Engineering 3D Scaffold‐Free Nanoparticle‐Laden Stem Cell Constructs for Piezoelectric Enhancement of Human Neural Tissue Formation and Function

脚手架 组织工程 纳米颗粒 压电 功能(生物学) 纳米技术 材料科学 神经干细胞 神经组织工程 干细胞 生物医学工程 工程类 细胞生物学 复合材料 生物
作者
Emma Claire James,Eva Tomaskovic‐Crook,Jeremy M. Crook
出处
期刊:Advanced Science [Wiley]
卷期号:11 (40): e2310010-e2310010 被引量:14
标识
DOI:10.1002/advs.202310010
摘要

Electrical stimulation (ES) of cellular systems can be utilized for biotechnological applications and electroceuticals (bioelectric medicine). Neural cell stimulation especially has a long history in neuroscience research and is increasingly applied for clinical therapies. Application of ES via conventional electrodes requires external connectors and power sources, hindering scientific and therapeutic applications. Here engineering novel 3D scaffold-free human neural stem cell constructs with integrated piezoelectric nanoparticles for enhanced neural tissue induction and function is described. Tetragonal barium titanate (BaTi03) nanoparticles are employed as piezoelectric stimulators prepared as cytocompatible dispersions, incorporated into 3D self-organizing neural spheroids, and activated wirelessly by ultrasound. Ultrasound delivery (low frequency; 40 kHz) is optimized for cell survival, and nanoparticle activation enabled ES throughout the spheroids during differentiation, tissue formation, and maturation. The resultant human neural tissues represent the first example of direct tissue loading with piezoelectric particles for ensuing 3D ultrasound-mediated piezoelectric enhancement of human neuronal induction from stem cells, including augmented neuritogenesis and synaptogenesis. It is anticipated that the platform described will facilitate advanced tissue engineering and in vitro modeling of human neural (and potentially non-neural) tissues, with modeling including tissue development and pathology, and applicable to preclinical testing and prototyping of both electroceuticals and pharmaceuticals.
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