Your search keyword '"Brendan B. Murphy"' showing total 2 results

1. MXtrodes: MXene-infused bioelectronic interfaces for multiscale electrophysiology and stimulation

Author

Puneet Bagga, Gregory T. Robbins, Sarah E. Gullbrand, M. Sergison, Flavia Vitale, Nicolette Driscoll, Kathryn A. Davis, Andrew G. Richardson, Yury Gogotsi, Timothy R. Dillingham, John A. Wolf, Timothy H. Lucas, Nicholas V. Apollo, Hung-Ching Chen, John D. Medaglia, Ravinder Reddy, Tyler S. Mathis, Kanit Hantanasirisakul, Brendan B. Murphy, and Brian Erickson

Subjects

Fabrication, Computer science, Small animal, Microstimulation, Nanotechnology, Electronics, Electrochemistry, Biocompatible material, Electrical conductor

Abstract

Soft bioelectronic interfaces for mapping and modulating excitable networks at high resolution and at large scale can enable paradigm-shifting diagnostics, monitoring, and treatment strategies. Yet, current technologies largely rely on materials and fabrication schemes that are expensive, do not scale, and critically limit the maximum attainable resolution and coverage. Solution processing is a cost-effective manufacturing alternative, but biocompatible conductive inks matching the performance of conventional metals are lacking. Here, we introduce MXtrodes, a novel class of soft, high-resolution, large-scale bioelectronic interfaces enabled by Ti3C2 MXene and scalable solution processing. We show that the electrochemical properties of MXtrodes exceed those of conventional materials, and do not require conductive gels when used in epidermal electronics. Furthermore, we validate MXtrodes in a number of applications ranging from mapping large scale neuromuscular networks in humans to delivering cortical microstimulation in small animal models. Finally, we demonstrate that MXtrodes are compatible with standard clinical neuroimaging modalities.

Published

2021

2. Multimodal in vivo recording using transparent graphene microelectrodes illuminates spatiotemporal seizure dynamics at the microscale

Author

Ramya Vishnubhotla, Flavia Vitale, Brian Litt, Nicolette Driscoll, Hajime Takano, Olivia O. Dickens, Brendan B. Murphy, A. T. Charlie Johnson, Arian Ashourvan, Kathryn A. Davis, Richard E. Rosch, and Danielle S. Bassett

Subjects

Electrophysiology, Epilepsy, Microelectrode, Seizure onset, Calcium imaging, Computer science, Temporal resolution, medicine, Ictal, medicine.disease, Neuroscience, Microscale chemistry

Abstract

Neurological disorders such as epilepsy arise from disrupted brain networks. Our capacity to treat these disorders is limited by our inability to map these networks at sufficient temporal and spatial scales to target interventions. Current best techniques either sample broad areas at low temporal resolution (e.g. calcium imaging) or record from discrete regions at high temporal resolution (e.g. electrophysiology). This limitation hampers our ability to understand and intervene in aberrations of network dynamics. Here we present a technique to map the onset and spatiotemporal spread of acute epileptic seizures in vivo by simultaneously recording high bandwidth microelectrocorticography and calcium fluorescence using transparent graphene microelectrode arrays. We integrate dynamic data features from both modalities using non-negative matrix factorization to identify sequential spatiotemporal patterns of seizure onset and evolution, revealing how the temporal progression of ictal electrophysiology is linked to the spatial evolution of the recruited seizure core. This integrated analysis of multimodal data reveals otherwise hidden state transitions in the spatial and temporal progression of acute seizures. The techniques demonstrated here may enable future targeted therapeutic interventions and novel spatially embedded models of local circuit dynamics during seizure onset and evolution.

Published

2020