Active photonic wireless power transfer into live tissues

Kim, Juho; Seo, Jimin; Jung, Dongwuk; Lee, Tae-Yeon; Ju, Hunpyo; Han, Junkyu; Kim, Namyun; Jeong, Jinmo; Cho, Sungbum; Seol, Jae Hun; Lee, Jong-Ho

doi:10.1073/pnas.2002201117

Cited by 50 publications

(44 citation statements)

References 39 publications

(35 reference statements)

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“…Subdermal solar cells can actively recharge electronic implants using an artificial light source, similar to inductive charging. A recently published study 18 investigated the concept of active photonic power transfer and presented its feasibility during an in vivo trial. The study suggested the use of a skin attachable light emitting patch that constantly illuminates the subdermal solar cell at a wavelengths 670 nm, because the energy per photon and the skin transmittance presented in the study are both high.…”

Section: Discussionmentioning

confidence: 99%

“…An ex vivo trial covered a solar module with a porcine skin flap and analyzed the generated power. 16 The in vivo animal trials were performed in mice 17 , 18 and pigs. 19 , 20 All trials reported promising results in the range of 1.9 to

of generated power by subdermal solar modules at an implantable size scale under midday solar irradiation (AM1.5G).…”

Section: Introductionmentioning

confidence: 99%

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Potential of subdermal solar energy harvesting for medical device applications based on worldwide meteorological data

et al. 2021

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. Significance: Active implants require batteries as power supply. Their lifetime is limited and may require a second surgical intervention for replacement. Intracorporal energy harvesting techniques generate power within the body and supply the implant. Solar cells below the skin can be used to harvest energy from light. Aim: To investigate the potential of subdermal solar energy harvesting. Approach: We evaluated global radiation data for defined time slots and calculated the output power of a subdermal solar module based on skin and solar cell characteristics. We assumed solar exposure profiles based on daily habits for an implanted solar cell. The output power was calculated for skin types VI and I/II. Results: We show that the yearly mean power in most locations on Earth is sufficient to power modern cardiac pacemakers if 10 min midday solar irradiation is assumed. All skin types are suitable for solar harvesting. Moreover, we provide a software tool to predict patient-specific output power. Conclusions: Subdermal solar energy harvesting is a viable alternative to primary batteries. The comparison to a human case study showed a good agreement of the results. The developed code is available open source to enable researchers to investigate further applications of subdermal solar harvesting.

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Section: Discussionmentioning

confidence: 99%

of generated power by subdermal solar modules at an implantable size scale under midday solar irradiation (AM1.5G).…”

Section: Introductionmentioning

confidence: 99%

Potential of subdermal solar energy harvesting for medical device applications based on worldwide meteorological data

et al. 2021

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“…However, transducers based on photovoltaics operated in the tissue transparency region (as discussed in Section 4.2.4) have been demonstrated in stimulators for peripheral nerves, spinal cord, or for powering of pacemakers. [117][118][119][120][121] Typically, inorganic solar cells based on p-i-n silicon or gallium arsenide have been used to power medical implants because of their action spectrum overlap with the tissue transparency window and their high power conversion efficiencies up to 45%. 117,118,122 However, relatively thick material layers are necessary to absorb the light efficiently, thus the devices are quite bulky and rigid.…”

Section: Infrared (Ir) Lightmentioning

confidence: 99%

Wireless Bioelectronic Devices Driven by Deep Red Light

Jakešová

2021

Linköping Studies in Science and Technology. Dissertations

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“…Moreover, an ex-vivo trial irradiated a photovoltaic module below a flap of porcine skin [14]. Acute in-vivo trials with implanted photovoltaic modules in mice [15], [16] and pigs [17], [18] showed promising power outputs. The trials showed that subcutaneous photovoltaic modules at implantable size scales can generate between 2-10 mW cm −2 under midday solar irradiation.…”

Section: Introductionmentioning

confidence: 99%

Implications of Wound Healing on Subcutaneous Photovoltaic Energy Harvesting

Tholl

Spring

Brot

et al. 2022

IEEE Trans. Biomed. Eng.

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Objective: Implanted cardiac pacemakers must be regularly replaced due to depleted batteries. A possible alternative is proposed by subcutaneous photovoltaic energy harvesting. The body's reaction to an implant can cause device encapsulation. Potential changes in spectral light transmission of skin can influence the performance of subcutaneous photovoltaic cells and has not yet been studied in large animal studies. Methods: Subcutaneous implants measuring changes in the light reaching the implant were developed. Three pigs received those implants and were analyzed for seven weeks. Spectral measurements with known irradiation were performed to identify possible changes in the transparency of the tissues above the implant during the wound healing process. A histological analysis at the end of the trial investigated the skin tissue above the subcutaneous photovoltaic implants. Results: The implants measured decreasing light intensity and shifts in the light's spectrum during the initial wound healing phase. In a later stage of tissue recovery, the implants measured a generally reduced light intensity compared to the healthy tissue after implantation. The spectral distribution of the measured light at the end of the trial was similar to the first measurements. The histological analysis showed subcutaneous granulation tissue formation for all devices. Conclusion: The varying reduction of light intensity reaching the implants means that safety margins must be sufficiently high to ensure the power. At the end of the wound healing process, the spectral distribution of the light reaching the implant is similar to healthy tissue. Significance: Optimizations of spectral sensitivity of photovoltaic cells are possible.

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Active photonic wireless power transfer into live tissues

Cited by 50 publications

References 39 publications

Potential of subdermal solar energy harvesting for medical device applications based on worldwide meteorological data

Potential of subdermal solar energy harvesting for medical device applications based on worldwide meteorological data

Wireless Bioelectronic Devices Driven by Deep Red Light

Implications of Wound Healing on Subcutaneous Photovoltaic Energy Harvesting

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