A Review: Electrode and Packaging Materials for Neurophysiology Recording Implants

Yang, Weiyang; Gong, Yan; Li, Wen

doi:10.3389/fbioe.2020.622923

Cited by 49 publications

(61 citation statements)

References 409 publications

(537 reference statements)

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“…Substrate materials with specific properties such as flexibility, biocompatibility, and stability are expected for the chronic implantation of electrodes in the complex environment of the body [15]. For all neural microelectrodes, the biocompatibility of [66]; and (c) nerve probes based on graphene, ZnO nanowires and conductive polymers [63].…”

Section: Substrate Materialsmentioning

confidence: 99%

Research Progress on the Flexibility of an Implantable Neural Microelectrode

et al. 2022

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Neural microelectrode is the important bridge of information exchange between the human body and machines. By recording and transmitting nerve signals with electrodes, people can control the external machines. At the same time, using electrodes to electrically stimulate nerve tissue, people with long-term brain diseases will be safely and reliably treated. Young’s modulus of the traditional rigid electrode probe is not matched well with that of biological tissue, and tissue immune rejection is easy to generate, resulting in the electrode not being able to achieve long-term safety and reliable working. In recent years, the choice of flexible materials and design of electrode structures can achieve modulus matching between electrode and biological tissue, and tissue damage is decreased. This review discusses nerve microelectrodes based on flexible electrode materials and substrate materials. Simultaneously, different structural designs of neural microelectrodes are reviewed. However, flexible electrode probes are difficult to implant into the brain. Only with the aid of certain auxiliary devices, can the implant be safe and reliable. The implantation method of the nerve microelectrode is also reviewed.

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Section: Substrate Materialsmentioning

confidence: 99%

Research Progress on the Flexibility of an Implantable Neural Microelectrode

et al. 2022

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“…In particular, we discuss the electrode and substrate materials. For more related discussion on packaging, biocompatibility, and multi electrode array recordings we refer the interested readers to (7,(41)(42)(43)(44) and references therein.…”

Section: Core Considerationsmentioning

confidence: 99%

“…Starting with acute inflammation, a release of reactive oxidative species (ROS), followed by possible chronic inflammation. Due to ROS attack and tissue regeneration processes, implant degradation and encapsulation, which affect long-term stability and efficacy of the device, may occur ( 41 ). Therefore, device materials must be biocompatible and withstand biological reactions.…”

Section: Core Considerationsmentioning

confidence: 99%

“…In addition, sterilization method should be carefully chosen ( 76 ). Whichever sterilization approach is chosen (i.e., ethanol sterilization, autoclaving, UV radiation, ethylene oxide gas) should not damage the electrode mechanical or optical properties, nor accelerate corrosion, denaturation or delamination of packaging materials ( 41 , 77 ).…”

Section: Core Considerationsmentioning

confidence: 99%

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Soft Devices for High-Resolution Neuro-Stimulation: The Interplay Between Low-Rigidity and Resolution

Vėbraitė

Hanein

2021

Front. Med. Technol.

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The field of neurostimulation has evolved over the last few decades from a crude, low-resolution approach to a highly sophisticated methodology entailing the use of state-of-the-art technologies. Neurostimulation has been tested for a growing number of neurological applications, demonstrating great promise and attracting growing attention in both academia and industry. Despite tremendous progress, long-term stability of the implants, their large dimensions, their rigidity and the methods of their introduction and anchoring to sensitive neural tissue remain challenging. The purpose of this review is to provide a concise introduction to the field of high-resolution neurostimulation from a technological perspective and to focus on opportunities stemming from developments in materials sciences and engineering to reduce device rigidity while optimizing electrode small dimensions. We discuss how these factors may contribute to smaller, lighter, softer and higher electrode density devices.

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“…Novel implantable devices ever-expanding capabilities more often include fully wireless communication and on-node data processing, thus imposing more rigorous requirements for device packaging [3]. Nowadays, implant packages, aside from ensuring small size, reliability, and biocompatibility, may additionally require CMOS compatibility and transparency to the communication signals [4][5][6]. Until now, the majority of implants were packaged by encasing entire systems in metal or glass cases or by using thick outer coatings, mainly made of medical-grade silicones [2,6,7].…”

Section: Introductionmentioning

confidence: 99%

Hermetic chip-scale packaging using Au:Sn eutectic bonding for implantable devices

Szostak,

Keshavarz,

Constandinou

2021

Preprint

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Advancements in miniaturisation and new capabilities of implantable devices impose a need for the development of compact, hermetic, and CMOScompatible micro packaging methods. Gold-tin-based eutectic bonding presents the potential for achieving low-footprint seals with low permeability to moisture at process temperatures below 350°C. In this paper, a method for the deposition of gold-tin eutectic alloy frames via sequential electroplating from commercially available solutions, with no special fabrication process, is described in detail. Bond quality was characterised through shear force measurements, scanning electron microscopy, visual inspection, and immersion tests. Characterisation of seals geometry, solder thickness, and bonding process parameters were evaluated, along with toxicity assessment of bonding layers to the human fibroblast cells. With a successful bond yield of over 70% and no cytotoxic effect, AuSn eutectic bonding appears as a suitable method for the protection of integrated circuitry in implantable applications.

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A Review: Electrode and Packaging Materials for Neurophysiology Recording Implants

Cited by 49 publications

References 409 publications

Research Progress on the Flexibility of an Implantable Neural Microelectrode

Research Progress on the Flexibility of an Implantable Neural Microelectrode

Soft Devices for High-Resolution Neuro-Stimulation: The Interplay Between Low-Rigidity and Resolution

Hermetic chip-scale packaging using Au:Sn eutectic bonding for implantable devices

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