Lukas Bereuter scite author profile

Abstract-Energy harvesting devices are widely discussed as an alternative power source for todays active implantable medical devices. Repeated battery replacement procedures can be avoided by extending the implants life span, which is the goal of energy harvesting concepts. This reduces the risk of complications for the patient and may even reduce device size. The continuous and powerful contractions of a human heart ideally qualify as a battery substitute. In particular, devices in close proximity to the heart such as pacemakers, defibrillators or bio signal (ECG) recorders would benefit from this alternative energy source. The clockwork of an automatic wristwatch was used to transform the hearts kinetic energy into electrical energy. In order to qualify as a continuous energy supply for the consuming device, the mechanism needs to demonstrate its harvesting capability under various conditions. Several in-vivo recorded heart motions were used as input of a mathematical model to optimize the clockworks original conversion efficiency with respect to myocardial contractions. The resulting design was implemented and tested during in-vitro and in-vivo experiments, which demonstrated the superior sensitivity of the new design for all tested heart motions.

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Energy Harvesting by Subcutaneous Solar Cells: A Long-Term Study on Achievable Energy Output

Bereuter

Williner

Pianezzi

et al. 2017

Ann Biomed Eng

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Active electronic implants are powered by primary batteries, which induces the necessity of implant replacement after battery depletion. This causes repeated interventions in a patients’ life, which bears the risk of complications and is costly. By using energy harvesting devices to power the implant, device replacements may be avoided and the device size may be reduced dramatically. Recently, several groups presented prototypes of implants powered by subcutaneous solar cells. However, data about the expected real-life power output of subcutaneously implanted solar cells was lacking so far. In this study, we report the first real-life validation data of energy harvesting by subcutaneous solar cells. Portable light measurement devices that feature solar cells (cell area = 3.6 cm2) and continuously measure a subcutaneous solar cell’s output power were built. The measurement devices were worn by volunteers in their daily routine in summer, autumn and winter. In addition to the measured output power, influences such as season, weather and human activity were analyzed. The obtained mean power over the whole study period was 67 µW (=19 µW cm−2), which is sufficient to power e.g. a cardiac pacemaker.

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The Swiss approach for a heartbeat-driven lead- and batteryless pacemaker

et al. 2017

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Leadless Dual-Chamber Pacing

Bereuter

Gysin

Kueffer

et al. 2018

JACC: Basic to Translational Science

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Lukas Bereuter

Towards Batteryless Cardiac Implantable Electronic Devices—The Swiss Way

Energy Harvesting by Subcutaneous Solar Cells: A Long-Term Study on Achievable Energy Output

The Swiss approach for a heartbeat-driven lead- and batteryless pacemaker

Leadless Dual-Chamber Pacing

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