Take-Home Messages •We report a novel electromagnetic-based sensing mechanism for quantifying naturally released acetone from the human breath. •The proposed technique may be used to continuously monitor acetone levels at ambient temperature and can be ultimately integrated into a wearable device with a detection limit of 1 ppm. •This technology can be used for various health diagnostics, such as fat metabolism, weight loss, type 2 diabetes, and ketosis. •The sensor designed using this electromagnetic approach can be ultimately integrated in a continuous, non-invasive, and personalized device that covers the entire breath acetone range.

We report a novel electromagnetic (EM) based mechanism for quantifying bending in PANI-CA chemo-actuators that detect breath acetone and validate feasibility in a proof-of-concept in vitro setup. Breath acetone serves as a biomarker of human metabolism, yet previously reported techniques are invasive, non-continuous, and/or operate at high temperatures. To overcome these limitations, we rely on previously reported polyaniline and cellulose acetate (PANI-CA) chemo-actuators that are known to flex up to 30° in response to breath acetone levels (i.e., up to 1250 ppm) in a reversible process. Our approach comprises of resonant loops placed in proximity to as well as embedded in 4 cm × 3 mm PANI-CA strips and operates at room temperature. To minimize impact to the strip's mechanical performance, loops are realized on lightweight conductive threads. Using Faraday's law as the strip deforms and the loops misalign, the sensor is shown to monitor acetone-headspace concentration at a limit of de...