The Molecular Structure of Human Red Blood Cell Membranes from Highly Oriented, Solid Supported Multi-Lamellar Membranes

Himbert, Sebastian; Alsop, Richard J.; Rose, Markus; Hertz, Laura; Dhaliwal, Alexander; Moran‐Mirabal, Jose M.; Verschoor, Chris P.; Bowdish, Dawn M. E.; Kaestner, Lars; Wagner, Christian; Rheinstädter, Maikel C.

doi:10.1038/srep39661

Cited by 55 publications

(70 citation statements)

References 79 publications

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“…DMPC, POPC, and POPS show a gradual increase in lamellar spacing and head–head distance with an increasing fraction of RBC membranes, as shown in Figures 3b,c. It converges to ≈56 Å for the d z ‐spacing and ≈44 Å for the head‐head distance, in good agreement with previously published measurements on red‐blood cell membranes 21…”

Section: Resultssupporting

confidence: 91%

“…The degree of order is quantified by fitting Herman's orientation function, as detailed in the Experimental Section. A degree of orientation between ≈82% and ≈97% was determined, in good agreement with previous studies on pure red blood cells,21 and on mono‐ or multicomponent synthetic membranes 22…”

Section: Resultssupporting

confidence: 90%

“…The preparation is based on a protocol first published by Himbert et al21 All blood samples were collected using sodium heparin coated venous blood collection tubes from BD (Product Number: BD 367874). The blood was washed twice and the RBC were isolated as described in ref.…”

Section: Methodsmentioning

confidence: 99%

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Hybrid Erythrocyte Liposomes: Functionalized Red Blood Cell Membranes for Molecule Encapsulation

et al. 2020

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The modification of erythrocyte membrane properties provides a new tool towards improved drug delivery and biomedical applications. The fabrication of hybrid erythrocyte liposomes is presented by doping red blood cell membranes with synthetic lipid molecules of different classes (PC, PS, PG) and different degrees of saturation (14:0, 16:0–18:1). The respective solubility limits are determined, and material properties of the hybrid liposomes are studied by a combination of X‐ray diffraction, epi‐fluorescent microscopy, dynamic light scattering (DLS), Zeta potential, UV‐vis spectroscopy, and Molecular Dynamics (MD) simulations. Membrane thickness and lipid orientation can be tuned through the addition of phosphatidylcholine lipids. The hybrid membranes can be fluorescently labelled by incorporating Texas‐red DHPE, and their charge modified by incorporating phosphatidylserine and phosphatidylglycerol. By using fluorescein labeled dextran as an example, it is demonstrated that small molecules can be encapsulated into these hybrid liposomes.

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Section: Resultssupporting

confidence: 91%

Section: Resultssupporting

confidence: 90%

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Hybrid Erythrocyte Liposomes: Functionalized Red Blood Cell Membranes for Molecule Encapsulation

et al. 2020

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“…[25] Anionic and zwitterionic unilamellar vesicles,A UVs and ZUVs,r espectively,p rovided microbial and mammalian membrane mimetics, [25,26] while weakly anionic AUVs (wAUVs) emulated erythrocytal membranes [27] (see the Supporting Information). [25] Anionic and zwitterionic unilamellar vesicles,A UVs and ZUVs,r espectively,p rovided microbial and mammalian membrane mimetics, [25,26] while weakly anionic AUVs (wAUVs) emulated erythrocytal membranes [27] (see the Supporting Information).…”

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confidence: 99%

Binary Encoding of Random Peptide Sequences for Selective and Differential Antimicrobial Mechanisms

et al. 2017

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Binary encoding of peptide sequences into differential antimicrobial mechanisms is reported. Such sequences are random in composition, but controllable in chain length, are assembled from the same two amino acids, but differ in the stereochemistry of one. Regardless of chirality, the sequences lyse bacteria including the "superbugs" methicillin-resistant Staphylococcus aureus (MRSA) and vancomycin-resistant Enterococci (VRE). Sequences with the same chirality, so-called homochiral sequences, assemble into antimicrobial pores and form contiguous helices that are biologically promiscuous and hemolytic. By contrast, heterochiral sequences that lack such persistence selectively attack bacterial membranes without oligomerizing into visible pores. These results offer a mechanistic rationale for designing membrane-selective and sequence-independent antimicrobials.

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“…The presence of this framework forms conditions for self-organization (self assembly) of biological tissues, which occurs without human interference, being supported by weak non-covalent (hydrogen, ion) bonds upon hydrophobic interaction of tissues. A similar organization of biological macro molecules in nature occurs, for example, in phospholipids, which are the main components of plasma cellular membranes 9 .…”

Section: Introductionmentioning

confidence: 91%

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2018

IJPSR

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Bulk nanocomposites prepared from aqueous albumin dispersion with carbon nanotubes by removing the liquid component from the dispersion have been investigated. The composites were obtained by thermostating and exposure to LED and IR diode laser radiation. The nanocomposites obtained under laser irradiation retain their shape and properties for several years, in contrast to the composites fabricated in different ways (which decompose into small fragments immediately after preparation). The low density of the composites under study (~1200 kg/m 3 ), which is close to the density of water, is due to their high porosity. The hardness of stable nanocomposites (~300 MPa) was found to be at the same level as the hardness of polymethylmethacrylate, aluminium, and iron and close to the hardness of human bone tissue. The cluster quasi ordering of the inner structure of nanocomposites revealed by atomic force microscopy indicates the possibility of forming a bulk nanotube framework in them, which can be caused by the effect of the electric field of laser radiation and ensure their stability and hardness. The presence of a framework in nanocomposites provides conditions for self-assembly of biological tissues and makes it possible to apply laser-prepared nanocomposites as a component of surgical implants.

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The Molecular Structure of Human Red Blood Cell Membranes from Highly Oriented, Solid Supported Multi-Lamellar Membranes

Cited by 55 publications

References 79 publications

Hybrid Erythrocyte Liposomes: Functionalized Red Blood Cell Membranes for Molecule Encapsulation

Hybrid Erythrocyte Liposomes: Functionalized Red Blood Cell Membranes for Molecule Encapsulation

Binary Encoding of Random Peptide Sequences for Selective and Differential Antimicrobial Mechanisms

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