Abstract:
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Miniaturization of active implantable medical devices is currently compromised by the available means for electrically/npowering them. Most common energy supply techniques for implants – batteries and inductive couplers – comprise bulky/nparts which, in most cases, are significantly larger than the circuitry they feed. Here, for overcoming such miniaturization/nbottleneck in the case of implants for electrical stimulation, it is proposed to make those implants act as rectifiers of high/nfrequency bursts supplied by remote electrodes. In this way, low frequency currents will be generated locally around the/nimplant and these low frequency currents will perform stimulation of excitable tissues whereas the high frequency currents/nwill cause only innocuous heating. The present study numerically demonstrates that low frequency currents capable of/nstimulation can be produced by a miniature device behaving as a diode when high frequency currents, neither capable of/nthermal damage nor of stimulation, flow through the tissue where the device is implanted. Moreover, experimental/nevidence is provided by an in vivo proof of concept model consisting of an anesthetized earthworm in which a commercial/ndiode was implanted. With currently available microelectronic techniques, very thin stimulation capsules (diameter/n,500 mm) deliverable by injection are easily conceivable. |
Abstract:
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This author's research is currently supported by a Ramón y Cajal fellowship from the Spanish Ministry for Science and Innovation (RYC-2009-04271) and a Marie Curie International Reintegration Grant (256376 – “TAMIVIVE”) from the European Commission. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript. |