Food Biotechnology
Zohre Noruzi Motlagh; Mahmoud A. Mahdavi; Reza Gheshlaghi
Abstract
Introduction Carotenoids have many effects on human health. These compounds are produced by plants and microalgae. The extraction of carotenoids from microalgae such as Chlorella has received much attention, since microalgae grow all year round (regardless of the season) and at a much faster rate ...
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Introduction Carotenoids have many effects on human health. These compounds are produced by plants and microalgae. The extraction of carotenoids from microalgae such as Chlorella has received much attention, since microalgae grow all year round (regardless of the season) and at a much faster rate than plants in non-arable lands. The aim of this research was to optimize the concentrations of nutrients (nitrogen and phosphorous) in the growth medium of microalgae with the objective of maximizing carotenoids content. At the optimized nutrient conditions, the effect of phytohormones on production of carotenoids using Chlorella sorokiniana IG-W-96 was investigated. Materials and MethodsChlorella sorokiniana IG-W-96 was cultivated in BG11 growth medium with light intensity of 25000 lux and light: dark cycle of 16: 8 supplied with compressed air flow of 0.5 vvm containing 6% vol carbon dioxide. Under three concentrations of nitrate (0.04, 0.25, 1.5 ) and three concentrations of phophate (0.01, 0.04, 0.16 ) and carotenoid concentration was measured. Full factorial experimnetal design was performed and the resuts of the experiments were analyzed using Minitab (ver. 21.01.1). Finally, the best concentrations of nitrate and phosphate were chosen for pigments production, and at that concentration, naphthalene acetic acid (0, 2.5, 5, 7.5, 10 and 12 ppm) was added to the culture medium to check its effect on pigments production. By measuring the dry weight of C. sorokiniana, its growth rate was determined. After extracting the pigments with solvent, the concentration of the pigments was determined by measuring the amount of light absorption. Results and DiscussionDry weightThe results showed that the highest amount of dry weight was related to the treatment with nitrate amount of 0.25 , and nitrate more and less than this amount caused a decrease in growth. This result was not dependent on the amount of phosphate and was true for all phosphate concentrations. Nitrate reduction from 1.5 to 0.25 increased the growth of microalgae up to 81.8%, so that the dry weight of 0.88 reached 1.6 . However, reduction of nitrate from 0.25 to 0.04 decreased the dry weight by 65.6%. In order to reach the maximum growth rate, it is necessary to determine the appropriate concentration of each nutrient. CarotenoidsUnlike the dry weight, not only the pigment production did not decrease with the excessive of nitrate concentration, but also the maximum amount of pigment production was related to the treatment with the maximum amount of nitrate concentration. Based on the results obtained, the concentration of carotenoids was higher in the concentration of 1.5 of nitrate and 0.04 of phosphate (6.7 ).When the nitrate concentration was very low (0.04 ), changing the phosphate concentration had no significant effect on the production rate of any of the pigments. Only when the nitrate concentration was high (1.5 ), change in phosphate concentration caused a change in pigments concentration. The increase of phosphate concentration from 0.01 to 0.04 increased the carotenoids concentration to 1.65-fold. Of course, increasing phosphate concentration to 0.16 did not affect the pigments concentration. Based on the statistical analysis, the P-value<0.05 indicated that the effect of the factors and the model was significant. In this situation, in order to increase the production of carotenoids, naphthalene acetic acid was added to the phytohormone culture medium. At the optimal concentration of 2.5 ppm of naphthalene acetic acid, the concentration of carotenoids increased by 26.71% and reached 8.49 . However, phytohormone had no significant effect on dry weight. ConclusionCarotenoid production using microalgae could be maximized through optimization of nutrients concentrations (nitrate and phosphate) in the growth medium. Phytohormones could further increase the prodcution of carotenoids at optimum concnetrations.
Food Chemistry
Zeinab Soltan Touyeh; Shiva Dehghan Abkenar; Nazanin Khakipour
Abstract
Introduction Rice as a staple food, especially in Asian countries, can be a major source of heavy metals. Heavy metals also enter the soils where crops grow naturally and / or through human activities. Metals are absorbed and accumulated in the edible parts of the plant and enter the food ...
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Introduction Rice as a staple food, especially in Asian countries, can be a major source of heavy metals. Heavy metals also enter the soils where crops grow naturally and / or through human activities. Metals are absorbed and accumulated in the edible parts of the plant and enter the food chain. Toxic metals, which are present in nature due to industrialization, have polluted the environment, including soil, air, water and food, and have adverse effects on human health through food chains. The Codex Organization has set maximum levels for these elements in various cereals to protect trade and health. Nitrate and nitrite are naturally present in soil, water and food. But today, foods have higher levels of nitrate and nitrite. Excessive use of nitrogen fertilizers to achieve higher yields and improper disposal of human and animal wastes may lead to nitrate accumulation in agricultural products. Very few studies have been performed on the measurement of heavy metal and nitrogen indices in replanted rice. The aim of this study was to measure the amounts of heavy metals (lead, cadmium and arsenic) and the amounts of nitrate and nitrite in first harvest rice and re-harvest rice and compare it with the standard values of the World Health Organization. Methods and Materials In this study, a total of 18 rice samples were prepared from three selected farms in the first and second cultivation times and the amount of nitrite, nitrate and heavy metals lead, cadmium, arsenic and mercury were evaluated. Results and Discussion The results showed that in all farms in the second crop the concentration of lead decreased significantly (P<0.05). The concentration of lead in all treatments of the first crop Has been more than allowed and in the second cultivation, the treatment of field number one and two, is more than allowed (P<0.05). The concentration of cadmium in all treatments is within the allowable range and in the second crop compared to the first crop of fields number one and three has a significant decrease and in field number two has increased significantly (P <0.05). The highest amount of cadmium is related to field treatments number three. The highest amount of arsenic was observed in the first crop of farm number one and it is more than the allowable limit and in other treatments the amount of arsenic was less than the allowable level and in all three farms the concentration of arsenic in the second crop was significantly reduced compared to the first crop. Regarding mercury, in fields number one and two, with the change of cultivation, the amount of mercury increased significantly and in field number three, there was a significant decrease (P <0.05). Mercury concentration is less than the allowable limit only in the second culture sample of farm number three. Nitrite and nitrate concentrations were also low in all treatments and were considered zero. Experiments showed the amount of nitrite and nitrate in all samples to be negligible and undetectable. Due to the fact that the detection limit of the method (LOQ) used to measure nitrate and nitrite is 100 ppb, the amount of nitrate and nitrite in all samples can be less than 100 ppb. The permissible level of nitrate in food products and rice grains is set at 50 mg/kg according to national standard 16596. The results of the samples showed that all 18 samples had lower amounts of nitrate than the allowable limit. Therefore, rice samples prepared from the first and second crops, their nitrate content is less than the allowable limit and have a complete degree of health. Conclusion According to the results obtained, all rice cultivated in the first and second crops have some arsenic, cadmium and lead, but the amount measured in some samples is less and in others, more than specified in the national standard of Iran. their consumption may be dangerous for consumers. These results also indicate that due to the stability of the field and plant type, there is a positive and significant relationship between the amount of heavy metals studied in rice and the time of cultivation, and this requires further studies on heavy metal contamination in the region. Take place. Therefore, with the conducted studies, it can be concluded that there are concerns in the consumption of rice cultivated in the city of Mazandaran province, in terms of the possibility of endangering the health of consumers.
