Impact of Shock-Induced Cavitation Bubble Collapse on the Damage of Cell Membranes with Different Lipid Peroxidation Levels

et al. 2021

J. Phys. Chem. B

Self Cite

The difference between diseased and healthy cellular membranes in response to mechanical stresses is crucial for biology, as well as in the development of medical devices. However, the biomolecular mechanisms by which mechanical stresses interact with diseased cellular components remain largely unknown. In this work, we focus on the response of diseased cellular membranes with lipid peroxidation to high-speed tensile loadings. We find that the critical areal strain (ξ c , when the pore forms) is highly sensitive to lipid peroxidation. For example, ξ c of a fully oxidized bilayer is only 64 and 69% of the nonoxidized one at the stretching speed of 0.1 and 0.6 m/s, respectively. ξ c decreases with the increase in the oxidized lipid ratio, regardless of the speeds. Also, the critical rupture tension of membranes exhibits a similar change. It is obvious that the oxidized membranes are more easily damaged than normal ones by high-speed stretching, which coincides with experimental findings. The reason is that peroxidation introduces a polar group to the tail of lipids, increases the hydrophilicity of tails, and warps the tails to the membrane− water interface, which causes loose accumulation and disorder of lipid tails. This can be deduced from the variation in the area per lipid and order parameter. In addition, the lowering stretching modulus and line tension of membranes (i.e., softening) after lipid peroxidation is also a significant factor. We reveal the difference between the peroxidized (diseased) and normal membrane in response to high-speed stretching, give the ξ c value in the pore formation of membranes and analyze the influence of the stretching speed, peroxidation ratio, and molecular structure of phospholipids. We hope that the molecular-level information will be useful for the development of biological and medical devices in the future.

Section: Resultsmentioning

confidence: 99%

Impact of Lipid Peroxidation on the Response of Cell Membranes to High-Speed Equibiaxial Stretching: A Computational Study

et al. 2021

J. Phys. Chem. B

Self Cite

“…19,20 For membranes, more studies have focused on the effects of shock waves and bubbles due to the use of one-component models. [21][22][23] Based on multi-component models, a small number of studies have revealed the influence of components such as cholesterol 24 or peroxidized phospholipid 25 on the response of membranes to shock. In fact, typical plasma membranes (PM) contain hundreds of different lipids.…”

Section: Introductionmentioning

confidence: 99%

Focal opening of the neuronal plasma membrane by shock-induced bubble collapse for drug delivery: a coarse-grained molecular dynamics simulation

Phys. Chem. Chem. Phys.

et al. 2022

Self Cite

“…If structural damage recovers slowly, it will evolve into more severe features such as pericyte detachment, astrocyte end-feet swelling or loss, and disrupted capillary basement membrane . Therefore, we perform the recovery simulation (100 ns) with the NPzAT ensemble as before . According to the analysis of helical content and RMSD (Figure S8), only compression damage (single shockwave) can recover in 100 ns.…”

Section: Resultsmentioning

confidence: 99%

“…11 Therefore, we perform the recovery simulation (100 ns) with the NPzAT ensemble as before. 18 According to the analysis of helical content and RMSD (Figure S8), only compression damage (single shockwave) can recover in 100 ns. Protein damage subjected to shock-induced cavitation does not recover appreciably within the limited MD simulation time.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…Molecular dynamics (MD) simulations have developed into a powerful tool for providing detailed molecular pictures involved in biological processes, − based on the underlying models. Anatomically, the BBB is composed of endothelial cells, tight junctions (TJs) between endothelial cells, basement membrane, pericyte, and astrocyte end feet.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

How Shockwaves Open Tight Junctions of Blood–Brain Barrier: Comparison of Three Biomechanical Effects

et al. 2022

J. Phys. Chem. B

Self Cite

Revealing how blast shockwaves open the tight junction of the blood–brain barrier (BBB) is very important for understanding blast-induced traumatic brain injury (bTBI) and shockwave-assisted drug delivery; however, the underlying mechanism remains unresolved. Here, we used multiscale molecular dynamics simulations to reveal the disruption mechanism of claudin-5 protein in a relatively complex BBB model by comparing three typical effects from blast loads. The results showed that the opening of claudin-5 did not result from the direct compressive loading of the single shockwave but from indirect cavitation and stretching effects induced by shockwaves. Importantly, stretch-mediated mechanical opening from the asymmetric distribution of overpressure in temporal and spatial dimensions is a novel damage mode. In detail, the nanojet from the cavitation pushed away two adjacent endothelial cell membranes and the embedded claudin-5 was rapidly stretched. Even α-helix showed a drastic conformational breakdown and its content was only 15.9%. Structural changes of this magnitude are difficult to repair in a short time, which may be related to chronic BBB dysfunction and persistent neurological deficits. This is a more common injury, since the tensile response of membranes to blast loads is relatively common. Taken together, we provided a biomechanical underpinning for acute disruption of tight junction proteins in BBB from exposure to blast shockwaves, and this may be helpful as a therapeutic strategy for bTBI.