Toward Functional Biointerfaces with Origami-on-a-Chip

IF 6.8 Q1 AUTOMATION & CONTROL SYSTEMS Advanced intelligent systems (Weinheim an der Bergstrasse, Germany) Pub Date : 2024-06-19 DOI:10.1002/aisy.202400055
Alonso Ingar Romero, Qianru Jin, Kevin Kit Parker, Joe Alexander, Bernhard Wolfrum, Tetsuhiko F. Teshima
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Abstract

Studying the behavior of electroactive cells, such as firing dynamics and chemical secretion, is crucial for developing human disease models and therapeutics. Following the recent advances in cell culture technology, traditional monolayers are optimized to resemble more 3D, organ-like structures. The biological and electrochemical complexity of these structures requires devices with adaptive shapes and novel features, such as precise electrophysiological mapping and stimulation in the case of brain- and heart-derived tissues. However, conventional organ-on-chip platforms often fall short, as they do not recreate the native environment of the cells and lack the functional interfaces necessary for long-term monitoring. Origami-on-a-chip platforms offer a solution for this problem, as they can flexibly adapt to the structure of the desired biological sample and can be integrated with functional components enabled by chosen materials. In this review, the evolution of origami-on-a-chip biointerfaces is discussed, emphasizing folding stimuli, materials, and critical findings. In the prospects, microfluidic integration, functional tissue engineering scaffolds, and multi-organoid networks are included, allowing patient-specific diagnoses and therapies through computational and in vitro disease modeling.

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利用芯片上的原产地技术打造功能性生物界面
研究电活性细胞的行为,如发射动态和化学分泌,对于开发人类疾病模型和治疗方法至关重要。随着细胞培养技术的不断进步,传统的单层细胞被优化为更类似于三维器官的结构。这些结构的生物和电化学复杂性要求设备具有自适应的形状和新颖的功能,例如在大脑和心脏组织的情况下,需要精确的电生理映射和刺激。然而,传统的片上器官平台往往无法重现细胞的原生环境,也缺乏长期监测所需的功能接口。起源芯片平台为这一问题提供了解决方案,因为它们可以灵活地适应所需生物样本的结构,并可通过所选材料与功能组件集成。在这篇综述中,我们将讨论芯片上折纸生物界面的演变,重点关注折叠刺激、材料和重要发现。展望未来,微流体集成、功能性组织工程支架和多器官网络将被纳入其中,从而通过计算和体外疾病建模实现针对患者的诊断和治疗。
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CiteScore
1.30
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审稿时长
4 weeks
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