Your search keyword '"Haney CR"' showing total 3 results

1. A wireless and battery-less implant for multimodal closed-loop neuromodulation in small animals.

Author

Ouyang W, Lu W, Zhang Y, Liu Y, Kim JU, Shen H, Wu Y, Luan H, Kilner K, Lee SP, Lu Y, Yang Y, Wang J, Yu Y, Wegener AJ, Moreno JA, Xie Z, Wu Y, Won SM, Kwon K, Wu C, Bai W, Guo H, Liu TL, Bai H, Monti G, Zhu J, Madhvapathy SR, Trueb J, Stanslaski M, Higbee-Dempsey EM, Stepien I, Ghoreishi-Haack N, Haney CR, Kim TI, Huang Y, Ghaffari R, Banks AR, Jhou TC, Good CH, and Rogers JA

Subjects

Animals, Optogenetics methods, Optogenetics instrumentation, Body Temperature physiology, Male, Electric Power Supplies, Sleep physiology, Wakefulness physiology, Rats, Epilepsy therapy, Prostheses and Implants, Wireless Technology instrumentation, Electroencephalography instrumentation, Electroencephalography methods, Electromyography methods

Abstract

Fully implantable wireless systems for the recording and modulation of neural circuits that do not require physical tethers or batteries allow for studies that demand the use of unconstrained and freely behaving animals in isolation or in social groups. Moreover, feedback-control algorithms that can be executed within such devices without the need for remote computing eliminate virtual tethers and any associated latencies. Here we report a wireless and battery-less technology of this type, implanted subdermally along the back of freely moving small animals, for the autonomous recording of electroencephalograms, electromyograms and body temperature, and for closed-loop neuromodulation via optogenetics and pharmacology. The device incorporates a system-on-a-chip with Bluetooth Low Energy for data transmission and a compressed deep-learning module for autonomous operation, that offers neurorecording capabilities matching those of gold-standard wired systems. We also show the use of the implant in studies of sleep-wake regulation and for the programmable closed-loop pharmacological suppression of epileptic seizures via feedback from electroencephalography. The technology can support a broader range of applications in neuroscience and in biomedical research with small animals., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

2. Bioresorbable photonic devices for the spectroscopic characterization of physiological status and neural activity.

Author

Bai W, Shin J, Fu R, Kandela I, Lu D, Ni X, Park Y, Liu Z, Hang T, Wu D, Liu Y, Haney CR, Stepien I, Yang Q, Zhao J, Nandoliya KR, Zhang H, Sheng X, Yin L, MacRenaris K, Brikha A, Aird F, Pezhouh M, Hornick J, Zhou W, and Rogers JA

Subjects

Animals, Biocompatible Materials, Biomedical Engineering instrumentation, Blood Chemical Analysis instrumentation, Blood Chemical Analysis methods, Brain diagnostic imaging, Brain physiology, Equipment Design, Female, Mice, Models, Animal, Neurosciences, Optical Fibers, Silicon chemistry, Temperature, Absorbable Implants, Biosensing Techniques instrumentation, Optics and Photonics instrumentation, Spectrum Analysis methods

Abstract

Capabilities in real-time monitoring of internal physiological processes could inform pharmacological drug-delivery schedules, surgical intervention procedures and the management of recovery and rehabilitation. Current methods rely on external imaging techniques or implantable sensors, without the ability to provide continuous information over clinically relevant timescales, and/or with requirements in surgical procedures with associated costs and risks. Here, we describe injectable classes of photonic devices, made entirely of materials that naturally resorb and undergo clearance from the body after a controlled operational lifetime, for the spectroscopic characterization of targeted tissues and biofluids. As an example application, we show that the devices can be used for the continuous monitoring of cerebral temperature, oxygenation and neural activity in freely moving mice. These types of devices should prove useful in fundamental studies of disease pathology, in neuroscience research, in surgical procedures and in monitoring of recovery from injury or illness.

Published

2019

3. Bioresorbable pressure sensors protected with thermally grown silicon dioxide for the monitoring of chronic diseases and healing processes.

Author

Shin J, Yan Y, Bai W, Xue Y, Gamble P, Tian L, Kandela I, Haney CR, Spees W, Lee Y, Choi M, Ko J, Ryu H, Chang JK, Pezhouh M, Kang SK, Won SM, Yu KJ, Zhao J, Lee YK, MacEwan MR, Song SK, Huang Y, Ray WZ, and Rogers JA

Subjects

Animals, Female, Kinetics, Magnetic Resonance Imaging, Male, Mice, Rats, Inbred Lew, Tissue Distribution, Absorbable Implants, Chronic Disease, Intracranial Pressure, Monitoring, Physiologic instrumentation, Silicon Dioxide chemistry, Temperature, Wound Healing

Abstract

Pressures in the intracranial, intraocular and intravascular spaces are clinically useful for the diagnosis and management of traumatic brain injury, glaucoma and hypertension, respectively. Conventional devices for measuring these pressures require surgical extraction after a relevant operational time frame. Bioresorbable sensors, by contrast, eliminate this requirement, thereby minimizing the risk of infection, decreasing the costs of care and reducing distress and pain for the patient. However, the operational lifetimes of bioresorbable pressure sensors available at present fall short of many clinical needs. Here, we present materials, device structures and fabrication procedures for bioresorbable pressure sensors with lifetimes exceeding those of previous reports by at least tenfold. We demonstrate measurement accuracies that compare favourably to those of the most sophisticated clinical standards for non-resorbable devices by monitoring intracranial pressures in rats for 25 days. Assessments of the biodistribution of the constituent materials, complete blood counts, blood chemistry and magnetic resonance imaging compatibility confirm the biodegradability and clinical utility of the device. Our findings establish routes for the design and fabrication of bioresorbable pressure monitors that meet requirements for clinical use.

Published

2019