Modeling of Dynamics of Nitrogenous Compounds in Microalgae Cells. 1. Batch Culture

Тренкеншу, Р. П.; Lelekov, Alexander S.

doi:10.17537/2018.13.348

Cited by 4 publications

(2 citation statements)

References 16 publications

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“…Processes 2023, 11, x FOR PEER REVIEW 7 of 14 treatment was calculated (according to Formula (1)), which for ammonium nitrogen was 75%, phosphates 52%, nitrites 94%, and sulfates 56% (Figure 2). In order to assess the quality of water purified from pollutants, final concentrations were compared with the permissible concentrations of pollutants in wastewater, established in order to prevent a negative impact on the operation of centralized sewage systems [64]. The result of post-treatment with microalgae shows high efficiency in the removal of biogenic elements and reaches the values of permissible concentrations for all substances except NH4 + .…”

Section: Resultsmentioning

confidence: 99%

Production of Biohydrogen from Microalgae Biomass after Wastewater Treatment and Air Purification from CO2

Velmozhina,

Shinkevich,

Zhazhkov

et al. 2023

Processes

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This article explores the feasibility of producing biohydrogen from microalgae following their use in wastewater purification from food industry facilities and the removal of high levels of carbon dioxide (CO2) from the air. The authors investigated various methods for disrupting the cell membranes of microalgae and their impact on biohydrogen yield. The microalgae biomass obtained after wastewater and air purification underwent pre-treatment using physicochemical and chemical methods, including microwave radiation, acid treatment, and thermal treatment. The highest hydrogen production occurred during thermal and acid treatments of biomass with the addition of starch (44.24 mL/L of suspension). The use of microwave radiation for processing did not yield significant results. A comparison of the biohydrogen values obtained from untreated and treated biomass revealed that treatment enhances biohydrogen yield.

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Section: Resultsmentioning

confidence: 99%

Production of Biohydrogen from Microalgae Biomass after Wastewater Treatment and Air Purification from CO2

Velmozhina,

Shinkevich,

Zhazhkov

et al. 2023

Processes

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“…Далее наблюдалась стабилизация плотности культуры, при этом численность клеток не менялась. Так как в питательную среду на второй ("красной") стадии выращивания не вносили биогенных элементов, то рост плотности культуры можно объяснить использованием внутриклеточных запасов, либо возвратом субстрата из распавшейся биомассы [14,20]. Динамика биомассы микроводорослей как в первом, так и во втором случае описывается экспоненциальным уравнением:…”

Section: модель 3 накопление вторичных каротиноидовunclassified

Modeling the Dynamics of Pigment Content in Cells of Dunaliella Salina Teod. Unicellular Alga at the Stage of Carotenogenesis

Lelekov¹,

Боровков²,

Новикова³

et al. 2019

Math.Biol.Bioinf.

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The work is focused on modeling of chlorophyll and carotenoids content dynamics in the in cells of the unicellular algae D. salina, living in salt water, at carotenogenesis induction phase. A mathematical model of pigments content in microalgae cells, which experience excess of light energy and the limit of nutrient medium mineral components, is proposed. The model is based on assumption, that observed rate of variation in pigment concentration is an algebraic sum of the rates of synthesis, photodestruction and partial recovery of photo-oxidized pigments. The rate of secondary carotenoids synthesis does not depend on external conditions and is determined by the quantity of key enzyme complex and its turnover rate. The rate of secondary carotenoids and chlorophyll photodestruction depends on the effective light intensity and is proportional to the amount of absorbed photosynthetically active radiation energy. The verification of the derived equations was conducted in the course of D. salina cultivation at the carotenogenesis stage. The specific rate of chlorophyll a photodestruction was determined, which resulted in 0.12 days–1. The secondary carotenoids concentration increases up to the maximum value, which is determined by the ratio of synthesis and photodestruction specific rates, as well as the maximum culture density. Under conditions of natural light in the Sevastopol region, the maximum concentration of carotenoids was 18.33 mg/l or 0.73 g/m2.

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Dynamics Modeling of Nitrogen Compounds in Microalgae Cells. 2. Chemostat

Lelekov¹,

Тренкеншу²

2019

Math.Biol.Bioinf.

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The work focuses on dynamics modeling of nitrogen compounds in microalgae cells under chemostat conditions. The analysis of classical models (Michaelis-Menten, Monod, Droop), which describe the kinetics of substrate-dependent growth of microalgae, was carried out. Classical models are shown to be applicable provided that the physicochemical parameters of the medium such as temperature, cell irradiation, etc are constant. As an alternative approach, the possibility of using linear splines in kinetics modeling of nitrate absorption by microalgae is shown. For the conditions of the chemostat, particular solutions for the generalized model of the dynamics of nitrogen compounds in the cells of microalgae considered in the first part of the work were obtained, and boundary conditions for the culture growth at unlimited nitrogen were determined. For limited growth, the equation for both the dependence of the specific growth rate on the intracellular nitrogen content, which coincides in form with the Droop model and the dependence of the specific growth rate on the extracellular concentration of nitrogen, which coincides in form with the Monod model were obtained. The species-specific coefficients of the equations such as the maximum specific rate of nitrogen absorption, the maximum specific rate of synthesis of structural components, the maximum content of reserve forms of nitrogen, the minimum share of structural forms of nitrogen in the total cell content were determined.

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Modeling of Dynamics of Nitrogenous Compounds in Microalgae Cells. 1. Batch Culture

Cited by 4 publications

References 16 publications

Production of Biohydrogen from Microalgae Biomass after Wastewater Treatment and Air Purification from CO2

Production of Biohydrogen from Microalgae Biomass after Wastewater Treatment and Air Purification from CO2

Modeling the Dynamics of Pigment Content in Cells of Dunaliella Salina Teod. Unicellular Alga at the Stage of Carotenogenesis

Dynamics Modeling of Nitrogen Compounds in Microalgae Cells. 2. Chemostat

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