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

Tong Wei, Mi Zhou, Lingzhi Gu, Yang Zhou, Ming Li

2022The Journal of Physical Chemistry B14 citationsDOI

Abstract

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.

Topics & Concepts

Tight junctionBlood–brain barrierMaterials scienceMechanism (biology)Traumatic brain injuryOverpressureBiophysicsNeuroscienceMedicineCell biologyBiologyCentral nervous systemPhysicsQuantum mechanicsPsychiatryThermodynamicsTraumatic Brain Injury and Neurovascular DisturbancesHemoglobin structure and functionBarrier Structure and Function Studies
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