Reduction of eddy current losses in inductive transmission systems with ferrite sheets

Maass, M.; Griessner, Andreas; Steixner, Viktor; Zierhofer, Clemens

doi:10.1186/s12938-016-0297-4

Cited by 10 publications

(3 citation statements)

References 20 publications

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“…The operating frequency of alternating magnetic fields is typically chosen between 100 and 1 MHz. This range minimizes eddy current losses, thereby reducing the risk of localized heating and its subsequent influence on neural stability ( Maaß et al, 2017 ; Haerinia and Shadid, 2020 ; Mahmood et al, 2022 ). In addition to this, magnetic fields at these frequencies have the potential to disturb intracellular ionic concentrations, which can indirectly affect neural activity and cellular homeostasis ( Kletetschka et al, 2021 ; Panagopoulos et al, 2021 ).…”

Section: Existing Methods Of Delivering Power To Implantsmentioning

confidence: 99%

Comparative analysis of energy transfer mechanisms for neural implants

Miziev,

Pawlak,

Howard

2024

Front. Neurosci.

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As neural implant technologies advance rapidly, a nuanced understanding of their powering mechanisms becomes indispensable, especially given the long-term biocompatibility risks like oxidative stress and inflammation, which can be aggravated by recurrent surgeries, including battery replacements. This review delves into a comprehensive analysis, starting with biocompatibility considerations for both energy storage units and transfer methods. The review focuses on four main mechanisms for powering neural implants: Electromagnetic, Acoustic, Optical, and Direct Connection to the Body. Among these, Electromagnetic Methods include techniques such as Near-Field Communication (RF). Acoustic methods using high-frequency ultrasound offer advantages in power transmission efficiency and multi-node interrogation capabilities. Optical methods, although still in early development, show promising energy transmission efficiencies using Near-Infrared (NIR) light while avoiding electromagnetic interference. Direct connections, while efficient, pose substantial safety risks, including infection and micromotion disturbances within neural tissue. The review employs key metrics such as specific absorption rate (SAR) and energy transfer efficiency for a nuanced evaluation of these methods. It also discusses recent innovations like the Sectored-Multi Ring Ultrasonic Transducer (S-MRUT), Stentrode, and Neural Dust. Ultimately, this review aims to help researchers, clinicians, and engineers better understand the challenges of and potentially create new solutions for powering neural implants.

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Section: Existing Methods Of Delivering Power To Implantsmentioning

confidence: 99%

Comparative analysis of energy transfer mechanisms for neural implants

Miziev,

Pawlak,

Howard

2024

Front. Neurosci.

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“…Due to the placement of the coil parallel to the aluminum battery pouch, an eddy current is induced which alters the inductance and detunes the resonance of the LC circuit. Placing a magnetically active ferrite sheet helps to shield unwanted eddy currents, thereby increasing the transfer efficiency [54]. 300 μm ferrite sheets (MARUWA Co., Owariasahi, Japan) were laser-cut to size and affixed to each coil.…”

Section: Wireless Power Transfer and Coil Designmentioning

confidence: 99%

A Fully Implantable Wireless Bidirectional Neuromodulation System for Mice

Wright

Wong

Mathew

et al. 2021

Preprint

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Novel research in the field of bioelectronic medicine requires systems that pair high-performance neurostimulation and bio-signal acquisition hardware with advanced software signal processing and control algorithms. Although mice are the most commonly used animal in medical research, the size, weight, and power requirements of such systems either preclude their use or impose significant constraints on experimental design. Here, we describe a fully-implantable neuromodulation system suitable for use in mice, measuring 2.2 cm3 and weighing 2.8 g. A bidirectional wireless interface allows simultaneous readout of multiple physiological signals and complete control over stimulation parameters, and a wirelessly rechargeable battery provides a lifetime of up to 5 days on a single charge. The device was successfully implanted (N=12) and a functional neural interface (capable of inducing acute bradycardia) is demonstrated with functional lifetimes exceeding to three weeks. The design utilizes only commercially-available components and 3D-printed packaging, with the goal of accelerating discovery and translation of future bioelectronic therapeutics.

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“…Extensive studies of each type of SFNMs are still undergoing and much has been investigated in various in-vitro, ex-vitro and in-vivo biomedical applications [21,22,23]. The main required characteristics of SFNMs in biomedical area are super paramagnetic nature at 300 o K. They also have small magnetic and eddy losses, large resistivity and permeability, high chemical, mechanical and thermal stability and compatibility [24,25,26]. These features of SFNMs entice the researchers' attention for their diversified biomedical uses.…”

Section: Introductionmentioning

confidence: 99%

Suitability of Ferrites for Biomedical Applications

Dhiman

2021

Materials Research Foundations

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This chapter aims at the latest amelioration in the biomedical application of spinel ferrites. Magnetic hyperthermia treatment of tumour cells and contrast resonance imaging of human body parts, are a few applications of spinel ferrites that have gained substantial interest nowadays. The thermo-therapeutic and radiology based diagnosis treatment has many benefits over traditional methods used for disease diagnosis and imaging treatment of chronic carcinogenic origin diseases. The various types of doped and undoped spinel ferrite nanoparticles are investigated and optimised for different biomedical applications. Through this chapter, an attempt is made to provide readers the knowledge about various required characteristics and latest used strategies for the successful implementations of spinel ferrite in biomedical applications at commercial levels.

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Reduction of eddy current losses in inductive transmission systems with ferrite sheets

Cited by 10 publications

References 20 publications

Comparative analysis of energy transfer mechanisms for neural implants

Comparative analysis of energy transfer mechanisms for neural implants

A Fully Implantable Wireless Bidirectional Neuromodulation System for Mice

Suitability of Ferrites for Biomedical Applications

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