Sustainable brain-inspired electronics: digging into natural biomaterials for healthcare applications

João V. Paulin and Carlos C. B. Bufon
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Abstract

With traditional medical technologies shifting towards a more personalized point-of-view, current semiconductor-based electronics may need high-performance computing capability for cognitive and adaptive functions based on unspecific, multi-input, and complex tasks. Hence, developing electronic devices with improved capabilities is of utmost interest. One option takes inspiration from the synapse functionalities of the human brain. Due to their scalability and low power consumption, memristors and electrolyte-gated transistors are ideal candidates for efficient brain-inspired applications. Additionally, combining these device architectures with natural biomaterials (environmentally benign, biodegradable, biocompatible, and mechanically conformable) represents a new horizon toward transient and implantable synaptic devices. Here, we advertised the advances in artificial synaptic systems based on natural biomaterials and how these devices can be integrated into sustainable and intelligent healthcare systems. Our comprehensive review formulates the steps necessary for the next generation of healthcare electronics to flourish.

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可持续的脑启发电子学:挖掘天然生物材料的医疗应用价值
随着传统医疗技术转向更加个性化的视角,目前基于半导体的电子设备可能需要高性能计算能力,以实现基于非特定、多输入和复杂任务的认知和自适应功能。因此,开发具有更强功能的电子设备是人们最感兴趣的问题。一种方案是从人脑的突触功能中获得灵感。忆阻器和电解质门晶体管具有可扩展性和低功耗的特点,是高效脑启发应用的理想选择。此外,将这些器件架构与天然生物材料(对环境无害、可生物降解、生物相容性好、机械顺应性强)相结合,代表了瞬时和植入式突触器件的新前景。在此,我们介绍了基于天然生物材料的人工突触系统的进展,以及如何将这些装置整合到可持续的智能医疗保健系统中。我们的全面综述为下一代医疗保健电子产品的蓬勃发展制定了必要的步骤。
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