Micro-fabrication of high-thickness spiral inductors for the remote powering of implantable biosensors

A micro-fabrication process is proposed to realize high-thickness spiral inductors for the remote powering of implantable biosensors through inductive link. The process is suitable for different substrates, such as silicon and Pyrex, and enables the fabrication of the receiving inductor directly on the implantable system. The use of Ordyl Alpha960 is explored to achieve high-thickness structures. Ordyl is a dry film, negative photoresist that enables high-thickness mold (starting from [email protected]) with a single-layer deposition. Copper spiral inductors with a trace thickness of [email protected] are fabricated on silicon and tested. These inductors can receive up to 8.7mW, with a link efficiency of 25%, over a distance of 6mm from the transmitter. Tested within a real setup, these inductors enable bidirectional data communication with the external transmitter. Downlink communication (ASK) is successfully tested at 100kbps. Uplink communication (LSK) is successfully tested at 66.6kbps.

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