
      Solanum tuberosum Nodal segment N/A MS + 30% 6-month-old CW - Exhibited different effects among various maturities and concentration due to differences in hormone contents.
      - Significantly improved in vitro shoot growth at any concentrations for 6-month-old CW.
      - Only posed positive effect at the concentration of 30% for younger maturities of CW
      [10,45,46]
      MS: Murashige and Skoog basal medium[10,45,46]; Y3: Eeuwens basal medium[70]; DKW: Driver and Kuniyuki basal medium[8]; VW: Vacin and Went basal medium[71]; 2,4-D: 2,4-dichlorophenoxyacetic acid; NAA: α-naphthaleneacetic acid; IAA: indole-3-acetic acid; IBA: indole-3-butyric acid; BA: 6-benzylaminopurine; TDZ: Thidiazuron; GA3: gibberellic acid; PEG: polyethylene glycol; CW: coconut water; AC: activated charcoal.

      From the above text, we can easily reach the conclusion that coconut water was generally used as an addition in the plant tissue culture medium during the callus maturation and multiplication stage. Most researchers used 10% to 20% CW in the culture medium, which gives the greatest development to the secondary callus or somatic embryos. Very few researchers employed it in the initiation stage of callus since the low sugar content in CW.

      Coconut water has been used as an addition in the biotechnologies but there are still limitations of concern in the future. Firstly, the nutritional content of coconut water can vary depending on the coconut variety, maturity level, and environmental conditions. This can lead to unpredictable results in tissue culture experiments. Secondly, we have very limited understanding of active components of CW during tissue culture processes. While researchers have identified some beneficial components in coconut water, the specific mechanisms behind its effects are not fully understood. This knowledge gap hinders optimization of culture media and targeted applications. As an addition in the culture medium, efficient sterilization methods are crucial but can affect its beneficial properties of CW. Furthermore, finding the optimal concentration of coconut water for each plant species and culture system is crucial. Excessive amounts can have inhibitory effects, highlighting the need for careful optimization. These questions must be answered if we would like to further discover the potential of CW in tissue culture.

    • Coconut water has diverse and promising applications in medical addictives and biotechnology. It is widely recognized as a refreshing beverage and a versatile culinary ingredient, as its potential goes far beyond the realm of food and beverage. Our exploration has revealed the significant role of this natural gift for medical and biotechnological industry. The medical applications of coconut water are multifaceted. Its natural composition, rich in electrolytes, vitamins, and minerals, makes it an excellent option for rehydration and electrolyte balance, particularly in situations of dehydration and physical stress. Its antioxidant properties offer a unique advantage in combating oxidative stress and free radicals. Regarding biotechnology, coconut water versatility becomes evident as it serves as a nutrient-rich medium for cell and tissue culture. Its unique features make it an ideal candidate for plant cell/tissue culture and genetic research. In summary, coconut water is not merely a tropical thirst quencher; it is a reservoir of potential in the realms of medical science and biotechnology. As researchers continue to uncover its applications and benefits, the horizon of possibilities expands. This review underscores the importance of recognizing and harnessing the untapped potential of this natural wonder, not only for the betterment of our well-being but also for advancing the frontiers of medicine and biotechnology.

    • The authors confirm contribution to the paper as follows: Study design and writing: Mu Z, Tran BH, Xu H; Figure and table modification: Mu Z, Tran BH, Xu H, Yang Z, Xia W, Qamar UZ, Wang X; Review and editing: Luo J, Xiao Y, Mu Z. All authors reviewed the results and approved the final version of the manuscript.

    • All data used in this review paper were derived from Hainan University institutional repository and National University of Ho Chi Minh City institutional repository. All data were freely available and accessible without restrictions. Sources included: Hainan University institutional repository, National University of Ho Chi Minh City institutional repository.

      • This research was sponsored by the Scientific and Technological Cooperation Projects of Hainan Province (Grant No. ZDYF2020215), Hainan Yazhou Bay Seed Lab. + (JBGS + B21HJ0903), China Postdoctoral Science Foundation (Grant No. 2023M740951), Project for Science and Technology Innovation in Sanya City (Grant No. 2022KJCX53), the Postdoctoral Research Funding Project of Hainan Province, PhD Scientific Research and Innovation Foundation of Sanya Yazhou Bay Science and Technology City(HSPHDSRF-2023-12-002)and '111'Project (No. D20024).

      • The authors declare that they have no conflict of interest.

      • # Authors contributed equally: Zhihua Mu, Binh-Minh Tran, Hang Xu

      • Copyright: © 2024 by the author(s). Published by Maximum Academic Press, Fayetteville, GA. This article is an open access article distributed under Creative Commons Attribution License (CC BY 4.0), visit https://creativecommons.org/licenses/by/4.0/.
    Figure (1)  Table (3) References (72)
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    Mu Z, Tran BM, Xu H, Yang Z, Qamar UZ, et al. 2024. Exploring the potential application of coconut water in healthcare and biotechnology: a review. Beverage Plant Research 4: e018 doi: 10.48130/bpr-0024-0009
    Mu Z, Tran BM, Xu H, Yang Z, Qamar UZ, et al. 2024. Exploring the potential application of coconut water in healthcare and biotechnology: a review. Beverage Plant Research 4: e018 doi: 10.48130/bpr-0024-0009

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