What question did this study set out to answer?

The aim is to explore resonant inductive coupling as a power source for wireless bioelectronics.

April 16, 2026Open Access

From materials to systems: resonant inductive coupling for wireless bioelectronics

Key Points

The aim is to explore resonant inductive coupling as a power source for wireless bioelectronics.
Reviewed fundamental principles of resonant inductive coupling.
Analyzed material and structural designs for inductive coils.
Discussed integration into sensing and communication systems.
Highlighted advancements in bioresorbable inductive coil systems.
Resonant inductive coupling provides a biocompatible alternative to traditional batteries.
Material strategies enhance the stability of soft coils in biological environments.
Recent advancements indicate significant improvements in coil efficiency and integration.

Abstract

Abstract Wireless bioelectronics require alternatives to rigid, bulky batteries for long-term monitoring. This paper reviews resonant inductive coupling (RIC) as an efficient biocompatible power strategy surpassing conventional batteries. We summarize fundamental RIC principles and design parameters for biological environments. We then discuss material and structural strategies for soft, electrically stable coils and their integration into sensing, communication, and closed-loop platforms. Finally, we highlight recent advances in bioresorbable inductive coil systems.

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From materials to systems: resonant inductive coupling for wireless bioelectronics

Key Points

Abstract

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