Wireless induction coils embedded in diamond for power transfer in medical implants

Wireless power and data transfer to medical implants is a research area where improvements in current state-of-the-art technologies are needed owing to the continuing efforts for miniaturization. At present, lithographical patterning of evaporated metals is widely used for miniature coil fabrication...

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Bibliographic Details
Published in:Biomedical microdevices 2017-12, Vol.19 (4), p.79-10, Article 79
Main Authors: Sikder, Md. Kabir Uddin, Fallon, James, Shivdasani, Mohit N., Ganesan, Kumaravelu, Seligman, Peter, Garrett, David J.
Format: Article
Language:English
Subjects:
Accelerated aging tests
Accelerated tests
Alloys
Biocompatibility
Biological and Medical Physics
Biomedical engineering
Biomedical Engineering and Bioengineering
Biophysics
Coiling
Cross-sections
Data transfer (computers)
Diamond
Diamonds
Efficiency
Electric Wiring
Electricity
Encapsulation
Engineering
Engineering Fluid Dynamics
Fabrication
Feasibility studies
Heavy metals
Hermetic sealing
High impedance
Impedance
Induction coils
Medical equipment
Medical research
Miniaturization
Nanotechnology
Oxygen plasma
Platinum
Power efficiency
Power transfer
Prostheses and Implants
Q factors
Sealing
Silver
Silver base alloys
Stimulation
Surgical implants
Transplants & implants
Trenches
Tumor necrosis factor-TNF
Wireless communications
Wireless Technology
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Summary:Wireless power and data transfer to medical implants is a research area where improvements in current state-of-the-art technologies are needed owing to the continuing efforts for miniaturization. At present, lithographical patterning of evaporated metals is widely used for miniature coil fabrication. This method produces coils that are limited to low micron or nanometer thicknesses leading to high impedance values and thus limiting their potential quality. In the present work we describe a novel technique, whereby trenches were milled into a diamond substrate and filled with silver active braze alloy, enabling the manufacture of small, high cross-section, low impedance microcoils capable of transferring up to 10 mW of power up to a distance of 6 mm. As a substitute for a metallic braze line used for hermetic sealing, a continuous metal loop when placed parallel and close to the coil surface reduced power transfer efficiency by 43%, but not significantly, when placed perpendicular to the microcoil surface. Encapsulation of the coil by growth of a further layer of diamond reduced the quality factor by an average of 38%, which can be largely avoided by prior oxygen plasma treatment. Furthermore, an accelerated ageing test after encapsulation showed that these coils are long lasting. Our results thus collectively highlight the feasibility of fabricating a high-cross section, biocompatible and long lasting miniaturized microcoil that could be used in either a neural recording or neuromuscular stimulation device.
ISSN:1387-2176
1572-8781
DOI:10.1007/s10544-017-0220-1