Your search keyword '"Jacob T. Robinson"' showing total 3 results

1. A wireless millimetric magnetoelectric implant for the endovascular stimulation of peripheral nerves

Author

Joshua C. Chen, Peter Kan, Zhanghao Yu, Fatima Alrashdan, Roberto Garcia, Amanda Singer, C. S. Edwin Lai, Ben Avants, Scott Crosby, Zhongxi Li, Boshuo Wang, Michelle M. Felicella, Ariadna Robledo, Angel V. Peterchev, Stefan M. Goetz, Jeffrey D. Hartgerink, Sunil A. Sheth, Kaiyuan Yang, Jacob T. Robinson, Alrashdan, Fatima [0000-0001-7605-1056], Garcia, Roberto [0000-0001-8907-9867], Wang, Boshuo [0000-0003-1680-5957], Peterchev, Angel V [0000-0002-4385-065X], Goetz, Stefan M [0000-0002-1944-0714], Hartgerink, Jeffrey D [0000-0002-3186-5395], Sheth, Sunil A [0000-0003-0602-8509], Yang, Kaiyuan [0000-0001-7220-9389], Robinson, Jacob T [0000-0002-3509-3054], and Apollo - University of Cambridge Repository

Subjects

Electric Power Supplies, Swine, Biomedical Engineering, Animals, Medicine (miscellaneous), Bioengineering, Prostheses and Implants, Proof of Concept Study, Sciatic Nerve, Wireless Technology, Rats, Computer Science Applications, Biotechnology

Abstract

Funder: NIH U18EB029353, NSF GRFP, Funder: NIH U18EB029353, Funder: NIH R01DE021798, NSF GRFP, Funder: NIH R01DE021798, Implantable bioelectronic devices for the simulation of peripheral nerves could be used to treat disorders that are resistant to traditional pharmacological therapies. However, for many nerve targets, this requires invasive surgeries and the implantation of bulky devices (about a few centimetres in at least one dimension). Here we report the design and in vivo proof-of-concept testing of an endovascular wireless and battery-free millimetric implant for the stimulation of specific peripheral nerves that are difficult to reach via traditional surgeries. The device can be delivered through a percutaneous catheter and leverages magnetoelectric materials to receive data and power through tissue via a digitally programmable 1 mm × 0.8 mm system-on-a-chip. Implantation of the device directly on top of the sciatic nerve in rats and near a femoral artery in pigs (with a stimulation lead introduced into a blood vessel through a catheter) allowed for wireless stimulation of the animals' sciatic and femoral nerves. Minimally invasive magnetoelectric implants may allow for the stimulation of nerves without the need for open surgery or the implantation of battery-powered pulse generators.

Published

2022

2. In vivo lensless microscopy via a phase mask generating diffraction patterns with high-contrast contours

Author

Jesse K. Adams, Dong Yan, Jimin Wu, Vivek Boominathan, Sibo Gao, Alex V. Rodriguez, Soonyoung Kim, Jennifer Carns, Rebecca Richards-Kortum, Caleb Kemere, Ashok Veeraraghavan, and Jacob T. Robinson

Subjects

Mice, Microscopy, Optics and Photonics, Biomedical Engineering, Animals, Humans, Medicine (miscellaneous), Bioengineering, Algorithms, Computer Science Applications, Biotechnology

Abstract

The simple and compact optics of lensless microscopes and the associated computational algorithms allow for large fields of view and the refocusing of the captured images. However, existing lensless techniques cannot accurately reconstruct the typical low-contrast images of optically dense biological tissue. Here we show that lensless imaging of tissue in vivo can be achieved via an optical phase mask designed to create a point spread function consisting of high-contrast contours with a broad spectrum of spatial frequencies. We built a prototype lensless microscope incorporating the ‘contour’ phase mask and used it to image calcium dynamics in the cortex of live mice (over a field of view of about 16 mm2) and in freely moving Hydra vulgaris, as well as microvasculature in the oral mucosa of volunteers. The low cost, small form factor and computational refocusing capability of in vivo lensless microscopy may open it up to clinical uses, especially for imaging difficult-to-reach areas of the body.

Published

2022

3. A wireless millimetric magnetoelectric implant for the endovascular stimulation of peripheral nerves

Author

Joshua C, Chen, Peter, Kan, Zhanghao, Yu, Fatima, Alrashdan, Roberto, Garcia, Amanda, Singer, C S Edwin, Lai, Ben, Avants, Scott, Crosby, Zhongxi, Li, Boshuo, Wang, Michelle M, Felicella, Ariadna, Robledo, Angel V, Peterchev, Stefan M, Goetz, Jeffrey D, Hartgerink, Sunil A, Sheth, Kaiyuan, Yang, and Jacob T, Robinson

Subjects

Electric Power Supplies, Swine, Animals, Prostheses and Implants, Proof of Concept Study, Sciatic Nerve, Wireless Technology, Rats

Abstract

Implantable bioelectronic devices for the simulation of peripheral nerves could be used to treat disorders that are resistant to traditional pharmacological therapies. However, for many nerve targets, this requires invasive surgeries and the implantation of bulky devices (about a few centimetres in at least one dimension). Here we report the design and in vivo proof-of-concept testing of an endovascular wireless and battery-free millimetric implant for the stimulation of specific peripheral nerves that are difficult to reach via traditional surgeries. The device can be delivered through a percutaneous catheter and leverages magnetoelectric materials to receive data and power through tissue via a digitally programmable 1 mm × 0.8 mm system-on-a-chip. Implantation of the device directly on top of the sciatic nerve in rats and near a femoral artery in pigs (with a stimulation lead introduced into a blood vessel through a catheter) allowed for wireless stimulation of the animals' sciatic and femoral nerves. Minimally invasive magnetoelectric implants may allow for the stimulation of nerves without the need for open surgery or the implantation of battery-powered pulse generators.

Published

2021