key: cord-0068696-ag4nxrt4 authors: Baek, GahYoung; Saeed, Maham; Choi, Hyung-Kyoon title: Duckweeds: their utilization, metabolites and cultivation date: 2021-10-19 journal: Appl Biol Chem DOI: 10.1186/s13765-021-00644-z sha: 746a134ab61122a82113de19719cc549b8d5879e doc_id: 68696 cord_uid: ag4nxrt4 Duckweeds are floating plants of the family Lemnaceae, comprising 5 genera and 36 species. They typically live in ponds or lakes and are found worldwide, except the polar regions. There are two duckweed subfamilies—namely Lemnoidea and Wolffioideae, with 15 and 21 species, respectively. Additionally, they have characteristic reproduction methods. Several metabolites have also been reported in various duckweeds. Duckweeds have a wide range of adaptive capabilities and are particularly suitable for experiments requiring high productivity because of their speedy growth and reproduction rates. Duckweeds have been studied for their use as food/feed resources and pharmaceuticals, as well as for phytoremediation and industrial applications. Because there are numerous duckweed species, culture conditions should be optimized for industrial applications. Here, we review and summarize studies on duckweed species and their utilization, metabolites, and cultivation methods to support the extended application of duckweeds in future. Duckweeds are among the smallest free-floating aquatic plants worldwide. They have a simple morphology, comprising a few fronds; furthermore, they rarely flower [1, 2] . Duckweeds replicate and proliferate rapidly. The reproduction period is only 1.2 days per generation [3] . Additionally, they are highly adaptable and occur in diverse aquatic environments [4] . Similar to other aquatic plants, duckweed species generally inhabit the natural environment, such as ponds and lakes, and grow best especially in tropical and temperate regions [5, 6] . They can also grow well in local and industrial wastewater [7, 8] . Because of these features, duckweeds are suitable for various experimental and practical applications that require fast and high productivity. Duckweeds have been utilized for food, pharmaceutical, phytoremediation, and other industrial applications [9] [10] [11] [12] . Climate crisis has become a serious problem that threatens the food and feed supply of the increasing population of the world. It is known that duckweeds contain essential nutrients such as proteins, carbohydrates, and fats. Additionally, they contain a variety of secondary metabolites that are beneficial to humans. Therefore, consideration of cultivation methods of duckweeds is vital to their enhanced utilization in various industrial applications. There have been several reports regarding utilization, metabolites, and cultivation of duckweeds; these should be reviewed and summarized as a fundamental information for enhanced duckweed application. The objective of this review was to summarize the diverse utilization of duckweeds and their metabolites and cultivation methods. This review will be useful for further industrial applications of duckweeds. Duckweeds belong to the family Lemnaceae, comprising 5 genera and 36 species under two subfamilies Lemnoidea (15 species) and Wolffioideae (21 species) [13, 14] . Duckweed species self-replicate genetically identical clones Open Access *Correspondence: hykychoi@cau.ac.kr College of Pharmacy, Chung-Ang University, Seoul 06974, Republic of Korea It is known that most duckweeds proliferate rapidly, and the harvested yield per area is higher than the average of the major crop yields [4] . The protein production of duckweeds per harvested area was higher than that of soybean, rice, and corn; thus, it could solve the problem of farmland shortage to produce food or animal feed [25] [26] [27] [28] . Duckweeds contain starch, fatty acid, protein, and other secondary metabolites used in food and feed industries [7, 9, [29] [30] [31] [32] . Compared with red meat, plant-based foods have less of an association with cardiometabolic risks and diabetes [33, 34] . Additionally, duckweeds have been accepted as food resources without public aversion [35] . Because of their high yield, economic advantage, nutrient composition, and positive perception by people, duckweeds have been utilized as the plant-derived food and feed resources. Table 1 lists duckweed species used as food resources. Wolffia species have long been consumed as protein sources by humans in Asia [9, 29, 36] . Currently, duckweeds are mainly consumed as amino acid supplements [29] . Parabel, Ltd. has a product line of duckweed plant powders as an alternative to high protein foods [37, 38] . Duckweeds are also expected to occur in the European food market [39] . Consumption of plant protein, instead of animal protein, is expected to reduce energy use and greenhouse gases [40] . Duckweeds are good candidates for nutritious and safe meat protein substitutes for humans. Consumption of W. globosa as a meat substitute reduces the risk of iron deficiency while maintaining iron [27, 46, 47, 52] Sheep Landoltia punctata [49] Recycled feed supplement L. minuta [45] Waterfowl L. minor [50] homeostasis and folic acid concentration [41] . Clinical nutrition studies have demonstrated that the essential amino acids and vitamin B 12 contents of duckweeds are comparable to peas and cheese [29] . Iron and zinc in duckweeds are sufficient for the recommended allowance, similar to the sodium/potassium ratio and fiber content [42] . The amino acid composition of Wolffia sp. and Wolffiella sp. meets the World Health Organization (WHO) recommendations [9, 43] . The ratio of omega-3 to omega-6 fatty acids in Landoltia punctata, L. gibba, L. minor, S. polyrrhiza, W. microscopica, and Wolffiella hyalina makes them suitable for food and feed [9] . However, it should be noted that consumption of duckweed species high in oxalic acid could cause kidney stones [44] . Moreover, intake of duckweed with substance adsorption abilities could lead to heavy metal intake. Duckweed species have been used as livestock feed for hundreds of years and have been shown to be nutritious [15, 28, 31] . Duckweed feed can supply animals with phosphate and nitrogen [39] . L. minuta can be recycled as a feed supplement by adsorbing micronutrients such as selenium and zinc, which are essential for animals [45] . W. arrhiza, used as animal feed, yields protein content comparable to that by soybeans [17] . As listed in Table 1 , duckweeds are used as feed for various livestock, including cattle, chicken, fish, sheep, and waterfowl [7, 15, 26, 27, [46] [47] [48] [49] [50] [51] . L. minor and S. polyrrhiza are economically viable alternatives to fish and soybean meal feed for fish and waterfowl [27, 46, 50, 52] . In cows, there is no abnormality in the digestion of dry matter and crude protein of duckweed; thus, it could be used as an alternative feed for soybean meal [48] . Soybeans are most commonly used as feed, but the expansion of cultivation because of increased demand could emit significant greenhouse gases from land use change [53] . Duckweeds are considered as novel ingredients to replace soybeans, thus reducing the burden of greenhouse gas emissions and alleviating the negative aspects of feed production [51] . The protein content of duckweeds grown in organic manure is very high, and utilization of duckweed as feed has been suggested as a solution to environmental issues related to manure purification and feed production [54] . Duckweeds are protein sources that could replace soybean meal and are expected to be used as substitutes to reduce environmental pollution created by expanding soybean cultivation. As represented in Table 2 , duckweeds have been suggested as pharmaceutical resources. Previous studies have been reported that duckweed species such as L. minor, L. trisulca, and S. polyrrhiza have been widely utilized as folk medicine in China, Korea and a few European nations [12, 44, 55] . Duckweeds are medicinal herbs that do not have severe side effect [44] . Recent research has revealed the various pharmacological effects of duckweeds. L. minor has antibacterial activity against gram-negative bacilli (Pseudomonas fluorescens, Shigella flexneri, Escherichia coli, and Salmonella typhi) and gram-positive bacteria (Bacillus subtilis), and could Antibacterial activity L. minor and S. polyrrhiza [44, [56] [57] [58] Anticancer activity Landoltia punctata [59] Anti-adipogenic effect S. polyrrhiza [61] Antifungal activity L. aequinoctialis and S. polyrrhiza [58, 69] Antigen expression for vaccines after nuclear transformation L. minor [66] Antioxidant activity Landoltia punctata, L. gibba, L. minor, S. polyrrhiza, W. borealis, and Wolffiella caudata [44, 59] Colonic health improvement Landoltia punctata [62] Cytotoxic activity L. minor [44] Folk medicine (antiscorbutic, asthma, colds, diabetes, diuretic, febrifuge, general tonic, hives, measles, edema, rhinitis, soporific, and vitiligo) L. minor [12, 44] Folk medicine (choleretic and phytoncidic activities) L. trisulca [12] Folk medicine (erysipelas and leprosy) S. polyrrhiza [12] Immunomodulatory activity L. minor [57, 60] Monoclonal antibody production as a transgenic plant by LEX System L. minor [63, 64] Monoclonal antibody production for non-Hodgkin's lymphoma L. minor [67, 68] Recombinant human granulocyte colony-stimulating factor production W. arrhiza [65] be an alternative to antibacterial agents for the treatment of various diseases [44, 56, 57] . S. polyrrhiza also showed antimicrobial activities against seven gram-negative bacilli, one gram-positive bacterium, and two fungal pathogens [58] . Flavonoids in duckweeds could contribute metabolites for the antioxidant activity [59] . Apigenin and vitexin in Landoltia punctata have been suggested as constituents for treating non-small lung cancer [59] . L. minor has been shown to have immunomodulatory activity [57] . In particular, flavonoids in L. minor have been reported to have immunosuppressive effects by reducing free hemoglobin content and antibody production in human whole blood samples infected with ovalbumin antigen [60] . Flavonoids in S. polyrrhiza have been demonstrated to exert anti-adipogenic effect by reducing triglyceride content [61] . An increase in fecal butyric acid has been reported as a result of duckweed consumption, which may be associated with improved colon health in humans and is an important energy source for colon cells [62] . Although further research and clinical trials are required for practical use, duckweeds have great potential to be utilized for pharmaceutical purposes because of their diverse pharmacological effects. Another pharmacological potential of duckweeds is their use as a platform for human therapeutic proteins production. Recombinant therapeutic proteins are produced by Lemna Expression System (LEX System) [63, 64] . Additionally, nuclear-transformed W. arrhiza expresses human granulocyte colony-stimulating factor [65] . Nuclear-transformed L. minor-based expression studies for avian influenza vaccine development have shown the potential of transgenic duckweed to provide good-quality antigens for vaccine development [66] . Synthon/Biolex Therapeutics produces large quantities of antibodies for non-Hodgkin's lymphoma using duckweed species [67, 68] . Duckweed-based antibody production could be considerably inexpensive and could provide easy to scale up platforms for diverse antibody-based therapies to treat and prevent diseases. Duckweeds, tolerant to extreme conditions, are known as effective remediation resources for pollutants in wastewater. They purify sewage through the powerful accumulation of chemicals by adsorption or uptake [25, 70, 71] . As listed in Table 3 , duckweeds have been reported to purify inorganic, organic, and pharmaceutical materials. Ammonium elimination is necessary for the purification of wastewater because ammonium increases eutrophication in ponds and forms nitrates in groundwater [72] . Landoltia punctata absorbs ammonium from water and stores ammonium ions as a useful nitrogen source [19, 73] . Excessive concentration of boron, a by-product of industrial production, is detrimental to the ecosystem. L. gibba has also been reported to remove boron from water [11, 74] . Boron is adsorbed to apiogalacturonans in the cell wall of duckweeds [75] . L. minor captures iron, L. gibba captures sulfate, and S. polyrrhiza captures fluoride [76] [77] [78] . Nitrogen and phosphorous emissions from manure in livestock systems contribute to eutrophication of ecosystems; thus, their recovery and reuse are significant and essential tasks [79] . For example, Landoltia punctata, L. gibba, L. minuta, L. turionifera, S. polyrrhiza, and W. borealis purify wastewater or swine lagoons by removing nitrogen and phosphorous [19, 70, 71, 76, [79] [80] [81] . The adsorption capacity of nitrogen and phosphorus is especially valuable because duckweeds can be reused as fertilizers that release nitrogen and phosphorus in the soil [82] . Duckweeds are resistant to several heavy metals and can be used for bioremediation in local and industrial wastewater by accumulating heavy metals, including arsenic, cadmium, chromium, cobalt, copper, lead, nickel, selenium, and zinc [45, [83] [84] [85] [86] [87] [88] [89] [90] [91] [92] [93] [94] . They have an enzymatic antioxidant mechanism to control oxidative stress caused by heavy metals and reduce damage [83] . Duckweeds relieve the stress of heavy metals that affect nutrient absorption by activating antioxidative mechanisms [85] . The chelating action of duckweeds can also alleviate the stress caused by heavy metals, such as chromium (IV) [85, 93] . The release of diverse pharmaceuticals into environment severely affects various plants and animals, and their removal through phytoremediation is important. L. turionifera and W. borealis could remove pharmaceuticals, such as acetaminophen, fluoxetine, progesterone, and sulfamethoxazole [71] . L. minor can remove benzotriazoles used in anti-corrosion products, coolants, and dishwashing liquids [95] . L. turionifera can eliminate pesticides, such as imidacloprid insecticide, from contaminated water [96] . L. gibba was used for the remediation of fresh water contaminated with nonsteroidal anti-inflammatory drug ibuprofen [97] . Applications of L. gibba for removing tetracycline and L. minor for removal antimicrobials have also been reported [98, 99] . Industrial wastewater from modern factories and sewage from large animal farms, hospitals, and homes are known to cause problems in aquatic environments. Duckweeds could be the best aquatic purification plant. Phytoremediation using duckweeds is a cost-effective and environmentally friendly strategy to prevent environmental pollution and preserve aquatic and terrestrial ecosystems. However, the purification capacity of duckweeds and disposal of contaminated duckweeds should be thoroughly considered. In recent years, interest in the developing alternative energy sources has increased owing to environmental problems and climate changes. Biofuels are renewable energy alternatives to fossil fuels and include bioalcohols, biodiesel, and biogas. Duckweeds have been used for bioethanol production as a renewable energy resource [25] . With the increasing need for biomass, research has focused on duckweeds and their starch content. Under proper conditions, the doubling time of duckweed biomass ranges from 1.34 to 4.54 days [4]. Starch could be used for bioethanol production through a considerably simple conversion process [25] . Duckweed biomass production is economical because, unlike corn, duckweeds do not require mechanical grinding; additionally, the byproduct of ethanol fermentation has a high protein content that could be reused as livestock feed [25] . As listed in Table 4 , duckweeds have been used as a resource for biomass and biofuel production. Duckweeds with a high starch content, high biomass production, and low lignin content could be promising sources of bioethanol production [103] . Duckweeds can be enzymatically converted to bioethanol by fermentation without thermophysical pretreatment [104] . L. aequinoctialis and S. polyrrhiza have been selected to increase bioethanol yield as they have a high starch content and biomass production capacity [105, 106] . S. polyrrhiza could be utilized as a substitute for corn starch to make the bioethanol industry Inorganic Ammonium Landoltia punctata [19] Arsenic L. gibba, L. valdiviana, S. intermedia, and W. arrhiza [83, [87] [88] [89] Boron L. gibba [11, 74] Cadmium L. minor and L. trisulca [90] [91] [92] Chromium S. polyrrhiza [93] Cobalt Landoltia punctata [94] Copper L. aequinoctialis, L. gibba, L. minor, and L. trisulca [84, 85, 91, 92] Fluoride S. polyrrhiza [78] Iron L. minor [77] Lead L. perpusilla [86] Nickel Landoltia punctata and L. minor [90, 94] Nitrogen Landoltia punctata, L. gibba, L. minuta, and S. polyrrhiza [19, 70, 76, [79] [80] [81] Phosphorous Landoltia punctata, L. gibba, L. minuta, L. turionifera, S. polyrrhiza, and W. borealis [70, 71, 76, [79] [80] [81] Selenium L. minuta [45] Sulfate L. gibba [76] Zinc L. minor and L. minuta [45, 90] Organic Dairy industry processing wastewater L. minor [100] Hydrocarbons in crude oil-contaminated wetlands L. aequinoctialis [101] Synthetic dyes L. minor [102] Wastewater Landoltia punctate and W. arrhiza [7, 17] Pharmaceutical Acetaminophen L. turionifera and W. borealis [71] Antimicrobials L. minor [99] Benzotriazoles L. minor [95] Fluoxetine L. turionifera and W. borealis [71] Ibuprofen L. gibba [97] Imidacloprid L. turionifera [96] Progesterone L. turionifera and W. borealis [71] Sulfamethoxazole L. turionifera and W. borealis [71] Tetracycline antibiotics L. gibba [98] sustainable because its ethanol yield (6.42 × 10 3 l ha −1 ) has been found to be higher than that of corn (4.31 × 10 3 l ha −1 ) [106] . Cytokinin treatment has been suggested as a good option to increase the growth rate of and starch accumulation in S. polyrrhiza [107] . Landoltia punctata could be used for biobutanol production by a mutant strain of yeast [103] . L. minor can be pyrolyzed to produce biochar, and biochars are catalysts for biogas [108] . After extracting starch from duckweeds, the residual cell wall can be broken down into sugars and uronic acids, which can be converted into biofuel sources [109] . Additionally, L. minuta has been reported as an ecofriendly energy resource that converts solar energy into electricity by acting as a plant fuel cell to generate electricity [110] . L. aequinoctialis and W. globosa have a high relative growth rate even under microgravity, making them suitable for use in space exploration [111] . L. gibba is also suitable for agriculture and bioregeneration systems for space exploration because it has shown a high growth rate under an extreme range of lighting from low growth luminosity to a total daily photon mass similar to that received on the brightest and longest days [112] . In long-term space exploration, W. arrhiza could also be a photosynthetic producer [113] . Duckweeds can be utilized as resources for biodegradable plastics. Biodegradable plastics are polymers that can be degraded by living organisms and are invented as alternatives to non-degradable plastics [114] . Lemna species produce biodegradable plastics for various industrial products [115] . Blending duckweed biomass and polyethylene has shown good stability and matrix characteristics [115] . Proteins, carbohydrates, and fats in duckweeds Table 5 lists the total content of proteins, carbohydrates, and fats in various duckweeds. The proportion of the total content of amino acids in duckweeds was the highest compared with that of carbohydrates and fatty acids. The total protein content of duckweeds ranges from 19.8% to 48.2% per dry weight. Relatively higher level of total amino acid (48.2%) per dry weight was observed in W. globosa [116] . Relatively higher level of total carbohydrate content (38%) was reported in L. gibba [117] . In addition, total fatty acid content was relatively higher in L. minor (11.4%) [30] . The nine essential amino acids found in the duckweed species are histidine, isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine and eleven non-essential amino acids, namely alanine, arginine, asparagine, aspartate, cysteine, glutamate, glutamine, glycine, proline, serine, and tyrosine, were also found in duckweeds (Table 6) [9, 15, 54, 116, 122] . Amino acid derivatives, such as citrulline, cystathionine, hydroxyproline, γ-aminobutyric acid (GABA), and taurine, were also found (Table 6) [54, 122] . Notably, the amino acid compositions of W. microscopica and Wolffiella hyalina are close to the content of lysine (30 mg/ kg), sulfur amino acids (15 mg/kg) including cysteine and methionine, threonine (15 mg/kg), and tryptophan (4 mg/kg) required for adults per day according to WHO recommendations. Additionally, the contents of cysteine and methionine are 22% higher than the recommended allowance [43] . Carbohydrates in duckweeds comprised sugars, polysaccharides, and starch. Sugars, such as apiose, arabinose, fructose, fucose, galactose, glucose, mannose, raffinose, rhamnose, sucrose, and xylose, were found in duckweeds (Table 6) [10, 75]. The compositions of duckweed cell walls were similar among species, consisting of pectin and hemicellulose [109] . Among the polysaccharides that do not make up the cell wall, inulin has been reported [120] . Starch accounts for approximately 4.0% to 29.8% of duckweed species, as listed in Table 5 . High levels of starch accumulation have been observed under nutritional deficiency conditions in S. polyrrhiza [106] . Adequate salinity condition (150 mM NaCl) induce starch accumulation in Landoltia Biobutanol Landoltia punctata [103] Biodegradable plastics for various industrial products Lemna sp. [115] Bioethanol L. aequinoctialis, L. minor, and S. polyrrhiza [104] [105] [106] Biofuels L. gibba, S. polyrrhiza, and W. australiana [109] Biogas L. minor [108] Biomass production as a bioregenerative system for space exploration L. aequinoctialis, L. gibba, and W. globosa [111, 112] Photosynthetic producer in space exploration W. arrhiza [113] Plant fuel cell L. minuta [110] punctata, L. aequinoctialis, L. gibba, L. minor, and S. intermedia [125] . However, duckweeds produce low total protein levels under saline condition (10, 20, and 30 mmol/L NaCl concentration) [106] . Therefore, when choosing salt treatment as an induction method to increase biomass for biofuel production, circumspection regarding its correlation with protein levels is required. L. aequinoctialis and S. polyrrhiza are known as high-starch duckweed species; therefore, they can be utilized in the biofuel industry [105, 106] . As listed in Table 5 , the total fatty acids content ranges from 1.05% to 1.62% and the triacylglycerol composition is 0.02% in Landoltia punctata, L. aequinoctialis, S. polyrrhiza, and W. globosa [119] . The fatty acids found in duckweeds included behenic acid, eicosanoic acid, 6-hexadecenoic acid, 2-hydroxypalmitic acid, lauric acid, lignoceric acid, α-linolenic acid, γ-linolenic acid, linoleic acid, linolenic acid, myristic acid, nonadecylic acid, oleic acid, palmitelaidic acid, palmitic acid, pentadecylic acid, stearic acid, and stearidonic acid (Table 6) [9, 17, 32, Medium-chain fatty acids Lauric acid [120, 123] Short-chain fatty acids C2, C3, C4, and C5 [28] 119, 120, 123] . Three fatty acids-linoleic acid, linolenic acid, and palmitic acid-are dominant, accounting for approximately 80% of the total fatty acids [119] . The content of α-linolenic acid is also particularly high (between 11 and 25%) [9] . The ratio of omega-3 to omega-6 fatty acids in duckweeds has been reported to range from 5:3 to 4:1 [9]. Increased consumption of omega-3 fatty acids could prevent inflammatory diseases, cancer, cardiovascular diseases, and other chronic diseases, therefore, the omega-3:omega-6 ratio in duckweeds is noteworthy [126] . Short chain fatty acids (SCFAs) have also been identified in L. minor, the total SCFA is 16.6 mM, of which C 2 and C 3 account for 11.8 and 3.1 mM, respectively [28] . SCFAs can be absorbed into colon epithelial cells through diffusion or active transport; C 2 and C 3 , in particular, are easily transported to other cells and organs [127] . SCFAs have been reported to contribute to the healthy intestinal environment, regulate the immune system, and prevent colorectal cancer [127, 128] . Despite their substantial potential as bioactive materials, profiling individual intact lipid species in duckweeds has rarely been performed. Further investigation should be conducted to reveal the profiles of such lipid species in various duckweed species to broaden application of duckweeds. As listed in Table 7 , duckweeds contain various useful secondary metabolites including phenolic compounds (flavonoids, phenylpropanoids, and tannins) and terpenoids. Various physiological properties have facilitated their utility, and they have been highlighted in the pharmaceutical, cosmetics, and food industries. Phenolic compounds are bioactive compounds with diverse pharmacological activities in humans [129] . The total phenolic content ranges from 1.3% to 2.9% in L. minor [30] . As listed in Table 7 , the phenolic compounds detected in duckweeds are flavonoids, hydroxycinnamic acids, and tannin. The flavonoids in duckweeds are apigenin, luteolin, and their derivatives (Table 7) . Duckweeds are known to have a higher flavonoid content (> 2%) than most other plants (0.5% to 1.5%) [94] . In particular, S. polyrrhiza and W. globosa has a high flavonoid content (4.22% and 5.85%, respectively), which could be advantageous in producing flavonoids [130] . Landoltia punctata showed significant apigenin content, and the contents of luteolin and its derivatives were high in L. gibba, S. polyrrhiza, W. borealis, and Wolffiella caudata [59] . Landoltia punctata, S. polyrrhiza, W. borealis, and Wolffiella caudata contain abundant C-glycosylated flavonoids, which exhibit high antioxidant activity [59, 131] . Apigenin and vitexin of Landoltia punctata could be used as anticancer adjuvants, and flavone C-glycosides from L. japonica exhibits cytotoxic activity against various human cancer cell lines, such as HepG-2, SW-620, and A-549 [59, 132] . Anthocyanins have been detected in L. gibba and S. intermedia and exhibit antioxidant properties [83, 87] . Hydroxycinnamic acids detected in duckweeds include caffeic acid, cinnamic acid, m-coumaric acid, p-coumaric acid, ferulic acid, isofelulic acid, and sinapic acid [17, 123, 133, 134] . Hydroxycinnamic acids possess antibacterial, anticollagenase, anti-inflammatory, anti-obesity, antioxidant, anti-tyrosinase, neuroprotection, and ultraviolet protection activities that could contribute to human health [135, 136] . Terpenoids (isoprenoids) have been widely utilized in the pharmaceutical, food, cosmetic, pesticide, chemical industries [137] . Terpenoids such as carotenoids, phytosterols, and saponins, have been detected in duckweeds (Table 7) . Neophytadiene, 24-methylenecycloartan-3-one, saponin, and squalene have also been reported [17, 28, 42, 58, 134] . Saponins, including 24-dehydroechinoside, echinoside A, stichoposide C, and stichoposide D, show antitumor, hypolipidemic activity, and antihypertensive effects and suppress fat accumulation [138] . L. minor contains a total saponin content 3.2 g/kg dried weight [28] . Phytosterols, such as Δ5-avenasterol, campesterol, cycloartenol, β,δ-sitosterol, and stigmasterol, have been reported in duckweeds [9, 17, 124, 133, 134] . Phytosterols account for approximately 20% of the wax fraction of S. polyrrhiza [134] . Phytosterols are cholesterol-lowering agents that reduce serum and liver cholesterol [139] . Carotenoids belonging to the tetraterpene found in duckweeds included α-carotene, β-carotene, loliolide, lutein, lycopene, violaxanthin, xanthophyll, and zeaxanthin [9, 30, 112, 120, 124] . Duckweed species are distributed in various regions in the natural environment, except for deserts and polar regions [6] . The growth of duckweed species is exponential and faster than most other plants under appropriate carbon dioxide, light, pH, temperature, and nutrient supply conditions [15, 73] . Table 8 lists the culture conditions of various duckweeds. Erlenmeyer flasks, Magenta vessel, and Petri dishes have been used for most small-volume cultures (< 500 mL) [4, 75, 96, 100, 104, 107, [140] [141] [142] 161] . Small-scale cultures should be subcultured periodically, and the light-dark cycle and temperature conditions should be constant to achieve a uniform growth rate and constant nutrient contents. It is important which culture medium to choose because incorrect selection can lead to physiological disturbances or death of the plants [143] . Schenk and Hildebrandt medium, Hutner medium, Murashige and Skoog medium, and Hoagland medium are generally used as Table 7 Secondary metabolites in duckweeds Phenolic compounds Flavonoids Anthocyanin L. gibba and S. intermedia [83, 87] Apigenin Landoltia punctata and S. polyrrhiza [59, 131] Apigenin 6-C-(2″-O-trans-caffeoyl-Dmalate)-β-glucoside L. japonica [132] Apigenin 7-O-glucoside S. polyrrhiza [59, 131] Apigenin 8-C-glucoside (vitexin) Landoltia punctata, L. gibba, and S. polyrrhiza [59, 131] 5-O-(E)-caffeoylquinic acid Landoltia punctata and S. polyrrhiza [59] 3-O-(E)-coumaroylquinic acid S. polyrrhiza [59] 6,8-Di-C-β-glucosylapigenin L. japonica [132] 6,8-Di-C-β-glucosylluteolin L. japonica [132] Isoorientin L. japonica [132] Isovitexin L. japonica [132] Luteolin S. polyrrhiza [131] Luteolin-6-C-glucoside-8-C-rhamnoside Landoltia punctata and W. borealis [59] Luteolin 6-C-(2″-O-trans-caffeoyl-Dmalate)-β-glucoside L. japonica [132] Luteolin 6-C-(2″-O-trans-coumaroyl-Dmalate)-β-glucoside L. japonica [132] Luteolin 7-O-glucoside S. polyrrhiza [59, 131] Luteolin-7-O-β-glucoside L. japonica [132] Luteolin-7-O-glucoside-C-glucoside Landoltia punctata, W. borealis, and Wolffiella caudata [59] Luteolin 8-C-glucoside (orientin) S. polyrrhiza and W. borealis [59, 131] Luteolin-8-C-glucoside-6-C-rhamnoside Landoltia punctata, L. gibba, W. borealis, and Wolffiella caudata [59] Luteolin-8-C-glucoside-6-C-xyloside Landoltia punctata, L. gibba, and W. borealis [59] Hydroxycinnamic acids Caffeic acid L. aequinoctialis and W. arrhiza [17, 133] Cinnamic acid S. polyrrhiza [134] m-Coumaric acid L. aequinoctialis [133] p-Coumaric acid L. aequinoctialis, L. minor, and W. arrhiza [17, 123, 133] Ferulic acid L. minor and W. arrhiza [17, 123] Isoferulic acid L. aequinoctialis [133] Sinapic acid L. aequinoctialis [133] Tannin 24-Methylenecycloartan-3-one W. arrhiza [17] Saponin L. minor and S. polyrrhiza [28, 42, 58] β-Sitosterol L. aequinoctialis, S. polyrrhiza, W. arrhiza, and W. microscopica [9, 17, 133, 134] δ-Sitosterol L. minor [124] Stigmasterol L. aequinoctialis, L. minor, S. polyrrhiza, W. arrhiza, and W. microscopica [9, 124, 133, 134] Squalene S. polyrrhiza [134] Tetraterpenoids α-Carotene L. gibba [120] refined media for the culture of various duckweeds. Schenk and Hildebrandt medium contains sucrose as the carbon source and KNO 3 as a nitrogen source [144] . Regarding nitrogen sources, Hutner medium contains NH 4 NO 3 , Murashige and Skoog medium contains NH 4 NO 3 and KNO 3 , and Hoagland medium contains Ca(NO 3 ) 2 and KNO 3 [145] [146] [147] . The differences in nitrogen sources could affect the starch and biomass production of duckweeds [105, 148] . In mass production (> 500 mL), duckweeds are cultivated in artificial environments (bioreactors) or natural ponds, well water, dairy, and local wastewater [11, 37, 54, 73, 83, 105, 106, 112, 149, 150, 162] . Under optimal environment conditions, including wind protection, water nutrient concentration, and optimum duckweed density, duckweeds can produce biomass with a productivity of 10-30 tons/ha per year [6, 151] . In open pond systems, S. polyrrhiza in organic manure and inorganic fertilizer is high in protein and carbohydrate contents, respectively [54] . Duckweeds grow rapidly even in animal wastewater, producing high biomass [106] . In the natural underground water, duckweeds have a tendency to grow slowly, lengthen roots, and possess lower protein content because of insufficient nitrogen and mineral nutrients [6, 106] . Conditions of essential phytonutrients, such as ammonium, calcium, magnesium, nitrogen, and phosphorous, affect the biomass of duckweeds [73] . Duckweeds grow in a wide pH range of 3.5 to 9.0, and the optimal pH range is between 6.5 and 7.5 [6, 73, 152, 153] . The pH determines the ratio of NH 3 to NH 4 + in the culture medium. As the pH increases, NH 4 + increases, thus preventing the transport of anions in the duckweed membrane and eventually reducing growth, high NH 3 at low pH exhibits toxicity [73, 153] . The pH also has a significant effect on the conversion of duckweed biomass into biobutanol. Bacterial growth yields sufficient butanol for industrial use when culture maintained between pH 4.5 and 5.0 [103] . Light intensity and duckweed growth rate show a direct relationship, unless the light intensity is too high. The lowest growth rate was at a low intensity of 6 μmol m -2 s −1 , and the growth rate increased with increasing light intensity to 1000 μmol m -2 s −1 [141] . Duckweeds accumulate antioxidants to prevent damage when exposed to excessive light. However, it has been proposed that the choice of optimal light intensity balances light efficiency with the antioxidant contents [112] . It was also reported that different light qualities affected the growth and physiological characteristics of duckweeds. Irradiation with ultra-high-frequency electromagnetic radiation has increased the growth rate and biomass, whereas infrared irradiation increased the number of fronds in L. minor culture [154] . However, ultraviolet rays delay the development of duckweeds and the growth of the root system, and radiofrequency radiation induced oxidative stress in the plants [154, 155] . In a natural environment, duckweeds generally grow in the range of 6 to 33 ℃; the optimum water temperature for duckweeds growth is between 19 and 30 ℃ [6, 73, 152] . In late summer in the temperate climate region of the world, duckweeds undergo a morphological change called turion because of the reduction in temperatures [6]. They sink into water bodies, storing starch as energy for the next growing season, and remain dormant. When the temperature increases in spring, they germinate because of light [156, 157] . Turion-type duckweeds could be suggested as useful biofuel feedstock because of their high anthocyanin and starch contents and low lignin content [156, 157] . Under controlled laboratory conditions, induction of conversion to turion by abscisic acid treatment has been possible for S. polyrrhiza [156] . According to diverse goals and targets, optimal cultivation of duckweeds will be necessary from an economic and industrial point of view. Various culture methods of duckweeds using diverse types of bioreactors and conditions should be employed for the utilization as food, pharmaceutical, phytoremediation, and biofuel resources. Aquaponics that combine aquaculture and hydroponics could be a sustainable production system for plants [158] . Additionally, the cultivation of various plants employing Xanthophyll L. gibba [120] Zeaxanthin L. gibba and W. microscopica [9, 112] the Internet of Things (IoT) and artificial intelligence (AI) technology enables the mass-production of goodquality plants by controlling environmental conditions, such as irrigation irradiation, atmospheric pressure, wind speed, temperature, and humidity [159, 160] . Aquaponics coupled with IoT and AI technology could be employed for duckweed cultivation in the future. 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Dissertation Nitrogen removal and conversion by duckweed grown on waste-water Characterization of environmental conditions required for production of livestock and fish fodder from duckweed (Lemna gibba L.) 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US Patent 6,040,498 Cultivation, harvesting and processing of floating aquatic species with high growth rates Publisher's Note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations Not applicable. Authors' contributions GB contributed to investigation and writing the manuscript. MS contributed to the investigation. HC contributed to the conceptualization, supervision, and writing the manuscript. All authors have read and approved the final manuscript. This work was supported by the National Research Foundation of Korea (NRF) Grant (NRF-2015R1A5A1008958) funded by the Korean government (MSIP) and Chung-Ang University Research Scholarship Grants in 2020. Not applicable. The authors declare that they have no competing interests.