Soft Bioelectronics Using Nanomaterials and Nanostructures for Neuroengineering.

in Accounts of chemical research by Minjeong Kim, Hyunjin Lee, Seonghyeon Nam, Dae-Hyeong Kim, Gi Doo Cha

TLDR

  • Soft nanobioelectronics are tiny devices that can be used to record and control the activity of neurons in the brain. These devices are made of soft materials that can stretch and conform to the shape of the brain, and they are integrated with nanomaterials and nanoscale structures to improve their performance. The study provides a detailed overview of these devices and their potential applications in treating neurological diseases like brain tumors, epilepsy, and Parkinson's disease. However, there are still challenges to overcome, such as improving the long-term stability and biocompatibility of these devices, and integrating multiple functions and modalities in a single device.

Abstract

ConspectusThe identification of neural networks for large areas and the regulation of neuronal activity at the single-neuron scale have garnered considerable attention in neuroscience. In addition, detecting biochemical molecules and electrically, optically, and chemically controlling neural functions are key research issues. However, conventional rigid and bulky bioelectronics face challenges for neural applications, including mechanical mismatch, unsatisfactory signal-to-noise ratio, and poor integration of multifunctional components, thereby degrading the sensing and modulation performance, long-term stability and biocompatibility, and diagnosis and therapy efficacy. Implantable bioelectronics have been developed to be mechanically compatible with the brain environment by adopting advanced geometric designs and utilizing intrinsically stretchable materials, but such advances have not been able to address all of the aforementioned challenges.Recently, the exploration of nanomaterial synthesis and nanoscale fabrication strategies has facilitated the design of unconventional soft bioelectronics with mechanical properties similar to those of neural tissues and submicrometer-scale resolution comparable to typical neuron sizes. The introduction of nanotechnology has provided bioelectronics with improved spatial resolution, selectivity, single neuron targeting, and even multifunctionality. As a result, this state-of-the-art nanotechnology has been integrated with bioelectronics in two main types, i.e., bioelectronics integrated with synthesized nanomaterials and bioelectronics with nanoscale structures. The functional nanomaterials can be synthesized and assembled to compose bioelectronics, allowing easy customization of their functionality to meet specific requirements. The unique nanoscale structures implemented with the bioelectronics could maximize the performance in terms of sensing and stimulation. Such soft nanobioelectronics have demonstrated their applicability for neuronal recording and modulation over a long period at the intracellular level and incorporation of multiple functions, such as electrical, optical, and chemical sensing and stimulation functions.In this Account, we will discuss the technical pathways in soft bioelectronics integrated with nanomaterials and implementing nanostructures for application to neuroengineering. We traced the historical development of bioelectronics from rigid and bulky structures to soft and deformable devices to conform to neuroengineering requirements. Recent approaches that introduced nanotechnology into neural devices enhanced the spatiotemporal resolution and endowed various device functions. These soft nanobioelectronic technologies are discussed in two categories: bioelectronics with synthesized nanomaterials and bioelectronics with nanoscale structures. We describe nanomaterial-integrated soft bioelectronics exhibiting various functionalities and modalities depending on the integrated nanomaterials. Meanwhile, soft bioelectronics with nanoscale structures are explained with their superior resolution and unique administration methods. We also exemplified the neural sensing and stimulation applications of soft nanobioelectronics across various modalities, showcasing their clinical applications in the treatment of neurological diseases, such as brain tumors, epilepsy, and Parkinson's disease. Finally, we discussed the challenges and direction of next-generation technologies.

Overview

  • The study focuses on the development of soft bioelectronics for neural applications, specifically for neuronal recording and modulation at the intracellular level. The hypothesis being tested is that the integration of nanomaterials and nanoscale structures in soft bioelectronics can enhance their performance in terms of sensing and stimulation, and improve their long-term stability and biocompatibility. The methodology used for the experiment includes a review of the literature on bioelectronics and nanotechnology, as well as an analysis of the technical pathways in soft bioelectronics integrated with nanomaterials and implementing nanostructures for application to neuroengineering. The primary objective of the study is to provide a comprehensive overview of the state-of-the-art in soft nanobioelectronics for neural applications and to discuss the challenges and direction of next-generation technologies.

Comparative Analysis & Findings

  • The study compares the outcomes observed under different experimental conditions or interventions detailed in the literature on soft bioelectronics integrated with nanomaterials and implementing nanostructures for application to neuroengineering. The key findings of the study include the enhanced spatiotemporal resolution and endowed various device functions achieved through the integration of nanotechnology in soft bioelectronics. Soft nanobioelectronics with synthesized nanomaterials exhibit various functionalities and modalities depending on the integrated nanomaterials, while soft bioelectronics with nanoscale structures are explained with their superior resolution and unique administration methods. The neural sensing and stimulation applications of soft nanobioelectronics across various modalities are showcased, highlighting their clinical applications in the treatment of neurological diseases, such as brain tumors, epilepsy, and Parkinson's disease. The study also discusses the challenges and direction of next-generation technologies, including the need for further development of soft nanobioelectronics with improved long-term stability and biocompatibility, as well as the integration of multiple functions and modalities in a single device.

Implications and Future Directions

  • The study's findings have significant implications for the field of neuroscience and clinical practice, as they demonstrate the potential of soft nanobioelectronics for neural applications. The study identifies several limitations of the current soft nanobioelectronics, including the need for further development of long-term stability and biocompatibility, as well as the integration of multiple functions and modalities in a single device. The study suggests several future research directions, including the development of soft nanobioelectronics with improved long-term stability and biocompatibility, as well as the integration of multiple functions and modalities in a single device. The study also highlights the potential of soft nanobioelectronics for the treatment of neurological diseases, such as brain tumors, epilepsy, and Parkinson's disease, and suggests that further research is needed to explore their clinical applications in detail.