2014
DOI: 10.1073/pnas.1403002111
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Wireless power transfer to deep-tissue microimplants

Abstract: The ability to implant electronic systems in the human body has led to many medical advances. Progress in semiconductor technology paved the way for devices at the scale of a millimeter or less ("microimplants"), but the miniaturization of the power source remains challenging. Although wireless powering has been demonstrated, energy transfer beyond superficial depths in tissue has so far been limited by large coils (at least a centimeter in diameter) unsuitable for a microimplant. Here, we show that this limit… Show more

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Cited by 436 publications
(329 citation statements)
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“…Reaching and stimulating these nerves requires excess wiring as well as powering scheme. To avoid implanting a power source, we performed wireless remote neuromodulation of pelvic nerves using the FNC integrated with a tiny coil ( Figure 6 a) for the midfield powering scheme which allows the transfer of mW levels of power to FNC in deep tissue (>5 cm) 18. Figure 6b shows the assembled active FNC implanted on a pelvic nerve.…”
Section: Resultsmentioning
confidence: 99%
See 1 more Smart Citation
“…Reaching and stimulating these nerves requires excess wiring as well as powering scheme. To avoid implanting a power source, we performed wireless remote neuromodulation of pelvic nerves using the FNC integrated with a tiny coil ( Figure 6 a) for the midfield powering scheme which allows the transfer of mW levels of power to FNC in deep tissue (>5 cm) 18. Figure 6b shows the assembled active FNC implanted on a pelvic nerve.…”
Section: Resultsmentioning
confidence: 99%
“…These challenges include (i) for the autonomic nervous system, complex innervation of the organs or muscles, rendering precise control of specific functions challenging; (ii) quick and mechanically secure implantation which is an important consideration in the presence of physiological motion such as respiratory and cardiovascular movements; and (iii) considerable compliance and flexibility from the neural interfaces since nerves are highly compliant and associated with moving organs. Additionally, the integration of NIT with wireless powering by either ultrasound17 or electromagnetic powers18 is a promising direction for future bioelectronic medicine.…”
Section: Introductionmentioning
confidence: 99%
“…Experiments in porcine tissue in the cardiac [ Figure 3 transferred power. A microelectronic stimulator, about 2 mm in diameter and 3 mm in length, weighing 70 mg, was powered using this method and used to pace the heart of a rabbit [31]. These results show that energy transfer can be made largely insensitive to fine tissue structure, provided that some phaseadjustment mechanism is available at the source.…”
Section: Midfield Energy Transfermentioning
confidence: 97%
“…A metal plate patterned with circular slots was shown to reproduce the main features of the optimal current sheet [ Figure 3(a)]. The structure is excited by four radio-frequency ports [31] with different relative phases, which can be adjusted to control the position of the focal point [ Figure 3(b)]. A tiny microelectronic device, containing a coil about 2 mm in diameter, was used to measure power transfer.…”
Section: Midfield Energy Transfermentioning
confidence: 99%
“…The maximum efficiency was shown to be a function of the dielectric property of the tissue, distance between the source and receiver (z f ), and orientation (θ) of the receiver coil. The optimal source with its efficiency close to the global bound was physically realized and measured in [9].…”
Section: Introductionmentioning
confidence: 99%