An overview of microalgae biomass as a sustainable aquaculture feed ingredient: food security and circular economy

Lipids play a dynamic role in the formation of membranes and are important energy storage molecules. Although microalgae may have oil contents exceeding 60% by weight of dry biomass, the most common oil contents are in the range of 20–50% [76–78]. Polyunsaturated fatty acids present in microalgal lipids include arachidonic acid (ARA) and DHA. Cryptothecodinium and Schizochytrium contain DHA, Phaeodactylum, Nitzschia, Isochrysis, and Diacronema contain EPA, and Cryptothecodinium and Schizochytrium contain ARA. Microalgal species can produce EPA concentrations ranging from 7 to 34% fatty acids. These fatty acids are rare and difficult to synthesize in a lab. These components are currently derived from fish oil and are restricted in vegetable oils, including palm, soybean, rapeseed, and canola, in aquafeed [79]. Microalgae may produce high amounts of lipids and have a nutritionally advantageous fatty acid composition when grown under stress conditions. Polyunsaturated fatty acids (PUFAs), such as EPA (20:5, −3), and DHA (22:6, −3) are the important constituents of microalgal lipids. Microalgae species, such as S. limacinum, P. tricornutum, and Nannochloropsis sp., comprise 30–40% of ω-3 fatty acids in their total content [53]. LC-PUFAs such as ω-3 and 6 must be consumed regularly because humans and many animals cannot synthesize them [80]. PUFAs are also necessary ingredients for fish growth because they cannot be formed from saturated and monounsaturated fatty acids [81]. Fish have high tropical levels in aquatic environments due to their ability to metabolize PUFA to produce LC-PUFA, which strongly contributes to tropical upgrading. It is critical to understand how farmed fish create and store LC-PUFAs to substitute terrestrial plant lipids for fish oil in commercial aquafeeds. Through enhanced synthesis and selective use of dietary fatty acids, it is possible to increase the body<apos;>s storage of LC-PUFA. Data synthesis was performed to determine optimal fatty acid levels that improve the generation and storage of omega-3 polyunsaturated fatty acids in edible portions of salmonids [82].

Microalgae improved the fatty acid profile of fish and shrimp by improving the ω-3/ ω-6 ratio, increasing PUFA content, and enriching long-chain PUFAs [83,84]. Aquatic animals have higher nutritional value when their fatty acid profile is improved, which benefits consumers. Additionally, supplementing aquatic animals’ diets with microalgal PUFAs can increase their growth and immunity It has been reported that Nile tilapia can digest Schizochytrium sp. lipids with 98% efficiency [85]. Lipid digestibility in juvenile European seabass (Dicentrarchus labrax), Nile tilapia with C. vulgaris, Schizochytrium sp. Spirulina sp., and Chlorella sp., and African catfish (Clarus gariepinus) with C. vulgaris and S. maxima has been shown to be more than 80% [85–87]. Lower digestibility has been noted under certain conditions, such as for N. gaditana in juvenile African catfish [88]. A microalgae-based feed might also improve fish survival due to its functional properties, including probiotics, prebiotics, immunostimulants, antivirals, antibacterials, etc. Bacteria or microbes that are probiotics are believed to contribute to a healthy gut when consumed. For example, microalgae are probiotics for fish. The microbiome in the colon digests algal cells and generates probiotics that inhibit the growth of infectious agents [89,90]. Consumption of Tetraselmis suecica live cells significantly reduced the number of harmful bacteria in the stomach of white shrimp (Fenneropenaeus indicus) as compared to a control group [91]. The addition of Schizochytrium sp. meal to the diet at 1.2% significantly improved Nile tilapia health [92]. Previous studies have found that Spirulina can induce non-specific immune responses against infections in a variety of fish [93,94]. When S. Platensis is used at a 10% concentration, it has been proven to dramatically increase the production of white blood cells, red blood cells, hemoglobin, albumin, and total protein in rainbow trout [95].

LC-PUFAs are beneficial to animals and humans as they provide biologically active compounds such as prostaglandins and thromboxanes, which are crucial for the formation of cholesterol and triglycerides in the blood, as well as the prevention of certain diseases such as arthritis and rheumatoid arthritis [96]. DHA (22:6) and EPA (20:5), two of the most beneficial LC-PUFAs, stand out for their many health benefits. DHA improves brain health, which maintains neurons, boosts short- and long-term memory, and aids in the treatment of brain disorders such as memory loss and cognitive decline. By reducing oxidative stress and plasma triglycerides, as well as providing benefits for the treatment of inflammation, arrhythmia, and cardiovascular disease [97,98]. Microalgae also produce a wide range of fatty acids that are useful for the food and feed industry, including gamma-linolenic acid (GLA), linoleic acid (LA), alpha-linolenic acid (ALA), and ARA [99]. Wound healing and regeneration, as well as the eradication of invading microorganisms, may be aided by these essential fatty acids [100]. The lipid content of C. vulgaris has been reported to be 35–40% by weight, with a content of 27% linolenic and 24% linoleic acid [101]. Spirulina sp. has been promoted as an inexpensive source of GLA [100]. Recent research has indicated that microalgae such as Chlorella sp. and Schizochytrium sp. are more attractive than other autotrophic species due to their nutritional qualities and ability to be effectively consumed by aquaculture species. Thanks to the well-developed technology for mass cultivation of Schizochytrium and Chlorella sp. in aquafeeds, the use of fish oil can be significantly reduced in the future. To achieve sustainable substitution of fish oil in aquaculture, research must focus on the use of microalgal species.

Proteins have been recognized as the building components that are responsible for individual growth. Proteins are constructed from peptide bonds that link amino acid units [102]. In terms of quality and amino acid composition, microalgae protein is a great alternative to fish meals. The protein concentration of algae has been reported to range from 40 to 60 wt/wt % [103]. Another study discovered that C. vulgaris has between 51 and 58% protein, while Spirulina sp. comprises between 60% and 71%. Additionally, Arthrosphira platensis has a protein content of 70% by weight [104]. Protein is so abundant in some microalgae species that it accounts for more than half of their biomass. Most Spirulina strains, as well as a few Chlorella and Nannochloropsis strains, have a protein content of 40 to 65% [105]. Microalgae can synthesize all amino acid molecules; therefore, algae-derived amino acids are preferred over other protein-rich foods [106]. Microalgae can synthesize several protein compounds faster than traditional protein sources. Table 3 summarizes the current research on microalgal biomass used as a replacement for fishmeal and fish oil.

Kim et al. [107] discovered that parrotfish (Oplegnathus fasciatus) fed 5% Arthrospira had significantly higher weight, protein efficiency, and feed consumption compared to the control group fed fish meal. Fish need meals with 30% to 55% crude protein and amino acids tailored to their individual nutritional needs to achieve maximum growth [108]. Sørensen et al. [109], demonstrated that Phaeodactylum tricornutum can replace up to 6% of fish meal in the diet of Atlantic salmon (Salmo salar) without affecting digestibility, utilization, or growth performance. Protein digestibility of microalgae varies from 50% to 94% in different fish species. Protein digestibility of rainbow trout, Nile tilapia, European seabass, and African catfish has been reported to exceed 80% [110]. In African catfish and Nile tilapia, bead milling improved N. gaditana protein digestibility by 16 and 17 %, respectively [86]. Enzymatically processed microalgae digest protein 6% faster than whole-cell Nannochloropsis oceanica [40]. Protein digestion was enhanced in a diet containing Schizochytrium sp. when organic minerals were added [87]. N. oceanica and C. vulgaris provided amino acids with higher digestibility than 90% for European seabass and Atlantic salmon [87,111]. Tetraselmis sp. exhibited significantly lower mino acid digestibility than juvenile European seabass. Pretreatment would break down larger proteins into peptides and individual amino acids, which increases amino acid digestibility [110].

Threonine, isoleucine, lysine, leucine, methionine, valine, and histidine are essential amino acids that the body cannot produce itself. Therefore, it is important to consume them through foods that contain EAAs, such as tofu, eggs, and fish [112]. Vegans and vegetarians have few options since the majority of plant-based proteins do not meet the EAA profile. To overcome this problem, an alternative source with a balanced protein profile and low cost is required [113]. Protein digestibility of the microalgal protein (S. platensis protein concentration) ranges from 87.5 to 97.8% [114]. However, certain algae (510–710 g/kg) have more protein than eggs or soybeans (132–370 g/kg) and have fairly comparable EAAs [115]. Due to their high content of EAA, microalgae are considered one of the best vegan protein sources. It is well known that microalgae contain EAAs and non-NEAAs, both of which have health benefits [113]. NEAAs include amino acids, proline, arginine, glutamic acid, glycine, aspartic acid, tyrosine, cysteine, serine, and glutamic acid are a few examples. The amino acid profile of C. vulgaris and H. pluvialis, the proportion of NEAAs is around 51% and 49%, respectively [116]. A healthy immune system is influenced by these chemicals, as well as gene expression, antioxidant responses, and cell signaling [117]. Many studies indicate that the amount of microalgal meal that should be added to aquafeed varies depending on the type of algae used and the aquaculture species being fed. It would be beneficial to study the growth capacity of microalgae and identify the variables that influence their effectiveness.

The color of microalgae is one of its most distinguishing properties, which is determined by pigments. Microalgae pigments are critical for their nutritional performance in aquaculture. In addition to chlorophyll, microalgae include carotenoids and phycobiliproteins. The Nannochloropsis genus contains pigments such as chlorophyll and astaxanthin. Photosynthesis in algae is facilitated by pigments, which are brightly colored chemical compounds. Carotenoids, chlorophylls, and phycobilin are the three primary types of microalgal photosynthetic pigments [127,128]. Microalgae pigments are eye-catching natural colors that include high-value components with health-promoting qualities that include antioxidants, vitamin precursors, neuroprotective, and immunological boosters [129]. These pigments may address the increased demand for natural colors due to health concerns about the adverse effects of synthetic pigments [127,130]. Aquaculture uses a high concentration of carotenoids, such as β-carotene and astaxanthin, due to their vibrant color and antioxidant effects. These molecules have the potential to improve the quality and value of farmed fish, such as salmon and Asian tiger shrimp (Penaeus monodon) [131]. Phytochemicals such as astaxanthin and β-carotene are abundantly generated by the microalgae Haematococcus pluvialis and Dunaliella salina (3–7% wt/wt) in natural abundance [132,133]. Table 4 shows the pigment compositions of numerous algae species, as well as the health benefits associated with them.

Microalgal biomass has been shown to affect fish pigmentation. H. pluvialis is the most commonly used microalgae specifically for color enhancement. In the aquaculture industry, whole cells and extracts of H. pluvialis extracts are used as feed additives (1.5–1.7%) [134]. Several algae species are used as pigments in fish feed. The Haematococcus produces Astaxanthin, which gives salmon its pink hue [134]. Additionally, Spirulina contains additional carotenoids that ornamental koi and other fish can convert to astaxanthin and other brightly colored pigments [135]. Phaeodactylum tricornutum produces large quantities of fucoxanthin, which has been shown to contribute to the golden yellow coloration of gilthead seabreams [136]. Carotenoids are found in a wide variety of products, including natural feed colors, food supplements, vitamin supplements, and health foods. The high concentration of carotenoids in D. saline makes it the most popular species for large-scale production (up to 14% dry weight) [137]. Microalgae strains that are commercially feasible for pigment synthesis must meet a series of criteria, including improved nutritional components, non-toxicity, and the presence of digestible cell walls for nutrient absorption [129]. Phycobiliproteins, β-carotene, and astaxanthin are used mainly as colorants, pharmaceuticals, aquaculture, and nutraceuticals. Chlorococcum sp. (Astaxanthin, lutein, β-carotene), D. salina (β-carotene, zeaxanthin, chlorophylls a, b), H. pluvialis (astaxanthin, canthaxanthin, lutein), Spirulina sp. (β-carotene, zeaxanthin, phycocyanin, allophycocyanin), Porphyridium sp. (phycoerythrin) [138–143].

Natural feed pigments, feed additives, nutrients, and health food products are commonly made from carotenoids. Carotenoids found in abundance in D. salina make it the species most often exploited for large-scale production [144]. Carotenes from Dunaliella species were shown to improve the health of L. vannamei shrimp given high-carotene diets. Coloration and market acceptability can be achieved by supplementing Red tilapia diets with A. platensis, a source of pigmentation [145,146]. According to these studies, low amounts of Arthrospira or other microalgae can enhance the color and flavor of numerous fish species, such as tilapia. Therefore, additional studies are required to evaluate the impact of various microalgal pigments on commercial aquaculture.

Microalgae are high in vitamins, and vitamin B has been shown to function as a cofactor for mitochondrial enzymes, reducing oxidative breakdown and improving metabolism [147,148]. Microalgae, including Spirulina sp., have more Vitamin B12 (127–244 g/g) than plant or animal-based foods. This vitamin helps prevent megaloblastic anemia, which causes fatigue and weakness [149]. Another study found a significant amount of vitamin E (3.7 mg/g) in the Euglena gracilis microalgae. Vitamin E has been reported to reduce the risk of cancer, eye disease, heart disease, and other diseases [150]. A high amount of vitamin C content (3.44 mg/g) has been found in the Eisenia arborea brown microalgae, which is equivalent to that of mandarin oranges [151]. This antioxidant vitamin is necessary for immune system function, tissue formation, and repair [152].

Microalgae are rich in carbohydrates, and polysaccharides are readily found in both their cytoplasm and chloroplast [153]. Microalgae carbohydrates are used for several reasons, including energy storage and structural components in cell walls [154]. Due to the high photoconversion efficiency, macroalgae such as P. cruentum contain carbohydrates (40–57 wt% dry weight), Prymnesium parvum (30–33 wt% dry weight), and S. quadricauda (21–52 wt% dry weight) [155,156]. For each species of the algal genus, there is a distinct variation in glucose metabolism and content [156,157]. Algae with high carbohydrate yield and sugar content are suitable for human consumption. The culture system and environmental conditions can impact algal production and glucose content [153]. Microalgae contain about 10–25% carbohydrates and their amount varies with culture age and growth conditions [158]. A variety of starches, cellulose, sugars and other polysaccharides are found in microalgae. Bacteria and fungi naturally produce the polysaccharide β-glucan, which is made of D-glucose. These polysaccharides can be found in large quantities in the Chlorella sp., microalgae [78,159]. Table 5 displays the monosaccharide compositions of several microalgae.

Microalgal carbohydrates are digestible according to the type and quantity of carbohydrates in biomass, as well as the kind of fish that consumes microalgal carbohydrates [160]. The carbohydrate digestibility of microalgal species varies between 22% and 83%, depending on fish species [110]. S. maxima and C. vulgaris were found to have a higher carbohydrate digestibility (greater than 70%) in Nile tilapia [86]. Microalgae contain starch-like carbohydrates that can be easily digested. In vitro research revealed that C. sorokiniana, Klamath, and N. sphaeroides showed greater carbohydrate digestibility [161]. Studies conducted on Nile tilapia, African catfish, and in vitro studies have shown that C. vulgaris has a higher carbohydrate digestibility value than other algal species [86]. Certain microalgal species, such as Spirulina sp., Chlorella sp., and Schizochytrium sp., have been demonstrated to have excellent fiber digestibility [162]. Isochrysis sp. and Nannochloropsis sp. fiber digestibility in rainbow trout was determined to be 96% and 38%, respectively [11]. Even though Isochrysis sp. contained more fiber than Nannochloropsis sp., the latter had a higher fiber digestibility, suggesting that the type of fiber (soluble or insoluble) is important for digestion. Compared to other nutrients, starch is a readily digestible food for fish and crustaceans [163].

The antiviral and antibacterial properties of β-glucan have been shown in humans, and it has also been shown in fish to have high antibacterial and immune-stimulating properties [164]. Furthermore, the types of carbon sources used and the metabolic mechanism employed are other important variables that affect the sugar concentration in microalgae [115]. The use of light has been shown to influence both algal growth and biomass composition during algal culture since light is an important energy source for photosynthetic activity [78,153]. For algal cultivation, the light intensity is normally between 200 and 400 mol photons m²/s. Nutritional restriction may be used to alter the metabolic process of microalgae and cause glucose accumulation [44].

During cultivation, microalgae cells can absorb and accumulate substantial amounts of heavy metals (HMs) [78,186–188]. Several studies have examined the bioaccumulation of HMs in microalgal biomass due to the existence of negatively charged functional groups on the surface of microalgal cells [189–191]. HMs absorbed by microalgae include predominantly arsenic (As), cadmium (Cd), copper (Cu), chromium (Cr), lead (Pb), mercury (Hg), nickel (Ni), and lanthanum (La). In fact, both living and non-living microalgae are effective in absorbing HMs from the environment and water [21,191]. Non-living microalgae can accumulate Cd, Cr, Hg, and Pb at 59, 98, 36, and 131 mg/g, respectively. Non-living algal biomass has a strong capacity to adsorb HMs primarily due to their surface functional groups [192].

When microalgal biomass containing concentrated HMs is fed to fish, harmful compounds can migrate up the food chain. Certain strategies can be employed to avoid bioaccumulation of HMs in the food chain when microalgae are used as aquafeed. The amount of HMs in the culture media should be monitored regularly during microalgae culture. If HMs concentrations exceed the EPA<apos;>s guidelines, the culture medium must be treated or relieved. This method may avoid the bio-accumulation of HMs in the food chain. Before using microalgae as fish food, it is possible to eliminate HMs from them. HMs desorption may occur through pH-induced desorption or metal-chelating agent treatment. The pH of algal cells must be lowered to the isoelectric points of functional groups on their surfaces to neutralize their surface charge [193]. Heavy metals adsorbed on the surface of algae might be combined with metal chelating agents to facilitate their desorption. HMs have been successfully desorbed from microalgae biomass using these two approaches [193–196]. When HMs are attached to the surface of algal cells rather than within algal cells, desorption techniques may be used to remove them from the biomass of microalgae. In contrast to the accumulation of HMs inside algal cells, microalgal cells can be treated by desorption to remove HMs adhering to the surface. Therefore, after desorption, HMs content in algal cells should be evaluated to determine whether microalgae can serve as aquafeed.

Since microalgae have a high starch concentration, replacing the biomass of microalgae with a fish meal reduces digestibility. Furthermore, aquatic animals must dissolve the cellulose-rich cell walls of algae before consuming their nutritional components. For these two challenges, meals supplemented with microalgae- in fish and shrimp culture are poorly absorbed [197]. Dietary wheat starch levels of 20% in juvenile largemouth bass (Micropterus salmoides) not only impeded weight gain but also produced oxidative stress and impaired innate immunity. Fish offered 5% and 10% starch diets showed significant weight gain, growth rate, protein efficiency ratio, and feed conversion ratio when compared to fish-fed 20% starch diets [198]. It is generally recognized that omnivore fish digest carbohydrates are better than carnivorous fish, although they exhibit significant anatomical and physiological differences in their digestive systems [198,199]. Another study found that omnivorous fish have various digestive capacities [20]. Rather than raw biomass, defatted microalgae biomass is often used as a supplement to fish feed in the fishing sector. After oil extraction, the starch content in the biomass could be increased. The microalgae biomass must be effectively managed to avoid an excessive starch content. The apparent digestibility coefficients (ADCs) of macronutrients, amino acids, and fatty acids were studied in freshwater (Arthrospira, Chlorella) and marine microalgal (Schizochytrium) components in Nile tilapia [85]. Compared to chlorella, Arthrospira exhibited significantly higher ADCs of crude protein and all EAAs (86%), which corresponded well with the reported values for fishmeal and plant feeds. Schizochytrium had the highest DHA content, as well as the highest ADCs for lipids (total PUFA 98%), ω-3 (98%), and ω-6 (92.4%), as well as the maximum digestibility of DHA. Spirulina and Schizochytrium were shown to be effective protein substitutes for tilapia diets, while Schizochytrium was discovered to be a good LC-PUFA supplement [200].

For microalgal cells to be preserved, they usually need to be spray-dried after they have been removed from the growing reactor. Furthermore, microalgal biomass is dried in a variety of ways, such as sun drying, drum drying, and oven drying. However, the microalgae cell wall remains intact in these circumstances, indicating that digestion is restricted [87,201,202]. A cellulose-rich cell wall causes poor digestion of microalgae-supplemented fish diets [203]. The cell wall protects the algal cell and its intracellular components during growth. It is necessary to disrupt the cellulose structure of the cell wall in order to access the intracellular contents. Due to a lack of intestinal flora, several species of fish are unable to digest non-starch carbohydrates effectively [204,205]. Therefore, cellulose cannot be digested by fish, and the structure of the cell walls of microalgae cannot be effectively dissolved by many species of fish. As a consequence, aquatic organisms will not be able to consume nutrients found in algal cells. To improve the digestibility of microalgal biomass for use in fish/shrimp aquaculture, certain pretreatment techniques could be applied. Microalgae, for starters, contain starch, which may be separated before using algal biomass as aquafeed. Second, destroying the cell wall may cause the nutritional components of the microalgae to be released [206]. Enzymatic digestion and physical treatment have been shown to destroy microalgae cell walls effectively [206,207]. Microalgae cell walls are made up of pectin, hemicellulose, cellulose, and glycoproteins. In algae, enzymes such as glucosidase, cellulase, hemicellulase, xylanase, and exoglucanase break down the cell wall [206].

To improve nutrient digestibility, biomass can be pretreated/processed using pasteurization, freeze-drying, bead milling, high-pressure homogenization, pulse electric field, microwave, chemical, and enzymatic treatments [208]. During biomass processing or pretreatment, the rigid cell wall of algae is broken down, releasing internal nutrients that can be digested and absorbed by fish. According to studies, the processing of specific microalgae is linked to improved digestibility in certain fish [87,209,210]. Physical treatment processes such as sonication, the beating of beads, and freezing can be used to damage the microalgal cell wall. The cost of the aforementioned methodologies should be used to determine their viability in a real-world application [4]. The grinding of Tetraselmis sp. beads, for example, increased protein digestibility in European seabass by 20% compared to untreated cells [87]. Pretreatment with bead milled microalgae rather than whole biomass increased the digestibility of amino acids such as phenylalanine and aspartic acid in European seabass, but not the digestibility of essential amino acids [87]. Nannochloropsis and Chlorella cell walls were broken by bead milling for 10 minutes, which could release nutrients and improve digestibility [86,209,211]. For European seabass, enzyme processing improved the protein digestion of Nannochloropsis sp. and Chlorella sp., as well as energy digestion of Nannochloropsis sp. Tetraselmis sp., and Chlorella sp., by 14%, 11%, and 40%, respectively [87]. Due to the fact that the degree of cell rupture differs between species, nutritional accessibility can vary despite equal processing conditions [212].

Anti-nutritional factors (ANFs) are biological components that affect gastrointestinal and metabolic function in animals and humans. These ANFs were detected in vegetable soybean and peanut proteins together with phytic, lectin, and tannic acids. Due to the increased nature of ANFs, protein meals or peanut meals cannot be used in aquafeed [213]. Microalgae have been shown to contain a variety of ANFs, such as Tetradesmus obliquus, Kirchneriella lunaris, and Pseudokirchneriella subcapitata [214,215]. Previous studies indicate that the tannic acid levels of S. maxima (6.86 mg/g) and C. vulgaris (1.44 mg/g) were comparable [216]. High absorption of microalgae may negatively affect fish growth because of antinutritional components in microalgae. ANF-supplemented aquafeed reduced liver enzyme activities and reduced intestinal brush border enzymes in juvenile Japanese seabass (Lateolabrax japonicus) [217].

It would be beneficial to discover and study anti-nutritional components in microalgae to increase their incorporation into fish diets. A pretreatment strategy for microalgae should also include the scavenging of anti-nutritional factors. Many studies have demonstrated effective ways to eliminate the anti-nutritional components from soybean meals [218,219]. Antinutritional chemicals may be removed by specific microorganisms through their activities. When Aspergillus sojae and/or Aspergillus ficuum are used in conjunction with solid-state fermentation, the phytic acid was reduced by 53.27% to 73.16%. Enzymes produced from microorganisms may also be used to remove certain anti-nutritional substances [220]. Another study found a maximum tannin removal rate of 73%. If antinutritional components are identified in microalgae, different physical treatment methods, including extraction, frying, blanching, and soaking, may be utilized to minimize their concentration. The pretreatment treatments described above have been shown to significantly decrease ANFs in a variety of vegetable proteins [221–224]. For example, extrusion cooking with optimal barrel temperature, extruder speed, and moisture content removed 61.25 % of tannin in linseed meals [224]. Eventually, these technologies may be utilized to pre-retreat microalgae to eliminate anti-nutritional components and surge algal biomass assimilation into fish diets, which would be beneficial in the long run.

Most aquafeed substitutes microalgae biomass for fish meal. Microalgae cultivated in a culture medium should be harvested and dried, and the moisture adjusted before being used to make algae biomass-supplemented fish feed pellets. Centrifugation, sedimentation, and filtration are all processes used to collect suspended algae cells in a culture medium. The collection of algae biomass accounts for 30% of microalgae production costs. In addition to that, flocculation harvesting incorporates aluminum into biomass, making microalgae-based aquafeed based on microalgae undesirable [225]. Drying wet microalgae (with a moisture content of 70–90 %) is required before the algae can be delivered to the feed factory. This is an energy-intensive, time-consuming, and costly technique [226]. Managing the moisture content of dehydrated microalgae biomass is important throughout the pelletization process.

Certain alternatives have been proposed and thoroughly explored to overcome the aforementioned concerns. The development of more cost-effective biomass harvesting methods is an essential first step. Co-cultivation of a filamentous fungus with microalgae previously resulted in fungal-algal pellets [15,227]. As a consequence, biomass collection has become a passive process that does not require human interaction. Several fungal strains, including Mucor circinelloides and Aspergillus oryzae, produce high-value components when cultured with microalgae, which can improve the nutritional content of biomass [228,229]. Microalgae immobilization techniques have also been implemented to minimize collection costs. After growing in the substratum, a biofilm<apos;>s biomass may be scraped off using scrapers. Immobilized microalgae are more economical to harvest than suspended microalgae [230]. Microalgae can be used to make an eco-friendly closed or semi-closed food chain aquaculture system. Zooplankton is the main food source for fish and shrimp in this environment. In addition to breaking down animal waste, microalgae can also transform it into valuable components [15,231]. Therefore, harvesting and drying can be avoided, and microalgae can be used to improve aquaculture water quality. Therefore, this unique approach to microalgae aquaculture is more economically feasible while still addressing the objectives of a circular economy.