NanoNeuroRFID: A Wireless Implantable Device Based on Magnetoelectric Antennas

Zaeimbashi, Mohsen; Lin, Hao; Dong, Cunzheng; Liang, Xianfeng; Nasrollahpour, Mehdi; Chen, Huaihao; Sun, Nian X.; Matyushov, Alexei; He, Yifan; Wang, Xinjun; Tu, Cheng; Wei, Yuyi; Zhang, Yi; Cash, Sydney S.; Onabajo, Marvin; Shrivastava, Aatmesh

doi:10.1109/jerm.2019.2903930

Cited by 78 publications

(50 citation statements)

References 30 publications

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“…So far, some of the most common forms of wireless power system for implantable neural devices are discussed and summarized in Table II. Apart from these, there are emerging technologies which combines multiple stimulation options and optofluidic channel [146], [147], uses innovative approach to achieve an ultra-miniaturized implant [148], introduces scalable and distributed wireless neural platform [149], [150], wireless optoelectronic photometer for dynamic mapping of the brain [151], simultaneous multichannel optogenetics stimulation and multichannel electrical recording system [152]. Fig.…”

Section: F Ultrasound Based Wireless Systemmentioning

confidence: 99%

Biointegrated and Wirelessly Powered Implantable Brain Devices: A Review

Das

Moradi

Heidari

2020

IEEE Trans. Biomed. Circuits Syst.

116

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Implantable neural interfacing devices have added significantly to neural engineering by introducing the lowfrequency oscillations of small populations of neurons known as local field potential as well as high-frequency action potentials of individual neurons. Regardless of the astounding progression as of late, conventional neural modulating system is still incapable to achieve the desired chronic in vivo implantation. The real constraint emerges from mechanical and physical differences between implants and brain tissue that initiates an inflammatory reaction and glial scar formation that reduces the recording and stimulation quality. Furthermore, traditional strategies consisting of rigid and tethered neural devices cause substantial tissue damage and impede the natural behavior of an animal, thus hindering chronic in vivo measurements. Therefore, enabling fully implantable neural devices requires biocompatibility, wireless power/data capability, biointegration using thin and flexible electronics, and chronic recording properties. This article reviews biocompatibility and design approaches for developing biointegrated and wirelessly powered implantable neural devices in animals aimed at long-term neural interfacing and outlines current challenges toward developing the next generation of implantable neural devices.Index Terms-Biocompatibility, biointegration, implantable neural device, mechanical flexibility, wireless power transfer.

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Section: F Ultrasound Based Wireless Systemmentioning

confidence: 99%

Biointegrated and Wirelessly Powered Implantable Brain Devices: A Review

Das

Moradi

Heidari

2020

IEEE Trans. Biomed. Circuits Syst.

116

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“…Therefore, we focus on the recent progress on thin-film magnetostrictive materials in this article. Several types of integrated multiferroic devices based on thin-film ME heterostructures including ME sensors [18,63,[67][68][69][70][71], inductors [35], filters [32] and antennas [43,72,73] are presented in this section. Based on the direct ME effect, a giant ME coefficient (α ME ) as high as 5kV/cm Oe was obtained by the direct deposition of FeCoSiB on Si substrate with a Si/SiO 2 /Pt/ AlN/FeCoSiB layer stack [71].…”

Section: Magnetoelectric Applicationsmentioning

confidence: 99%

A Review of Thin-Film Magnetoelastic Materials for Magnetoelectric Applications

Liang

Dong

Chen

et al. 2020

Sensors

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Since the revival of multiferroic laminates with giant magnetoelectric (ME) coefficients, a variety of multifunctional ME devices, such as sensor, inductor, filter, antenna etc. have been developed. Magnetoelastic materials, which couple the magnetization and strain together, have recently attracted ever-increasing attention due to their key roles in ME applications. This review starts with a brief introduction to the early research efforts in the field of multiferroic materials and moves to the recent work on magnetoelectric coupling and their applications based on both bulk and thin-film materials. This is followed by sections summarizing historical works and solving the challenges specific to the fabrication and characterization of magnetoelastic materials with large magnetostriction constants. After presenting the magnetostrictive thin films and their static and dynamic properties, we review micro-electromechanical systems (MEMS) and bulk devices utilizing ME effect. Finally, some open questions and future application directions where the community could head for magnetoelastic materials will be discussed.

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“…The device also revealed the capability to act as a receiver antenna [ 105 ]. Keeping focus on the antennas, NanoNeuroRFID is an ultra-compact implantable device composed by a ME antenna array that can harvest electromagnetic energy to power the device, sense quasi-static neuronal magnetic fields as small as 200 pT without direct contact to the tissue, communicate with an external transceiver and works from 10 to 100 MHz, where tissue loss is small [ 106 ]. The ME antenna based on FeGaB/AlN thin film exhibited a sensitivity of 2.475 Hz/nT and an ultra-low magnetic noise of 2.36 pT/Hz 1/2 at 10 Hz.…”

Section: Applications In the 40 Contextmentioning

confidence: 99%

“…The ME antenna based on FeGaB/AlN thin film exhibited a sensitivity of 2.475 Hz/nT and an ultra-low magnetic noise of 2.36 pT/Hz 1/2 at 10 Hz. The device is composed by an array of ME antennas for increasing the output voltage [ 106 ].…”

Section: Applications In the 40 Contextmentioning

confidence: 99%

Magnetoelectrics: Three Centuries of Research Heading Towards the 4.0 Industrial Revolution

et al. 2020

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Magnetoelectric (ME) materials composed of magnetostrictive and piezoelectric phases have been the subject of decades of research due to their versatility and unique capability to couple the magnetic and electric properties of the matter. While these materials are often studied from a fundamental point of view, the 4.0 revolution (automation of traditional manufacturing and industrial practices, using modern smart technology) and the Internet of Things (IoT) context allows the perfect conditions for this type of materials being effectively/finally implemented in a variety of advanced applications. This review starts in the era of Rontgen and Curie and ends up in the present day, highlighting challenges/directions for the time to come. The main materials, configurations, ME coefficients, and processing techniques are reported.

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NanoNeuroRFID: A Wireless Implantable Device Based on Magnetoelectric Antennas

Cited by 78 publications

References 30 publications

Biointegrated and Wirelessly Powered Implantable Brain Devices: A Review

Biointegrated and Wirelessly Powered Implantable Brain Devices: A Review

A Review of Thin-Film Magnetoelastic Materials for Magnetoelectric Applications

Magnetoelectrics: Three Centuries of Research Heading Towards the 4.0 Industrial Revolution

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