Alteration in Zeta Potential of Erythrocytes in Preeclampsia Patients

Karemore, Megha N.; Avari, Jasmine G.

doi:10.5772/intechopen.85952

Cited by 2 publications

(2 citation statements)

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“…The electrokinetic (zeta) potential, an electrochemical property of erythrocyte surfaces, is determined by the net electrical charge of surface-exposed molecules. The surfaces of erythrocyte membranes carry a net negative charge at a neutral pH, and sialic acid residues are responsible for most of the negative charges on the cell surface ( Mehrishi and Bauer, 2002 ; Karemore and Avari, 2019 ; Doltchinkova et al, 2021 ). The erythrocyte membrane is surrounded by a fixed layer of cations and coions in the medium (Galassi and Wilke, 2021) by a diffuse double layer (DDL) of a mixture of cations and anions.…”

Section: Introductionmentioning

confidence: 99%

Electrokinetic properties of healthy and β-thalassemia erythrocyte membranes under in vitro exposure to static magnetic field

Doltchinkova,

Lozanova,

Rukova

et al. 2023

Front. Chem.

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Introduction: The current understanding of the biological impacts of a static magnetic field (SMF) is restricted to the direct interactions of the magnetic field with biological membranes. The electrokinetic (zeta) potential is an electrochemical property of erythrocyte surfaces which was negatively charged in physiological media after SMF exposure (0.1‒2.0 T).Methods: The novel data about electrokinetic parameters of the erythrocytes is determined by microelectrophoresis after SMF-exposure in norm and heterozygous β-thalassemia. The methods of light scattering, lipid peroxidation, fluorescence microscopy are used.Results: The electrokinetic potential of erythrocytes in norm is increased after SMF intensities due to enhanced negatively exposed charges on the outer surface of the membrane accompanied by an increase in light scattering where changes in cell morphology are observed. Conversely, a decrease in the zeta potential of β-thalassemia erythrocytes upon SMF-treatment was determined because of the reduction in the surface electrical charge of the membranes, where a significant decrease in light scattering at 1.5 T and 2.0 T was recorded. Exposure to SMF (0.5–2.0 T) was associated with an increase in the malondialdehyde content in erythrocytes. Biophysical studies regarding the influence of SMF on the electrostatic free energy of cells shows an increase in negative values in healthy erythrocytes, which corresponds to the implementation of a spontaneous process. This is also the process in β-thalassemia cells after SMF exposure with lower negative values of free electrostatic energy than erythrocytes in norm.Discussion: The effect of static magnetic field (SMF 0.1–2.0 T) on the electrokinetic and morphological characteristics of erythrocytes in norm and β-thalassemia is determined and correlated with the increase/reduction in surface charge and shrinkage/swelling of the cells, respectively. Lipid peroxidation of healthy and β-thalassemia erythrocytes caused an enhancement of lipid peroxidation because of the higher concentrations of TBARS products in cellular suspension. SMF (0.1‒2.0 T) altered the spontaneous chemical processes with negative values of electrostatic free energy of erythrocytes in norm and β-thalassemia accompanied by a lower FITC-Concanavalin A binding affinity to membrane receptors (SMF 2.0 T). The electrokinetic properties of human erythrocytes in norm and β-thalassemia upon SMF treatment and their interrelationship with the structural-functional state of the membrane were reported. The presented work would have future fundamental applications in biomedicine.

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Section: Introductionmentioning

confidence: 99%

Electrokinetic properties of healthy and β-thalassemia erythrocyte membranes under in vitro exposure to static magnetic field

Doltchinkova,

Lozanova,

Rukova

et al. 2023

Front. Chem.

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“…Important as structural models of membrane organization, erythrocytes carry negative surface electrical charge at physiological pH due to carboxyl groups of sialic acids in the cell membrane. This charge varies in different disease condition which can be determined by electrokinetic potential values [5]. The negative charges on the cells prevent erythrocyte aggregation and participate in immunohematological reactions [6].…”

Section: Introductionmentioning

confidence: 99%