A Dual-Band Wireless Power Transmission System for Evaluating mm-Sized Implants

Distributed neural interfaces made of many mm-sized implantable medical devices (IMDs) are poised to play a key role in future brain-computer interfaces because of less damage to the surrounding tissue. Evaluating them wirelessly at preclinical stage (e.g., in a rodent model), however, is a major ch...

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Bibliographic Details
Published in:IEEE transactions on biomedical circuits and systems 2019-08, Vol.13 (4), p.595-607
Main Authors: Jia, Yaoyao, Mirbozorgi, S. Abdollah, Zhang, Pengcheng, Inan, Omer T., Li, Wen, Ghovanloo, Maysam
Format: Article
Language:English
Subjects:
Algorithms
Animals
Back telemetry
behavioral experiments
Biomedical optical imaging
Bluetooth
Brain damage
closed- loop power control
Coils
Computer Simulation
Damage assessment
Dual band
Electric Power Supplies
Equipment Design
Free floating
headstage
Human-computer interface
implantable medical device
Interfaces
Medical devices
Medical electronics
Medical equipment
neural interfacing
Neural networks
On-Off Keying
Optical resonators
Power efficiency
Prostheses and Implants
Rodents
Sheep
Specific absorption rate
Stimulators
Surgical implants
Telemetry
Wireless power transmission
Wireless Technology - instrumentation
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Summary:Distributed neural interfaces made of many mm-sized implantable medical devices (IMDs) are poised to play a key role in future brain-computer interfaces because of less damage to the surrounding tissue. Evaluating them wirelessly at preclinical stage (e.g., in a rodent model), however, is a major challenge due to weak coupling and significant losses, resulting in limited power delivery to the IMD within a nominal experimental arena, like a homecage, without surpassing the specific absorption rate limit. To address this problem, we present a dual-band EnerCage system with two multi-coil inductive links, which first deliver power at 13.56 MHz from the EnerCage (46 × 24 × 20 cm 3 ) to a headstage (18 × 18 × 15 mm 3 , 4.8 g) that is carried by the animal via a 4-coil inductive link. Then, a 60 MHz 3-coil inductive link from the headstage powers up the small IMD (2.5 × 2.5 × 1.5 mm 3 , 15 mg), which in this case is a free floating, wirelessly powered, implantable optical stimulator (FF-WIOS). The power transfer efficiency and power delivered to the load (PDL) from EnerCage to the headstage at 7 cm height were 14.9%-22.7% and 122 mW; and from headstage to FF-WIOS at 5 mm depth were 18% and 2.7 mW, respectively. Bidirectional data connectivity between EnerCage-headstage was established via bluetooth low energy. Between headstage and FF-WIOS, on-off keying and load-shift-keying were used for downlink and uplink data, respectively. Moreover, a closed-loop power controller stabilized PDL to both the headstage and the FF-WIOS against misalignments.
ISSN:1932-4545
1940-9990
DOI:10.1109/TBCAS.2019.2915649