Silveira Júnior Arialdo M, Faustino Silvia Maria Mathes, Holanda Fabrício Holanda E, Ferreira Irlon Maciel, da Cunha Alan Cavalcanti
Department of Environment and Development, Federal University of Amapá, Macapá, Amapá, Brazil.
Postgraduate Program in Tropical Biodiversity, Federal University of Amapá, Macapá, Amapá, Brazil.
PeerJ. 2025 Aug 11;13:e17879. doi: 10.7717/peerj.17879. eCollection 2025.
The aim of the present study is to assess the kinetic growth and yield of microalgae belonging to the species (Kützing, 1833) grown under different macronutrient concentrations (N:P:K), pH and temperature. A three-level three-variable Box-Behnken factorial design was developed to test the influence of environmental factors on the growth parameters applied to a microalgal crop, namely: maximum cell density (N), specific growth rate (µ, d), doubling time (T) and maximum yield (P). A classical logistic growth model was applied to estimate the kinetic behavior of a culture in comparison to other studies in the literature. Maximum cell density (N) significantly changed between 32.3 ± 0.84 and 101.5 ± 12.5 × 105 cells mL ( = 0.004). Specific growth rates (µ) and P showed significant mean variations between 0.28 ± 0.10 day and 6.21 ± 4.57 cells mL d, respectively. All growth curves were adjusted to the proposed logistic model and range variation was (0.65 ≤ r ≤ 0.99, = 0.01). Maximum microalgae cell density per crop was found at temperature of 24 °C (N = 49.0 × 105 cells mL) ( = 0.01), in 20 mL Nitrogen, Phosphorus, and Potassium (NPK) dilution (N = 46.5 × 105 cells mL) ( = 0.02). Despite the significant variation in pH values (5.0 ≤ pH ≤ 9.0, = 0.05), it did not have strong influence on plant growth responses. In conclusion, the kinetic study applied to growth and yield parameters emerged as reference for this species' kinetic behavior and bioprospecting under controlled and experimentally standardized conditions, and as support for pilot projects on bioreactors.
本研究的目的是评估在不同常量营养素浓度(氮:磷:钾)、pH值和温度条件下生长的(Kützing,1833)微藻的动力学生长和产量。开发了一种三水平三变量的Box-Behnken析因设计,以测试环境因素对应用于微藻作物的生长参数的影响,这些参数包括:最大细胞密度(N)、比生长速率(µ,d)、倍增时间(T)和最大产量(P)。与文献中的其他研究相比,应用经典逻辑生长模型来估计培养物的动力学行为。最大细胞密度(N)在32.3±0.84和101.5±12.5×10⁵个细胞/mL之间有显著变化(P = 0.004)。比生长速率(µ)和P分别在0.28±0.10天和6.21±4.57个细胞/mL·天之间有显著的平均变化。所有生长曲线都符合所提出的逻辑模型,范围变化为(0.65≤r≤0.99,P = 0.01)。每批作物的最大微藻细胞密度在24℃时测得(N = 49.0×10⁵个细胞/mL)(P = 0.01),在20 mL氮、磷、钾(NPK)稀释液中测得(N = 46.5×10⁵个细胞/mL)(P = 0.02)。尽管pH值有显著变化(5.0≤pH≤9.0,P = 0.05),但对植物生长反应没有强烈影响。总之,应用于微藻生长和产量参数的动力学研究成为该物种在受控和实验标准化条件下的动力学行为和生物勘探的参考,并为生物反应器试点项目提供支持。
