2024
DOI: 10.1039/d3en00353a
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The effect of nanoparticle surface charge on freshwater algae growth, reproduction, and lipid production

Emma McKeel,
Hye-In Kim,
Su-Ji Jeon
et al.

Abstract: Using functionalized carbon dots as models, positively charged nanoparticles were found to cause growth inhibition and aggregation in microalgae. Negative and near-neutral negative particles were associated with morphological changes.

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Cited by 2 publications
(1 citation statement)
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“…For this purpose, different cellular and sub-cellular targets/endpoints have been considered (Fig. 4), such as (1) size/biovolume and shape Soares 2014, 2020;Ostovich et al 2023;McKeel et al 2024); (2) membrane integrity (viability) (Nagai et al 2011;Soares 2012a, 2015b); (3) metabolic (esterase) activity (Debenest et al 2012;Machado and Soares 2013;Peng et al 2019;Ciccia et al 2023); (4) macromolecules content and distribution: proteins, carbohydrates, and lipids (Moreira et al 2020;Ciccia et al 2023;Ostovich et al 2023); (5) photosynthetic performance and pigment content (chla, chlb, and carotenoids) (Debenest et al 2012;Peng et al 2019;Almeida et al 2021;dos Reis et al 2022); (6) cell cycle and DNA content (Machado and Soares 2014;Sousa et al 2018;Almeida et al 2019Almeida et al , 2021); (7) mitochondrial membrane potential (Machado and Soares 2015a;Almeida et al 2019;Ciccia et al 2023); (8) oxidative stress assessment: ROS production, enzymatic (superoxide dismutase and catalase activity) and non-enzymatic (reduced glutathione) defenses and lipid peroxidation Soares 2012b, 2021b;Almeida et al 2019;Filová et al 2021); and (9) molecular (transcriptomic and metabolomics) analysis (Guo et al 2021;Mizukami-Murata et al 2021;Gómez-Martínez et al 2023).…”
Section: Cellular and Sub-cellular Targetsmentioning
confidence: 99%
“…For this purpose, different cellular and sub-cellular targets/endpoints have been considered (Fig. 4), such as (1) size/biovolume and shape Soares 2014, 2020;Ostovich et al 2023;McKeel et al 2024); (2) membrane integrity (viability) (Nagai et al 2011;Soares 2012a, 2015b); (3) metabolic (esterase) activity (Debenest et al 2012;Machado and Soares 2013;Peng et al 2019;Ciccia et al 2023); (4) macromolecules content and distribution: proteins, carbohydrates, and lipids (Moreira et al 2020;Ciccia et al 2023;Ostovich et al 2023); (5) photosynthetic performance and pigment content (chla, chlb, and carotenoids) (Debenest et al 2012;Peng et al 2019;Almeida et al 2021;dos Reis et al 2022); (6) cell cycle and DNA content (Machado and Soares 2014;Sousa et al 2018;Almeida et al 2019Almeida et al , 2021); (7) mitochondrial membrane potential (Machado and Soares 2015a;Almeida et al 2019;Ciccia et al 2023); (8) oxidative stress assessment: ROS production, enzymatic (superoxide dismutase and catalase activity) and non-enzymatic (reduced glutathione) defenses and lipid peroxidation Soares 2012b, 2021b;Almeida et al 2019;Filová et al 2021); and (9) molecular (transcriptomic and metabolomics) analysis (Guo et al 2021;Mizukami-Murata et al 2021;Gómez-Martínez et al 2023).…”
Section: Cellular and Sub-cellular Targetsmentioning
confidence: 99%