Abstract
The ability of microalgae to grow heterotrophically lies in the ability to oxidize organic compounds present in the external environment. The aim of this work was to evaluate the growth of Chlorella vulgaris under heterotrophic culture conditions using Basal Bold and NPK media supplemented with different sole carbon sources (glucose, fructose, sucrose, glycerol or acetate). The kinetic parameters obtained were maximum specific growth rate (µ max ), doubling time (DT), maximal absorbance, which was also converted to cell concentration values using a linear relation, and cell productivity (P X ). Among all the treatments analyzed, the highest maximum specific growth rate found was 0.030 hour -1 (0.72 day -1 ) in the treatment using Basal Bold medium supplemented with glucose. The highest cellular concentration and cell productivity were also found for this same treatment (4.03 x 10 6 cell mL -1 and 64.0 x 10 6 cell L -1 day -1 , respectively). It was concluded that that the Basal Bold medium was more efficient for Chlorella vulgaris growth, since it induced higher values of µ max and cellular concentration. Results obtained were very reproducible using microplate assay.
Highlights
One of the most studied microalgae species is Chlorella vulgaris, which has been cultivated since 1960 in Japan
Microalgae cultures supplemented with glucose had higher values of maximum specific growth rate in both Basal Bold (0.030 hour-1) and NPK (0.017 hour-1) media compared to the other carbon sources
Higher μmax were previously observed in heterotrophic cultures supplemented with glucose for Chlorella vulgaris (0.042 hour-1) when compared to other carbon sources (Bonini & Bastos, 2012)
Summary
One of the most studied microalgae species is Chlorella vulgaris, which has been cultivated since 1960 in Japan. In 1980, there were approximately 26 large-scale factories in Asia producing about 1000 kg of biomass per month (Spolaore, Joannis-Cassan, Duran, & Isambert, 2006). Chlorella vulgaris has an average cell composition of 20 fat, 45 protein, 20 carbohydrate and 10% minerals and vitamins It may change according to nutritional and environmental factors, producing a protein, carbohydrate or lipid-rich biomass (Silva & Sforza, 2016). This microalga can accumulate pigments such as chlorophyll a and b, β-carotene and xanthophylls (Guedes, Amaro, & Malcata, 2011). Its intracellular carbon reserve form is starch (Bailey & Neish, 1954)
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