Eric M Trautmann
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Explore the profile of Eric M Trautmann including associated specialties, affiliations and a list of published articles.
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12
Citations
555
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Recent Articles
1.
Zhao Z, Yu H, Wisniewski D, Cea C, Ma L, Trautmann E, et al.
Adv Sci (Weinh)
. 2024 Apr;
11(27):e2308014.
PMID: 38600655
Epidermal electrophysiology is a non-invasive method used in research and clinical practices to study the electrical activity of the brain, heart, nerves, and muscles. However, electrode/tissue interlayer materials such as...
2.
Coughlin B, Munoz W, Kfir Y, Young M, Meszena D, Jamali M, et al.
Nat Protoc
. 2023 Sep;
18(10):2927-2953.
PMID: 37697108
Neuropixels are silicon-based electrophysiology-recording probes with high channel count and recording-site density. These probes offer a turnkey platform for measuring neural activity with single-cell resolution and at a scale that...
3.
Stine G, Trautmann E, Jeurissen D, Shadlen M
Neuron
. 2023 Jun;
111(16):2601-2613.e5.
PMID: 37352857
The brain makes decisions by accumulating evidence until there is enough to stop and choose. Neural mechanisms of evidence accumulation are established in association cortex, but the site and mechanism...
4.
Trautmann E, Hesse J, Stine G, Xia R, Zhu S, OShea D, et al.
bioRxiv
. 2023 May;
PMID: 37205406
High-density, integrated silicon electrodes have begun to transform systems neuroscience, by enabling large-scale neural population recordings with single cell resolution. Existing technologies, however, have provided limited functionality in nonhuman primate...
5.
Williams A, Poole B, Maheswaranathan N, Dhawale A, Fisher T, Wilson C, et al.
Neuron
. 2023 May;
111(10):1685.
PMID: 37201504
No abstract available.
6.
Marshall N, Glaser J, Trautmann E, Amematsro E, Perkins S, Shadlen M, et al.
Nat Neurosci
. 2022 Oct;
25(11):1492-1504.
PMID: 36216998
Voluntary movement requires communication from cortex to the spinal cord, where a dedicated pool of motor units (MUs) activates each muscle. The canonical description of MU function rests upon two...
7.
Large-scale neural recordings with single neuron resolution using Neuropixels probes in human cortex
Paulk A, Kfir Y, Khanna A, Mustroph M, Trautmann E, Soper D, et al.
Nat Neurosci
. 2022 Feb;
25(2):252-263.
PMID: 35102333
Recent advances in multi-electrode array technology have made it possible to monitor large neuronal ensembles at cellular resolution in animal models. In humans, however, current approaches restrict recordings to a...
8.
Sun X, OShea D, Golub M, Trautmann E, Vyas S, Ryu S, et al.
Nature
. 2022 Jan;
602(7896):274-279.
PMID: 35082444
The brain's remarkable ability to learn and execute various motor behaviours harnesses the capacity of neural populations to generate a variety of activity patterns. Here we explore systematic changes in...
9.
Trautmann E, OShea D, Sun X, Marshel J, Crow A, Hsueh B, et al.
Nat Commun
. 2021 Jun;
12(1):3689.
PMID: 34140486
Calcium imaging is a powerful tool for recording from large populations of neurons in vivo. Imaging in rhesus macaque motor cortex can enable the discovery of fundamental principles of motor...
10.
Williams A, Poole B, Maheswaranathan N, Dhawale A, Fisher T, Wilson C, et al.
Neuron
. 2019 Dec;
105(2):246-259.e8.
PMID: 31786013
Though the temporal precision of neural computation has been studied intensively, a data-driven determination of this precision remains a fundamental challenge. Reproducible spike patterns may be obscured on single trials...