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

Yan, Dongxiao; Jiman, Ahmad A.; Bottorff, Elizabeth C; Patel, Paras R.; Meli, Dilara; Welle, Elissa J.; Ratze, David C.; Havton, Leif A.; Chestek, Cynthia A.; Kemp, Stephen W.P.; Bruns, Tim M.; Yoon, Euisik; Seymour, John P.

doi:10.1101/2022.01.19.476928

Cited by 4 publications

(3 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…As introduced earlier, Yan et al 52 combined DRIE with silicone casting and backside alignment to fabricate a Utah-like stretchable 3D MEA. However, the process flow involves complex steps, which usually affect fabrication costs and device design.…”

Section: Discussionmentioning

confidence: 99%

“…Because the fabrication process of the USEA is based on wafer-etching, conventional 3D microelectrode arrays (3D MEAs) are based on rigid silicon as the substrate material 50 . However, Lee et al 51 and Yan et al 52 demonstrated the possibility of producing flexible Utah-like 3D MEAs with silicon pillars by combining several micromachining techniques.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

A flexible protruding microelectrode array for neural interfacing in bioelectronic medicine

et al. 2022

View full text Add to dashboard Cite

Recording neural signals from delicate autonomic nerves is a challenging task that requires the development of a low-invasive neural interface with highly selective, micrometer-sized electrodes. This paper reports on the development of a three-dimensional (3D) protruding thin-film microelectrode array (MEA), which is intended to be used for recording low-amplitude neural signals from pelvic nervous structures by penetrating the nerves transversely to reduce the distance to the axons. Cylindrical gold pillars (Ø 20 or 50 µm, ~60 µm height) were fabricated on a micromachined polyimide substrate in an electroplating process. Their sidewalls were insulated with parylene C, and their tips were optionally modified by wet etching and/or the application of a titanium nitride (TiN) coating. The microelectrodes modified by these combined techniques exhibited low impedances (~7 kΩ at 1 kHz for Ø 50 µm microelectrode with the exposed surface area of ~5000 µm²) and low intrinsic noise levels. Their functionalities were evaluated in an ex vivo pilot study with mouse retinae, in which spontaneous neuronal spikes were recorded with amplitudes of up to 66 µV. This novel process strategy for fabricating flexible, 3D neural interfaces with low-impedance microelectrodes has the potential to selectively record neural signals from not only delicate structures such as retinal cells but also autonomic nerves with improved signal quality to study neural circuits and develop stimulation strategies in bioelectronic medicine, e.g., for the control of vital digestive functions.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A flexible protruding microelectrode array for neural interfacing in bioelectronic medicine

et al. 2022

View full text Add to dashboard Cite

show abstract

“…Additionally, the injection approach is accompanied by a risk of needle breakage and overdosing, and it eventually requires waste management of sharps (Yao et al, 2020). Microneedles (MNs) are devices with arrays of microscale needles or pins that can bypass the external barriers of tissues and achieve enhanced therapeutic delivery or biosensing in a minimally invasive manner (Byun et al, 2017; Yan et al, 2022) (Figure 1A–a,b). Various types of MNs, such as solid, hollow, or coated MNs, have been developed to increase the efficacy of MNs depending on their specific applications (Lee, Goudie, et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

Advances and challenges in developing smart, multifunctional microneedles for biomedical applications

Tavafoghi

Nasrollahi

Karamikamkar

et al. 2022

Biotech & Bioengineering

View full text Add to dashboard Cite

Microneedles (MNs) have been developed as minimally invasive tools for diagnostic and therapeutic applications. However, in recent years, there has been an increasing interest in developing smart multifunctional MN devices to provide automated and closed-loop systems for body fluid extraction, biosensing, and drug delivery in a stimuli-responsive manner. Although this technology is still in its infancy and far from being translated into the clinic, preclinical trials have shown some promise for the broad applications of multifunctional MN devices. The main challenge facing the fabrication of smart MN patches is the integration of multiple modules, such as drug carriers, highly sensitive biosensors, and data analyzers in one miniaturized MN device. Researchers have shown the feasibility of creating smart MNs by integrating stimuli-responsive biomaterials and advanced microscale technologies, such as microsensors and microfluidic systems, to precisely control the transportation of biofluids and drugs throughout the system. These multifunctional MN devices can be envisioned in two distinct strategies. The first type includes individual drug delivery and biosensing MN units with a microfluidic system and a digital analyzer responsible for fluid transportation and communication between these two modules.The second type relies on smart biomaterials that can function as drug deliverers and biosensors by releasing drugs in a stimuli-responsive manner. These smart biomaterials can undergo structural changes when exposed to external stimuli, such as pH and ionic changes, mimicking the biological systems. Studies have demonstrated a high potential of hydrogel-based MN devices for a wide variety of biomedical applications, such as drug and cell delivery, as well as interstitial fluid extraction. Biodegradable hydrogels have also been advantageous for fabricating multifunctional MNs due to their high loading capacity and biocompatibility with the drug of choice. Here, we first review a set of MN devices that can be employed either for biosensing or delivery of multiple target molecules and compare them to the conventional and more simple systems, which are mainly designed for singlemolecule sensing or delivery. Subsequently, we expand our insight into advanced MN systems with multiple competencies, such as body fluid extraction, biosensing,

show abstract

In-vivo recording of sensory signals from peripheral nerves using flexible 3D neural electrodes

Park

Jang

Kim

2022

Micro and Nano Syst Lett

View full text Add to dashboard Cite

To overcome the limitations of muscle-based prostheses, studies on nerve-based prostheses for sensory feedback have recently been reported. To develop such prostheses, intrafascicular electrodes, a type of peripheral nerve interface, are essentially used to connect the nervous system and external systems. Through these electrodes, sensory feedback to induce sensations in patients is possible. To evoke natural sensations, precise recordings of nerve signals should precede sensory feedback, in order to identify patterns of sensory signals in the nerve and to mimic these patterns in stimulating the nerve. For this purpose, we previously developed a PDMS-based flexible penetrating microelectrode array (FPMA). In the current study, we verified the ability of the FPMA to record sensory nerve signals. The FPMA implanted in the rabbit sciatic nerve was able to record spontaneous neural signals, and the recorded signals were separated into action potential units. In addition, sensory nerve signals synchronized with ankle movement were successfully recorded, demonstrating that the FPMA is a useful peripheral neural interface capable of recording high-resolution sensory signals.

show abstract

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

Cited by 4 publications

References 52 publications

A flexible protruding microelectrode array for neural interfacing in bioelectronic medicine

A flexible protruding microelectrode array for neural interfacing in bioelectronic medicine

Advances and challenges in developing smart, multifunctional microneedles for biomedical applications

In-vivo recording of sensory signals from peripheral nerves using flexible 3D neural electrodes

Contact Info

Product

Resources

About