Use of Arthrospira Platensis in Development of Functional Foods
Yeşildağ, İrem;
Çelekli, Abuzer
Because of its high protein content and rich nutritional profile, which includes essential amino acids and bioactive compounds like biliproteins and C-phycocyanin with antioxidant properties, Arthrospira platensis, also known as spirulina, is becoming more and more recognized as a potent food supplement. It also provides a major source of carotenoids, xanthophylls, phyto pigments, and vitamins A, E, B1, B7, and B8. It has a low fat content but is rich in linolenic and γ-linolenic acids, which are essential for human health. Rich in minerals such as iron, calcium and potassium, A. platensis can improve bone health and overall health. It ensures easy digestion thanks to its high carbohydrate content and lack of cellulose. Arthrospira platensis is known for its immunomodulatory, antioxidant, and hypocholesterolemic properties.
Abdel-Latif, H.M.R., El-Ashram, S., Yilmaz, S., Naiel, M.A.E., Kari, Z.A., Hamid, N.K.A., Dawood, M.A.O., Nowosad, J., Kucharczyk, D., 2022. The effectiveness of Arthrospira platensis and microalgae in relieving stressful conditions affecting finfish and shellfish species: An overview. Aquaculture Reports 24, 101135.
Ahmad, A., Ashraf, S.S., 2023. Sustainable food and feed sources from microalgae: Food security and the circular bioeconomy. Algal Research 103185.
AlFadhly, N.K.Z., Alhelfi, N., Altemimi, A.B., Verma, D.K., Cacciola, F., Narayanankutty, A., 2022. Trends and technological advancements in the possible food applications of Spirulina and their health benefits: A Review. Molecules 27, 5584.
Ampofo, J., Abbey, Lord, 2022. Microalgae: Bioactive composition, health benefits, safety and prospects as potential high-value ingredients for the functional food industry. Foods 11, 1744.
Arslan, P. 2013. Tavuk etinin sağlıklı beslenme için önemi. Piliç Eti Sektör Raporu Kitabı 88 91.
Becker, E.W., 2007. Micro-algae as a source of protein. Biotechnology advances 25, 207–210.
Beheshtipour, H., Mortazavian, A.M., Mohammadi, R., Sohrabvandi, S., Khosravi‐Darani, K., 2013. Supplementation of Spirulina platensis and Chlorella vulgaris algae into probiotic fermented milks. Comprehensive Reviews in Food Science and Food Safety 12, 144–154.
Belay, A., 1997. Mass culture of Spirulina outdoors—the Earthrise Farms experience. Spirulina platensis 1, 131–158.
Belay, A., 2007. Spirulina (Arthrospira): production and quality assurance, in: Spirulina in Human Nutrition and Health. CRC press, pp. 15–40.
Belay, A., 2013. Biology and industrial production of Arthrospira (Spirulina). Handbook of microalgal culture: applied phycology and biotechnology 339–358.
Birch, C.S., Bonwick, G.A., 2019. Ensuring the future of functional foods. International Journal of Food Science & Technology 54, 1467–1485.
Bortolini, D.G., Maciel, G.M., Fernandes, I. de A.A., Pedro, A.C., Rubio, F.T.V., Branco, I.G., Haminiuk, C.W.I., 2022. Functional properties of bioactive compounds from Spirulina spp.: Current status and future trends. Food Chemistry: Molecular Sciences 5, 100134.
Camacho, F., Macedo, A., Malcata, F., 2019. Potential industrial applications and commercialization of microalgae in the functional food and feed industries: A short review. Marine drugs 17, 312.
De la Jara, A., Ruano-Rodriguez, C., Polifrone, M., Assunçao, P., Brito-Casillas, Y., Wägner, A.M., Serra-Majem, L., 2018. Impact of dietary Arthrospira (Spirulina) biomass consumption on human health: main health targets and systematic review. Journal of Applied Phycology 30, 2403–2423.
Deng, R., Chow, T., 2010. Hypolipidemic, antioxidant, and antiinflammatory activities of microalgae Spirulina. Cardiovascular therapeutics 28, e33–e45.
Gentscheva, G., Nikolova, K., Panayotova, V., Peycheva, K., Makedonski, L., Slavov, P., Radusheva, P., Petrova, P., Yotkovska, I., 2023. Application of Arthrospira platensis for Medicinal Purposes and the Food Industry: A Review of the Literature. Life 13, 845.
Ghanbarzadeh, M., Moazami, N., Shahavi, M.H., Mirdamadi, S., 2022. Study of bioactive compounds in Arthrospira platensis MGH-1 fortified with micronutrients of iron, zinc, and manganese. Journal of Applied Phycology 34, 2449–2462.
Gibbs, N., Duffus, C.M., 1976. Natural protoplast Dunaliella as a source of protein. Applied and environmental microbiology 31, 602–604.
Guasto, A., Waliszewski, W., Bolivar, C., 2018. Arthrospira platensis. Monografía. In Methods.
Guedes, A.C., Malcata, F.X., 2012. Nutritional value and uses of microalgae in aquaculture. Aquaculture 10, 59–78.
Gün, D., Çelekli, A., Bozkurt, H., Kaya, S., 2022. Optimization of biscuit enrichment with the incorporation of Arthrospira platensis: nutritional and sensory approach. Journal of Applied Phycology 34, 1555–1563.
Henrikson, R., 1994. Spirulina: Superalimento del futuro. Ediciones Urano, Barcelone.
Hosseinkhani, N., McCauley, J.I., Ralph, P.J., 2022. Key challenges for the commercial expansion of ingredients from algae into human food products. Algal Research 64, 102696.
Katiyar, R., Arora, A., 2020. Health promoting functional lipids from microalgae pool: A review. Algal Research 46, 101800
Kulshreshtha, A., Jarouliya, U., Bhadauriya, P., Prasad, G., Bisen, P.S., 2008. Spirulina in health care management. Current pharmaceutical biotechnology 9, 400–405.
Matos, J., Cardoso, C., Bandarra, N.M., Afonso, C., 2017. Microalgae as healthy ingredients for functional food: A review. Food & function 8, 2672–2685.
Ndife, J., Ejikeme, C., Amaechi, N., 2010. Effect of oven drying on the functional and nutritional properties of whole egg and its components. African Journal of Food Science 4, 254–257.
Nielsen, C.H., Balachandran, P., Christensen, O., Pugh, N.D., Tamta, H., Sufka, K.J., Wu, X., Walsted, A., Schjørring-Thyssen, M., Enevold, C., 2010. Enhancement of natural killer cell activity in healthy subjects by Immulina®, a Spirulina extract enriched for Braun-type lipoproteins. Planta medica 76, 1802–1808.
Panlasigui, S., Spotswood, E., Beller, E., Grossinger, R., 2021. Biophilia beyond the building: Applying the tools of urban biodiversity planning to create biophilic cities. Sustainability (Switzerland) 13, 1–14. https://doi.org/10.3390/su13052450
Pina-Pérez, M.C., Brück, W.M., Brück, T., Beyrer, M., 2019. Microalgae as healthy ingredients for functional foods, in: The Role of Alternative and Innovative Food Ingredients and Products in Consumer Wellness. Elsevier, pp. 103–137.
Seyidoglu, N., Inan, S., Aydin, C., 2017. A prominent superfood: Spirulina platensis. Superfood and functional food the development of superfoods and their roles as medicine 22, 1–27.
Shao, W., Ebaid, R., El-Sheekh, M., Abomohra, A., Eladel, Hjg., 2019. Pharmaceutical applications and consequent environmental impacts of Spirulina (Arthrospira): An overview. Grasas Y Aceites 70, e292–e292.
Sharoba, A.M., 2017. Spirulina: Functional Compounds And Health Benefits. Plant Secondary Metabolites.
Sidari, R., Tofalo, R., 2019. A comprehensive overview on microalgal-fortified/based food and beverages. Food Reviews International 35, 778–805.
Turan, H., Yalçın, K., Sönmez, G., 2006. Balık Etinin Besin Değeri ve İnsan Sağlığındaki Yeri. Ege Journal of Fisheries and Aquatic Sciences 23, 505–508.
Udayan, A., Pandey, A.K., Sharma, P., Sreekumar, N., Kumar, S., 2021. Emerging industrial applications of microalgae: challenges and future perspectives. Systems Microbiology and Biomanufacturing 1, 411–431.
UTEX, 2024. https://utex.org/ (accessed 3.11.24)
Walter, P., 1997. Effects of vegetarian diets on aging and longevity. Nutrition reviews 55, S61 S65.
Walter, P., 1997. Effects of vegetarian diets on aging and longevity. Nutrition reviews 55, S61 S65.
Zariç, Ö. E. ve Çelekli, A. 2023. Fishing in Kars-Ardahan Lake Çıldır: Ecological Interactions and Conservation Strategies. 7. Ulusal Alabalık Kongresi
Zariç, Ö. E., Tekkaş, A., Yıldırım, G., & Çelekli, A. 2023. Modern insanlarda çene evrimi ve 20 yaş dişlerinin durumu: paleontolojik ve morfolojik incelemeler. 25. Ulusal Biyoloji Kongresi (İzmir, Türkiye), 190. https://doi.org/10.5281/zenodo.8361987
Zariç, Ö.E., Yeşildağ, İ., Yaygır, S., Çelekli, A., 2022. Removal of Harmful Dyes Using Some Algae. 3rd International Congress on Plant Biology; Rize, Turkey 173. https://doi.org/10.5281/zenodo.8190776
Zariç, Ö.E., Çelekli, A., Yaygır, S., 2024. Lakes of Turkey: comprehensive review of Lake Çıldır. Sciences and https://doi.org/10.26650/ASE20241353730
Çelekli, A., Yaygır, S., & Zariç, Ö. E. 2023. Lakes of Turkey: Comprehensive Review of Lake Abant. Acta Aquatica Turcica, 19(4), 368-380. https://doi.org/10.22392/actaquatr.1272430
Çelekli, A., Yaygır, S., Zariç, Ö.E., 2023a. A review of climate change-induced migration. Acta Biologica Turcica, 36(2), A3:1–11. https://doi.org/10.5281/zenodo.8190755
Çelekli, A., Yeşildağ, İ., Yaygır, S., Zariç, Ö.E., 2023b. Effects of urbanization on bioclimatic comfort conditions. Acta Biologica Turcica, 36(4), S2:1–10.
Çelekli, A., Yeşildağ, İ., Zariç, Ö.E., 2024b. Green building future: algal application technology. Journal of Sustainable Construction Materials and Technologies. Advance Online Publication. https://doi.org/10.47481/jscmt.1348260
Çelekli, A., Zariç, Ö. E. (2024.c). Rising Tide of Ocean Acidification. Environmental Research and Technology. Advance Online Publication. https://doi.org/10.35208/ert.1407588
Çelekli, A., Zariç, Ö., 2023a. Utilization of Herbaria in Ecological Studies: Biodiversity and Landscape Monitoring. Herbarium Turcicum. Advance Online Publication. https://doi.org/10.26650/HT.2023.134591
Çelekli, A., Zariç, Ö.E., 2023. Assessing the environmental impact of functional foods. 6th International Eurasian Conference on Biological and Chemical Sciences, 103.
Çelekli, A., Zariç, Ö.E., 2023b. Hydrobiology and ecology in the context of climate change: the future of aquatic ecosystems. 6th International Eurasian Conference on Biological and Chemical Sciences 539–545. https://doi.org/10.5281/zenodo.10021473
Çelekli, A., Zariç, Ö.E., 2023c. From Emissions to Environmental Impact: Understanding the Carbon Footprint. International Journal of Environment and Geoinformatics 10, 146–156. https://doi.org/10.30897/ijegeo.1383311
Çelekli, A., Zariç, Ö.E., 2024a. Breathing life into Mars: Terraforming and the pivotal role of algae in atmospheric genesis. Life Sciences in Space Research 41, 181–190. https://doi.org/10.1016/j.lssr.2024.03.001
Çelekli, A., Zariç, Ö.E., 2024b. Plasma-Enhanced Microalgal Cultivation: A Sustainable Approach for Biofuel and Biomass Production. In A. Shahzad & M. He (Eds.), Emerging Applications of Plasma Science in Allied Technologies (pp. 243-263). IGI Global. https://doi.org/10.4018/979-8-3693-0904-9.ch011
Ötleş, S., Pire, R., 2001. Fatty acid composition of Chlorella and Spirulina microalgae species. Journal of AOAC international 84, 1708–1714.
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