E J Chichilnisky
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Explore the profile of E J Chichilnisky including associated specialties, affiliations and a list of published articles.
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85
Citations
4508
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Recent Articles
1.
Vilkhu R, Vilkhu R, Vasireddy P, Vasireddy P, Kish K, Gogliettino A, et al.
J Neural Eng
. 2024 Dec;
22(1).
PMID: 39705808
Neural interfaces are designed to evoke specific patterns of electrical activity in populations of neurons by stimulating with many electrodes. However, currents passed simultaneously through multiple electrodes often combine nonlinearly...
2.
Wang P, Wu E, Ulusan H, Zhao E, Phillips A, Kling A, et al.
Adv Sci (Weinh)
. 2024 Nov;
12(3):e2408602.
PMID: 39588825
Silicon-based microelectronics can scalably record and modulate neural activity at high spatiotemporal resolution, but their planar form factor poses challenges in targeting 3D neural structures. A method for fabricating tissue-penetrating...
3.
Kling A, Cooler S, Manookin M, Rhoades C, Brackbill N, Field G, et al.
bioRxiv
. 2024 Nov;
PMID: 39554060
The visual image transmitted by the retina to the brain has long been understood in terms of spatial filtering by the center-surround receptive fields of retinal ganglion cells (RGCs). Recently,...
4.
Shah N, Phillips A, Madugula S, Lotlikar A, Gogliettino A, Hays M, et al.
Elife
. 2024 Nov;
13.
PMID: 39508555
Neural implants have the potential to restore lost sensory function by electrically evoking the complex naturalistic activity patterns of neural populations. However, it can be difficult to predict and control...
5.
Jang M, Hays M, Yu W, Lee C, Caragiulo P, Ramkaj A, et al.
IEEE J Solid-State Circuits
. 2024 Oct;
59(4):1123-1136.
PMID: 39391047
This paper presents a data-compressive neural recording IC for single-cell resolution high-bandwidth brain-computer interfaces. The IC features wired-OR lossy compression during digitization, thus preventing data deluge and massive data movement....
6.
Wu E, Brackbill N, Rhoades C, Kling A, Gogliettino A, Shah N, et al.
Nat Commun
. 2024 Sep;
15(1):7964.
PMID: 39261491
Fixational eye movements alter the number and timing of spikes transmitted from the retina to the brain, but whether these changes enhance or degrade the retinal signal is unclear. To...
7.
Vilkhu R, Vasireddy P, Kish K, Gogliettino A, Lotlikar A, Hottowy P, et al.
bioRxiv
. 2024 Sep;
PMID: 39229196
Objective: Neural interfaces are designed to evoke specific patterns of electrical activity in populations of neurons by stimulating with many electrodes. However, currents passed simultaneously through multiple electrodes often combine...
8.
Gogliettino A, Cooler S, Vilkhu R, Brackbill N, Rhoades C, Wu E, et al.
bioRxiv
. 2024 Apr;
PMID: 38585930
Linear-nonlinear (LN) cascade models provide a simple way to capture retinal ganglion cell (RGC) responses to artificial stimuli such as white noise, but their ability to model responses to natural...
9.
Shokri M, Gogliettino A, Hottowy P, Sher A, Litke A, Chichilnisky E, et al.
J Neural Eng
. 2024 Jan;
21(1).
PMID: 38271715
. Bi-directional electronic neural interfaces, capable of both electrical recording and stimulation, communicate with the nervous system to permit precise calibration of electrical inputs by capturing the evoked neural responses....
10.
Wu E, Rudzite A, Bohlen M, Li P, Kling A, Cooler S, et al.
bioRxiv
. 2023 Nov;
PMID: 37986895
Identifying neuronal cell types and their biophysical properties based on their extracellular electrical features is a major challenge for experimental neuroscience and the development of high-resolution brain-machine interfaces. One example...