Molecular dynamics simulations of heterogeneous cell membranes in response to uniaxial membrane stretches at high loading rates

Zhang, Lili; Zhang, Zesheng; Jasa, John; Li, Dongli; Cleveland, Robin O.; Negahban, Mehrdad; Jérusalem, Antoine

doi:10.1038/s41598-017-06827-3

Cited by 15 publications

(15 citation statements)

References 98 publications

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“…54 This force field has recently been used for all-atom simulations of RNA 36 and lipids. 55,56 For DML, charge distribution was described by the Gasteiger method. 57 Solvent was described explicitly by the SPC/E model for water.…”

Section: Simulation Methodsmentioning

confidence: 99%

Complexation of single stranded RNA with an ionizable lipid: an all-atom molecular dynamics simulation study

Rissanou

Karatasos

2020

Soft Matter

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Section: Simulation Methodsmentioning

confidence: 99%

Complexation of single stranded RNA with an ionizable lipid: an all-atom molecular dynamics simulation study

Rissanou

Karatasos

2020

Soft Matter

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“…However, their model does not include the time dependency of the pore formation process. The dependency of critical pore formation strain on the applied loading rate has been reported both by experimental (27,38) and numerical (23,24,39) studies. The implicit-solvent, head-tail model of Cooke et al (34) is another mesoscale approach that was successfully used to model the lipid membrane mechanical properties and pore formation (34,40,41).…”

Section: Introductionmentioning

confidence: 97%

Coarse-Grained Modeling of Pore Dynamics on the Red Blood Cell Membrane under Large Deformations

Razizadeh

Nikfar

Paul

et al. 2020

Biophysical Journal

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Transient pore formation on the membrane of red blood cells (RBCs) under high mechanical tensions is of great importance in many biomedical applications, such as RBC damage (hemolysis) and mechanoporation-based drug delivery. The dynamic process of pore formation, growth, and resealing is hard to visualize in experiments. We developed a mesoscale coarse-grained model to study the characteristics of transient pores on a patch of the lipid bilayer that is strengthened by an elastic meshwork representing the cytoskeleton. Unsteady molecular dynamics was used to study the pore formation and reseal at high strain rates close to the physiological ranges. The critical strain for pore formation, pore characteristics, and cytoskeleton effects were studied. Results show that the presence of the cytoskeleton increases the critical strain of pore formation and confines the pore growth. Moreover, the pore recovery process under negative strain rates (compression) is analyzed. Simulations show that pores can remain open for a long time during the high-speed tank-treading induced stretching and compression process that a patch of the RBC membrane usually experiences under high shear flow. Furthermore, complex loading conditions can affect the pore characteristics and result in denser pores. Finally, the effects of strain rate on pore formation are analyzed. Higher rate stretching of membrane patch can result in a significant increase in the critical areal strain and density of pores. Such a model reveals the dynamic molecular process of RBC damage in biomedical devices and mechanoporation that, to our knowledge, has not been reported before.

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“…It is a logical extension that blast-type loading, which occurs over a much shorter time scale compared to conventional (impact) TBI (microseconds vs. milliseconds) and induces loading at higher strain rates, should thus differ in the resultant injury profile to cells and tissue. We have recently predicted some mechanical effects of such high-rate blast injuries at the cellular 45 and molecular level 46 , but supporting experimental data is lacking in the current body of bTBI literature. It is important to note that blast and conventional TBI often (though not exclusively) occur together, and as such may be difficult to distinguish clinically in many cases due to limitations of current diagnostic tools.…”

Section: Discussionmentioning

confidence: 87%

Cognition based bTBI mechanistic criteria; a tool for preventive and therapeutic innovations

Garcia‐Gonzalez

Race

Voets

et al. 2018

Sci Rep

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Blast-induced traumatic brain injury has been associated with neurodegenerative and neuropsychiatric disorders. To date, although damage due to oxidative stress appears to be important, the specific mechanistic causes of such disorders remain elusive. Here, to determine the mechanical variables governing the tissue damage eventually cascading into cognitive deficits, we performed a study on the mechanics of rat brain under blast conditions. To this end, experiments were carried out to analyse and correlate post-injury oxidative stress distribution with cognitive deficits on a live rat exposed to blast. A computational model of the rat head was developed from imaging data and validated against in vivo brain displacement measurements. The blast event was reconstructed in silico to provide mechanistic thresholds that best correlate with cognitive damage at the regional neuronal tissue level, irrespectively of the shape or size of the brain tissue types. This approach was leveraged on a human head model where the prediction of cognitive deficits was shown to correlate with literature findings. The mechanistic insights from this work were finally used to propose a novel protective device design roadmap and potential avenues for therapeutic innovations against blast traumatic brain injury.

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Molecular dynamics simulations of heterogeneous cell membranes in response to uniaxial membrane stretches at high loading rates

Cited by 15 publications

References 98 publications

Complexation of single stranded RNA with an ionizable lipid: an all-atom molecular dynamics simulation study

Complexation of single stranded RNA with an ionizable lipid: an all-atom molecular dynamics simulation study

Coarse-Grained Modeling of Pore Dynamics on the Red Blood Cell Membrane under Large Deformations

Cognition based bTBI mechanistic criteria; a tool for preventive and therapeutic innovations

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