Litcius/Paper detail

Membrane stabilization <i>versus</i> perturbation by aromatic monoamine-modified γ-PGA for cryopreservation of human RBCs with high intracellular trehalose

Qingjing Niu, Shuhui Gao, Xingwen Liu, Jinghui Chong, Lixia Ren, Kongying Zhu, Wenxiong Shi, Xiaoyan Yuan

2022Journal of Materials Chemistry B15 citationsDOI

Abstract

membrane perturbation. The self-assembled nanoparticles of the obtained amphiphilic γ-PGA could be adsorbed on the cell membrane by the hydrophobic interaction to disturb the lipid arrangement and increase the membrane permeability of trehalose under hypertonic conditions. Results suggested that the intracellular trehalose could be enhanced progressively with the methylene spacer length, significantly increasing to 75.1 ± 0.7 mM by incubating hRBCs in 0.8 M trehalose containing phenylbutylamine-grafted γ-PGA at 4 °C for 24 h. Meanwhile, the other three polymers exhibited membrane stabilization in addition to improved intracellular trehalose, maintaining the membrane integrity during cryopreservation to achieve high cryosurvival. Molecular dynamics simulation further confirmed that defects could be formed by interaction of the above four amphiphilic polymers on the modeled phospholipid bilayer. It was believed that glycerol-free cryopreservation of human cells could be realized by using trehalose as the biocompatible cryoprotectant, and membrane stabilization can be a compensatory approach to membrane perturbation during impermeable biomolecule delivery.

Topics & Concepts

TrehaloseCryopreservationIntracellularMembraneMonoamine neurotransmitterBiophysicsMaterials scienceChemistryBiochemistryCell biologyBiologyEmbryoSerotoninReceptorPancreatic function and diabetesErythrocyte Function and PathophysiologySperm and Testicular Function
Membrane stabilization <i>versus</i> perturbation by aromatic monoamine-modified γ-PGA for cryopreservation of human RBCs with high intracellular trehalose | Litcius