RESUMO
Marine microalgae have been reported as an excellent source of bioactive compounds. The present study analyzesthe existence of bioactive phytochemicals and their efficacy in antimicrobial activity against aquatic pathogens.The antimicrobial compounds were extracted from three marine microalgae, namely Chlorella sp., Pavlova sp., andChaetoceros sp., and Pavlova sp. showed a broad spectrum of activity. Pavlova sp. extracts were tested against theselected aquatic pathogens, such as Vibrio harveyi, Vibrio parahaemolyticus, Pseudomonas aeroginosa, Aeromonashydrophila, and Staphylococcus aureus, and the result showed the inhibiting activity against aquatic pathogens. Theminimum inhibitory concentration and minimum bactericidal concentration, cytotoxic assay, and mode of actionwere also studied. The effective five crude extracts were purified by column chromatography and tested against thepathogens; then, the active fraction was partially characterized by Fourier transform infrared (FTIR) analysis. TheFTIR result suggested the presence of bioactive groups, such as amines, alkane, carboxylic acid, sulfoxide, alcohol,boron, etc. From the five extracts, two active extracts were selected and subjected to TLC (Thin layer chromatography).The cytotoxic activity (LD-50) indicates that the compound may be safe and effective for clinical trial. Finally, thealgal cytotoxic assay concluded that the isolated compound can also be used as an algicide to control algal blooms.This study proves that Pavlova sp. is an excellent source of pharmacologically active resourceful algae and showseffective activity against aquatic pathogens.
RESUMO
Microalgae produce a wide range of compounds including pigments, protein, starch, and lipids, which havebeen extensively used for various applications. In the current scenario, microalgal lipids are considered as apromising source for the production of next-generation bioenergy, and a huge productivity is needed to meet thedemand. Thus, to increase the production of biomass and lipid content, physical conditions play an importantrole and necessary to be optimized. The present study made such an attempt to optimize the physical factors forthe growth and production of lipid from Nannochloropsis gaditana. The study aimed to determine the effect ofphysical parameters such as pH, temperature, light intensity, and salinity. The results showed that the maximumgrowth rate of the N. gaditana was noticed in the salinity of 25 ppt, pH of 8, temperature of 25°C, and 2,000 luxof light intensity. The highest lipid content of the N. gaditana was noticed in the salinity of 30 ppt, pH of 8, andtemperature of 30°C with 2,000 lux light intensity. After optimization, above 40% of lipid yield was obtained,and it can be effectively utilized in bioenergy production.