Battery-free, lightweight, injectable microsystem for in vivo wireless pharmacology and optogenetics

Zhang, Yi; Castro, Daniel C.; Han, Yuan; Wu, Yixin; Guo, Hexia; Weng, Zhengyan; Xue, Yeguang; Ausra, Jokubas; Wang, Xueju; Li, Rui; Wu, Guangfu; Vázquez‐Guardado, Abraham; Xie, Yiwen; Xie, Zhaoqian; Ostojich, Diana; Peng, Dongdong; Sun, Rujie; Wang, Binbin; Yu, Yongjoon; Leshock, John P.; Qu, Subing; Su, Chun Ju; Shen, Wen; Hang, Tao; Banks, Anthony; Huang, Yonggang; Radulovic, Jelena; Gutruf, Philipp; Bruchas, Michael R.; Rogers, John A.

doi:10.1073/pnas.1909850116

Cited by 118 publications

(167 citation statements)

References 61 publications

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“…These devices operate on the basis of diffusion-controlled leakage of drug molecules, with rates that depend on the state of the system as it interacts with the surrounding biology. Although technologies with electronically programmable valves built into reservoirs and fluidic channels enable much greater versatility in the controlled drug release kinetics ( 5 – 7 ), secondary surgical procedures to extract the implanted hardware after completion of the delivery function are required. To overcome these key disadvantages, drug delivery platforms should ideally incorporate (i) active systems with wireless control, (ii) mechanically stable reservoir structures with complete sealing for zero leakage of drugs in the off state and compatibility with any drug chemistry, and (iii) fully bioresorbable construction to eliminate the need for secondary surgical removal processes after treatment.…”

Section: Introductionmentioning

confidence: 99%

Wirelessly controlled, bioresorbable drug delivery device with active valves that exploit electrochemically triggered crevice corrosion

et al. 2020

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Implantable drug release platforms that offer wirelessly programmable control over pharmacokinetics have potential in advanced treatment protocols for hormone imbalances, malignant cancers, diabetic conditions, and others. We present a system with this type of functionality in which the constituent materials undergo complete bioresorption to eliminate device load from the patient after completing the final stage of the release process. Here, bioresorbable polyanhydride reservoirs store drugs in defined reservoirs without leakage until wirelessly triggered valve structures open to allow release. These valves operate through an electrochemical mechanism of geometrically accelerated corrosion induced by passage of electrical current from a wireless, bioresorbable power-harvesting unit. Evaluations in cell cultures demonstrate the efficacy of this technology for the treatment of cancerous tissues by release of the drug doxorubicin. Complete in vivo studies of platforms with multiple, independently controlled release events in live-animal models illustrate capabilities for control of blood glucose levels by timed delivery of insulin.

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Section: Introductionmentioning

confidence: 99%

Wirelessly controlled, bioresorbable drug delivery device with active valves that exploit electrochemically triggered crevice corrosion

et al. 2020

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“…Such a multimodal use for silk films is quite challenging as it involves combining wireless powering and data transmission, vertical interconnect accesses and sensing elements on annealed silk films, all the while ensuring the mechanical and functional integrity of the resulting silk bioelectronic interface. Even with conventional plastic substrate materials such as the polyimide and elastomers, few bioelectronic systems exist [ 116–121 ] that represent the integration of the aforementioned functionalities in a compliant realization.…”

Section: Nontransient Silk: a Materials Candidate For The Soft Bionic mentioning

confidence: 99%

“…[ 118–121,123–134 ] This, in turn, can refashion the current material‐based neurotechnology research and complement the current state of the art in soft bioelectronics. [ 68,116,117,119,120,123,124,133–138 ]…”

Section: Concluding Opinion and Future Outlookmentioning

confidence: 99%

Toward Nontransient Silk Bioelectronics: Engineering Silk Fibroin for Bionic Links

2020

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He maintains his position as a Professor of Biomedical Engineering, Electrical and Computer Engineering, and Neurology at Johns Hopkins University in USA. His technical expertise is in the field of neuroengineering, including neural instrumentation, neuromorphic engineering, neural microsystems, optical imaging of the nervous system, neural control of prosthesis, brain-machine interfaces, and cognitive engineering.

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“…The same sound processor and a similar driver circuitry can also serve for the control of laser diodes in multichannel "passive" oCIs 56 where the light is fed into the cochlea via polymer-based waveguides probes 66 . Future modifications of the described hard-and software framework will also accommodate the combination of electrical and optical stimulation (combined oCI and eCI) for hybrid electro-optical stimulation 26 or optofluidics circuitry for application of photopharmacology into the cochlea and later optical stimulation [67][68][69] . Most studies presenting optogenetic stimulators address brain stimulation [70][71][72][73] , e.g.…”

Section: Utility Of the Developed Oci Systemmentioning

confidence: 99%

Hearing restoration by a low-weight power-efficient multichannel optogenetic cochlear implant system

Jablonski

Harczos

Wolf

et al. 2020

Preprint

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In case of deafness, cochlear implants bypass dysfunctional or lost hair cells by direct electrical stimulation (eCIs) of the auditory nerve. However, spectral selectivity of eCI sound coding is low as the wide current spread from each electrode activates large sets of neurons that align to a place-frequency (tonotopic) map in the cochlea. As light can be better confined in space, optical cochlear implants (oCIs) promise to overcome this shortcoming of eCIs. This requires fine-grained, fast, and power-efficient real-time sound analysis and control of multiple microscale emitters. Here, we describe the development, characterisation, and application for hearing restoration of a preclinical low-weight and wireless LED-based multichannel oCI system and its companion eCI system. The head-worn oCI system enabled deaf rats to perform a locomotion task in response to acoustic stimulation proofing of concept of multichannel optogenetic hearing restoration in rodents.Jablonski, Harczos et al.bioRχiv | 4/31

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Battery-free, lightweight, injectable microsystem for in vivo wireless pharmacology and optogenetics

Cited by 118 publications

References 61 publications

Wirelessly controlled, bioresorbable drug delivery device with active valves that exploit electrochemically triggered crevice corrosion

Wirelessly controlled, bioresorbable drug delivery device with active valves that exploit electrochemically triggered crevice corrosion

Toward Nontransient Silk Bioelectronics: Engineering Silk Fibroin for Bionic Links

Hearing restoration by a low-weight power-efficient multichannel optogenetic cochlear implant system

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