神经科学
体内
神经干细胞
内生
硬脑膜
创伤性脑损伤
生物医学工程
移植
再生(生物学)
生物神经网络
脊髓损伤
植入
医学
刺激
干细胞
中枢神经系统
神经组织工程
材料科学
神经假体
组织工程
再生医学
体外
电生理学
化学
超声波
脊髓
作者
Pengbo Zhou,Qingyuan Wu,Yang Wu,R. Stephanie Huang,Wei Li,Hanjie Niu,Hongtao Sun,Huiyu Liu
标识
DOI:10.1002/advs.202524326
摘要
Endogenous neuronal differentiation of neural stem cells (NSCs) is a promising route to restore function after traumatic brain injury (TBI), but direct transplantation of exogenous NSCs faces practical and immunological barriers and yields limited neuronal maturation. Here, a clinically relevant strategy is reported that converts a dura mater into an active piezoelectric patch to noninvasively drive endogenous NSC neurogenesis. Electrospun poly(L‑lactic acid) (PLLA) patches were subjected to surface confinement crystallization on metal substrates, producing a metastable α' crystal structure and markedly enhanced piezoelectric output. Under low‑intensity transcranial ultrasound, the treated patch generates reproducible pulsed electrical signals that remodel the local injury microenvironment. In vitro and in vivo assays show that ultrasound‑activated patches increase neuronal lineage differentiation (neurons/astrocytes ratio increased ∼9.6‑fold at 14 days) and promote greater neuronal maturation, while concomitantly modulating the immune milieu. In a rat TBI model, daily 2‑min ultrasound stimulation delivered via the patch substantially accelerated tissue repair and improved behavioral and cognitive outcomes compared with untreated controls. This work demonstrates a simple, scalable modification of clinical artificial dura mater to produce a soft, biodegradable piezoelectric implant capable of remote, noninvasive electrical modulation of endogenous NSCs, with broad implications for neural regeneration and potential clinical translation.
科研通智能强力驱动
Strongly Powered by AbleSci AI