Ultrathin, High Capacitance Capping Layers for Silicon Electronics with Conductive Interconnects in Flexible, Long‐Lived Bioimplants

Li, Jinghua; Li, Rui; Chiang, Chia‐Han; Zhong, Yuncheng; Shen, Helen C.; Hill, Mackenna; Baek, Janice Mihyun; Lee, Yujin; Viventi, Jonathan; Rogers, John A.

doi:10.1002/admt.201900800

Cited by 19 publications

(10 citation statements)

References 53 publications

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“…The chronic bioencapsulation layers are manufactured by integrating combinations of organic or inorganic materials with various deposition temperatures, thicknesses, and techniques such as spin‐coating, dip‐coating, chemical vapor deposition (CVD), or physical vapor deposition (PVD). [ 16 , 239 , 240 , 241 , 242 , 243 , 244 ] Among the various materials, polymer layers (SU‐8, PDMS, Parylene C, etc.) can serve as long‐term bio‐encapsulations, formed comparatively simply and at low cost, but the layers need to be quite thick, ranging from tens to hundreds of microns because of the polymers’ high value of water vapor transmission rates (WVTRs).…”

Section: Encapsulation For Implantable Bioelectronicsmentioning

confidence: 99%

Ultra‐Thin Flexible Encapsulating Materials for Soft Bio‐Integrated Electronics

2022

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Recently, bioelectronic devices extensively researched and developed through the convergence of flexible biocompatible materials and electronics design that enables more precise diagnostics and therapeutics in human health care and opens up the potential to expand into various fields, such as clinical medicine and biomedical research. To establish an accurate and stable bidirectional bio-interface, protection against the external environment and high mechanical deformation is essential for wearable bioelectronic devices. In the case of implantable bioelectronics, special encapsulation materials and optimized mechanical designs and configurations that provide electronic stability and functionality are required for accommodating various organ properties, lifespans, and functions in the biofluid environment. Here, this study introduces recent developments of ultra-thin encapsulations with novel materials that can preserve or even improve the electrical performance of wearable and implantable bio-integrated electronics by supporting safety and stability for protection from destruction and contamination as well as optimizing the use of bioelectronic systems in physiological environments. In addition, a summary of the materials, methods, and characteristics of the most widely used encapsulation technologies is introduced, thereby providing a strategic selection of appropriate choices of recently developed flexible bioelectronics.

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Section: Encapsulation For Implantable Bioelectronicsmentioning

confidence: 99%

Ultra‐Thin Flexible Encapsulating Materials for Soft Bio‐Integrated Electronics

2022

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“…Compared with other common dielectric coating approaches where a thin layer of organic or inorganic insulator was deposited via vapor deposition, high-quality silicon dioxide formed using thermal oxidation was shown to have good biocompatibility and longevity in the physiological environment. [33][34][35][36][37] This is the first instance of thermal oxide grown on microneedles, to our knowledge. The 70 µm thick PDMS as the substrate material enhanced the flexibility of the device and enabled the electrode array to conformally attach to the small diameter autonomic nerve.…”

Section: Mina Design and Fabricationmentioning

confidence: 99%

Ultraflexible and Stretchable Intrafascicular Peripheral Nerve Recording Device with Axon‐Dimension, Cuff‐Less Microneedle Electrode Array

Yan

Jiman

Bottorff

et al. 2022

Small

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Peripheral nerve mapping tools with higher spatial resolution are needed to advance systems neuroscience, and potentially provide a closed‐loop biomarker in neuromodulation applications. Two critical challenges of microscale neural interfaces are 1) how to apply them to small peripheral nerves, and 2) how to minimize chronic reactivity. A flexible microneedle nerve array (MINA) is developed, which is the first high‐density penetrating electrode array made with axon‐sized silicon microneedles embedded in low‐modulus thin silicone. The design, fabrication, acute recording, and chronic reactivity to an implanted MINA, are presented. Distinctive units are identified in the rat peroneal nerve. The authors also demonstrate a long‐term, cuff‐free, and suture‐free fixation manner using rose bengal as a light‐activated adhesive for two time‐points. The tissue response is investigated at 1‐week and 6‐week time‐points, including two sham groups and two MINA‐implanted groups. These conditions are quantified in the left vagus nerve of rats using histomorphometry. Micro computed tomography (micro‐CT) is added to visualize and quantify tissue encapsulation around the implant. MINA demonstrates a reduction in encapsulation thickness over previously quantified interfascicular methods. Future challenges include techniques for precise insertion of the microneedle electrodes and demonstrating long‐term recording.

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Section: Mina Design and Fabricationmentioning

confidence: 99%

Ultra-flexible and Stretchable Intrafascicular Peripheral Nerve Recording Device with Axon-dimension, Cuff-less Microneedle Electrode Array

Yan

Jiman

Bottorff

et al. 2022

Preprint

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Peripheral nerve mapping tools with higher spatial resolution are needed to advance systems neuroscience, and potentially provide a closed-loop biomarker in neuromodulation applications. Two critical challenges of microscale neural interfaces are (i) how to apply them to small peripheral nerves, and (ii) how to minimize chronic reactivity. We developed a flexible microneedle nerve array (MINA), which is the first high-density penetrating electrode array made with axon-sized silicon microneedles embedded in low-modulus thin silicone. We present the design, fabrication, acute recording, and chronic reactivity to an implanted MINA. Distinctive units were identified in the rat peroneal nerve. We also demonstrate a long-term, cuff-free, and suture-free fixation manner using rose bengal as a light-activated adhesive for two timepoints. The tissue response at 1-week included a sham (N=5) and MINA-implanted (N=5) group, and the response at 6-week also included a sham (N=3) and MINA-implanted (N=4) group. These conditions were quantified in the left vagus nerve of rats using histomorphometry. Micro-CT was added to visualize and quantify tissue encapsulation around the implant. MINA demonstrated a reduction in encapsulation thickness over previously quantified interfascicular methods. Future challenges include techniques for precise insertion of the microneedle electrodes and demonstrating long-term recording.

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Ultrathin, High Capacitance Capping Layers for Silicon Electronics with Conductive Interconnects in Flexible, Long‐Lived Bioimplants

Cited by 19 publications

References 53 publications

Ultra‐Thin Flexible Encapsulating Materials for Soft Bio‐Integrated Electronics

Ultra‐Thin Flexible Encapsulating Materials for Soft Bio‐Integrated Electronics

Ultraflexible and Stretchable Intrafascicular Peripheral Nerve Recording Device with Axon‐Dimension, Cuff‐Less Microneedle Electrode Array

Ultra-flexible and Stretchable Intrafascicular Peripheral Nerve Recording Device with Axon-dimension, Cuff-less Microneedle Electrode Array

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