The chemical composition of microalgae is not an intrinsic constant factor but varies over a wide range of factors, both depending on species and on cultivation conditions. Some microalgae have the capacity to acclimate to changes in environmental conditions by altering their chemical composition in response to environmental variability. A particularly dramatic example is their ability to replace phospholipids with non-phosphorus membrane lipids in phosphorus-depleted environments. It is possible to accumulate the desired products in microalgae to a large extent by changing environmental factors, like temperature, illumination, pH,
CO2 supply, salt and nutrients. Microphytes also produce chemical signals which contribute to prey selection, defense, and avoidance. These chemical signals affect large scale tropic structures such as
algal blooms but propagate by simple diffusion and laminar advective flow. Microalgae are seen as valuable biofertilizers because they help to improve both plant growth and soil fertilization. They are known to be a more sustainable option compared to agrochemicals due to their ability to decrease the usage of synthetic fertilizers, improve soil fertility, and optimize nutrients. The use of microalgae in cosmetic products is also becoming more prevalent. This is due to some of the benefits that arise from microalgae's compounds, including anti-aging, skin brightening, and UV protection. Algal can be found in many cosmetic products that people use on a daily basis. The compounds are used in antioxidants, moisturizing agents, skin sensitizers, sunscreens, thickening agents, etc. There are many different uses for microalgae in the pharmaceutical world. They produce bioactive compounds which possess therapeutic properties and serve as a drug delivery system. The extracellular-vesicles, which are derived from the microalgae, can be used for drug delivery. They are capable of crossing biological barriers, encapsulating proteins, nucleic acids, and small molecules.
Photo- and chemosynthetic algae Photosynthetic and chemosynthetic microbes can also form symbiotic relationships with host organisms. They provide them with vitamins and polyunsaturated fatty acids, necessary for the growth of the bivalves which are unable to synthesize it themselves. In addition, because the cells grow in aqueous suspension, they have more efficient access to water, CO2, and other nutrients. Microalgae play a major role in nutrient cycling and
fixing inorganic carbon into organic molecules and expressing
oxygen in marine
biosphere. While
fish oil has become famous for its
omega-3 fatty acid content, fish do not actually produce omega-3s, instead accumulating their omega-3 reserves by consuming microalgae. These omega-3 fatty acids can be obtained in the human diet directly from the microalgae that produce them. Microalgae can accumulate considerable amounts of proteins depending on species and cultivation conditions. Due to their ability to grow on non-arable land microalgae may provide an alternative protein source for human consumption or animal feed. Microalgae proteins are also investigated as
thickening agents or
emulsion and
foam stabilizers in the food industry to replace animal based proteins. Some microalgae accumulate
chromophores like
chlorophyll,
carotenoids,
phycobiliproteins or polyphenols that may be extracted and used as coloring agents. ==Cultivation of microalgae==