• Satoko Kawauchi, Akemi Kono, Yuriko Muramatsu, Grant Hennes, Shuta Seki, Susumu Tominaga, Yasue Haruyama, Yukari Komuta, Izumi Nishidate, Susumu Matsukuma, Yushan Wang, and Shunichi Sato.
• National Defense Medical College, 13077, Division of Bioinformation and Therapeutic Systems, National Defense Medical College Research Institute, 3-2 Namiki, Tokorozawa, Tokorozawa, Saitama, Japan, 359-8513; satok-bits@ndmc.ac.jp.
• J. Neurotrauma. 2024 Mar 27.

AbstractIn the past decade, signature clinical neuropathology of blast-induced traumatic brain injury has been under intense debate, but interface astroglial scarring (IAS) seems to be convincing. In this study, we examined whether IAS could be replicated in the rat brain exposed to a laser-induced shock wave(s) (LISW[s]), a tool that can produce a pure shock wave (primary mechanism) without dynamic pressure (tertiary mechanism). Under certain conditions, we observed astroglial scarring in the subpial glial plate (SGP), grey-white matter junctions (GM-WM), ventricular wall (VW) and regions surrounding cortical blood vessels, accurately reproducing clinical IAS. We also observed shock wave impulse-dependent meningeal damage (dural microhemorrhage) in vivo by transcranial near-infrared reflectance imaging. Importantly, there were significant correlations between the degree of dural microhemorrhage and the extent of astroglial scarring more than 7 days post-exposure, suggesting an association of meningeal damage with astroglial scarring. The results demonstrated that the primary mechanism alone caused the IAS and meningeal damage, both of which are attributable to acoustic impedance mismatching at multilayered tissue boundaries. The time course of glial fibrillary acidic protein (GFAP) immunoreactivity depended not only on the LISW conditions but also on the regions. In the SGP, significant increases in GFAP immunoreactivity were observed at 3 days post-exposure, while in the GM-WM and VW, GFAP immunoreactivity was not significantly increased before 14 days post-exposure, suggesting different pathological mechanisms. With the high-impulse single exposure or the multiple exposure (low impulse), fibrotic reaction or fibrotic scar formation was observed, in addition to astroglial scarring, in the cortical surface region. Although there are some limitations, this seems to be the first report on the shock wave-induced IAS rodent model. The model may be useful to explore potential therapeutic approaches for IAS.

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