Patrick T Sadtler
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Explore the profile of Patrick T Sadtler including associated specialties, affiliations and a list of published articles.
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10
Citations
494
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Recent Articles
1.
Losey D, Hennig J, Oby E, Golub M, Sadtler P, Quick K, et al.
Curr Biol
. 2024 Mar;
34(7):1519-1531.e4.
PMID: 38531360
How are we able to learn new behaviors without disrupting previously learned ones? To understand how the brain achieves this, we used a brain-computer interface (BCI) learning paradigm, which enables...
2.
Hennig J, Oby E, Golub M, Bahureksa L, Sadtler P, Quick K, et al.
Nat Neurosci
. 2021 Mar;
24(5):727-736.
PMID: 33782622
Internal states such as arousal, attention and motivation modulate brain-wide neural activity, but how these processes interact with learning is not well understood. During learning, the brain modifies its neural...
3.
Hennig J, Golub M, Lund P, Sadtler P, Oby E, Quick K, et al.
Elife
. 2018 Aug;
7.
PMID: 30109848
Millions of neurons drive the activity of hundreds of muscles, meaning many different neural population activity patterns could generate the same movement. Studies have suggested that these redundant (i.e. behaviorally...
4.
Golub M, Sadtler P, Oby E, Quick K, Ryu S, Tyler-Kabara E, et al.
Nat Neurosci
. 2018 Jul;
21(8):1138.
PMID: 29976964
In the version of this article initially published, equation (10) contained cos Θ instead of sin Θ as the bottom element of the right-hand vector. The error has been corrected...
5.
Golub M, Sadtler P, Oby E, Quick K, Ryu S, Tyler-Kabara E, et al.
Nat Neurosci
. 2018 Mar;
21(4):607-616.
PMID: 29531364
Behavior is driven by coordinated activity across a population of neurons. Learning requires the brain to change the neural population activity produced to achieve a given behavioral goal. How does...
6.
Oby E, Perel S, Sadtler P, Ruff D, Mischel J, Montez D, et al.
J Neural Eng
. 2016 Apr;
13(3):036009.
PMID: 27097901
Objective: A traditional goal of neural recording with extracellular electrodes is to isolate action potential waveforms of an individual neuron. Recently, in brain-computer interfaces (BCIs), it has been recognized that...
7.
Perel S, Sadtler P, Oby E, Ryu S, Tyler-Kabara E, Batista A, et al.
J Neurophysiol
. 2015 Jul;
114(3):1500-12.
PMID: 26133797
A diversity of signals can be recorded with extracellular electrodes. It remains unclear whether different signal types convey similar or different information and whether they capture the same or different...
8.
Lakshmanan K, Sadtler P, Tyler-Kabara E, Batista A, Yu B
Neural Comput
. 2015 Jun;
27(9):1825-56.
PMID: 26079746
Noisy, high-dimensional time series observations can often be described by a set of low-dimensional latent variables. Commonly used methods to extract these latent variables typically assume instantaneous relationships between the...
9.
Sadtler P, Quick K, Golub M, Chase S, Ryu S, Tyler-Kabara E, et al.
Nature
. 2014 Aug;
512(7515):423-6.
PMID: 25164754
Learning, whether motor, sensory or cognitive, requires networks of neurons to generate new activity patterns. As some behaviours are easier to learn than others, we asked if some neural activity...
10.
Perel S, Sadtler P, Godlove J, Ryu S, Wang W, Batista A, et al.
Annu Int Conf IEEE Eng Med Biol Soc
. 2013 Oct;
2013:299-302.
PMID: 24109683
Primary motor-cortex multi-unit activity (MUA) and local-field potentials (LFPs) have both been suggested as potential control signals for brain-computer interfaces (BCIs) aimed at movement restoration. Some studies report that LFP-based...