Talks

Neural mechanisms of active vision in the marmoset monkey, May 2021 | video

Publications

An ethologically motivated neurobiology of primate visually-guided reach-to-grasp behavior (2024). Mitchell JF, Wang KH, Batista AP, Miller CT. Current Opinion in Neurobiology, 86(102872), DOI: 10.1016/j.conb.2024.102872.
Pre-saccadic neural enhancements in marmoset area MT (2023). Coop SH, Yates JL, Mitchell JF. Journal of Neuroscience, JN-RM-2034-22; DOI: 10.1523/JNEUROSCI.2034-22.2023
A dynamic sequence of visual processing initiated by gaze shifts (2023). Parker, P.R.L., Martins, D.M., Leonard, E.S.P. et al. Nat Neurosci 26, 2192–2202. https://doi.org/10.1038/s41593-023-01481-7
Electrophysiology of Laminar Cortical Activity in the Common Marmoset (2023). Bucklaew, A, Coop, SH, Mitchell, JF. J. Vis. Exp. (198), e65397, doi:10.3791/65397.
Detailed characterization of neural selectivity in free-viewing primates (2023). Yates JL, Coop SH, Sarch GH, Wu RJ, Butts DA, Rucci M, Mitchell JF. Nature communications, 14(3656). doi: 10.1038/s41467-023-38564-9
Fast prediction in marmoset reach-to-grasp movements for dynamic prey. Shaw LH, Wang KH, Mitchell JF (2023). Current Biology, 33(12), P2557-2565.e4. doi: 10.1016/j.cub.2023.05.032
Desynchronizing the sleep---wake cycle from circadian timing to assess their separate contributions to physiology and behaviour and to estimate intrinsic circadian period. Wang W, Yuan RK, Mitchell JF, Zitting KM, St Hilaire MA, Wyatt JK, Scheer FAJL, Wright KP Jr, Brown EN, Ronda JM, Klerman EB, Duffy JF, Dijk DJ, Czeisler CA. Nat Protoc. 2022 Nov 14. doi: 10.1038/s41596-022-00746-y.
Post-saccadic following in the marmoset monkey as a read-out of pre-saccadic attention. Coop SH, Bunce G, Abrham Y, Bucklaew A, Mitchell JF. | bioRxiv
Perceptual restoration fails to recover unconscious processing for smooth eye movements after occipital stroke. Kwon S, Fahrenthold BK, Cavanaugh MR, Huxlin KR, Mitchell JF (2022). eLife 2022;11:e67573. DOI: https://doi.org/10.7554/eLife.67573 | pdf
Presaccadic motion integration drives a predictive postsaccadic following response. Kwon S, Rolfs M, Mitchell JF (2019). Journal of vision, 19(11), 12-12. | pdf
Motion Perception in the Common Marmoset. Cloherty SL, Yates JL, Graf D, DeAngelis GC, Mitchell JF (2019). Cereb Cortex. doi: 10.1093/cercor/bhz267. | pdf
Psychophysical measurement of marmoset acuity and myopia. Nummela SU, Coop S, Cloherty SL, Boisvert CJ, Leblanc M, Mitchell JF (2016). Devel Neurobio. Accepted Author Manuscript. Doi:10.1002/denu.22467. | pdf
Optogenetic manipulation of neural circuits in awake marmosets. MacDougall M, Nummela SU, Coop S, Disney A, Mitchell JF, Miller CT (2016). J Neurophysiol, 116(3), 1286-94. | pdf
Marmosets: A Neuroscientific Model of Human Social Behavior. Miller CT, Friewald W, Leopold DA, Mitchell JF, Silva AC, Wang XJ (2016). Neuron, 90(2), 219-233. | pdf
Motion dependence of smooth pursuit eye movements in the marmoset. Mitchell, JF, Priebe, NJ, & Miller, CT (2015). Journal of Neurophysiology, 113(10), 3954-3960. | pdf
The marmoset monkey as a model for visual neuroscience. Mitchell, J. F., & Leopold, D. A. Neuroscience research, 93, 20-46 (2015). | pdf
Active Vision in Marmosets: A Model System for Visual Neuroscience. JF Mitchell, JH Reynolds, CT Miller. The Journal of Neuroscience, 2014, 34(4):1183–1194. | pdf
The fine structure of shape tuning in area V4. AS Nandy, TO Sharpee, JH Reynolds, JF Mitchell. Neuron, 2013, 78:1102-15. | pdf
Attention-dependent reductions in burstiness and action-potential height in macaque area V4. EB Anderson, JF Mitchell, JH Reynolds. Nature Neuroscience 16, 1125-1131 (2013). | pdf
Attention influences single unit and local field potential response latencies in visual cortical area V4. KA Sundberg, JF Mitchell, TJ Gawne, JH Reynolds. J Neurosci, 2012, 32(45):16040-50. | pdf
Attentional modulation of firing rate varies with burstiness across putative pyramidal neurons in macaque visual area V4. EB Anderson, JF Mitchell, JH Reynolds. J Neurosci, 2011, 31(30):10983-92. | pdf
Spatial attention decorrelates intrinsic activity fluctuations in macaque area V4. JF Mitchell, KA Sundberg, JH Reynolds. Neuron, 2009, 63. 879-888. .... and Supplemental | pdf
Spatial attention modulates center-surround interactions in macaque visual area V4. KA Sundberg, JF Mitchell, JH Reynolds. Neuron, 2009, 61. 1-12. | pdf
Differential attention-dependent response modulation across cell classes in macaque visual area V4. JF Mitchell, KA Sundberg, JH Reynolds. Neuron, 2007, 55. 131-141. ... and Supplemental | pdf
ERP evidence that surface-based attention biases interocular competition during rivalry. W Khoe, JF Mitchell, JH Reynolds, SA Hillyard. J. Vision, 2008, 8(3):18, p1-11. | pdf
Exogenous attentional selection of transparent superimposed surfaces modulates early event-related potentials. W Khoe, JF Mitchell, JH Reynolds, SA Hillyard. Vision Research, 2005, 45. 3004-3014. | pdf
Object-based attention determines dominance in binocular rivalry. JF Mitchell, GR Stoner, JH Reynolds. Nature, 2004, 429. 410-413. | pdf
Sequential memory-guided saccades and target selection: A neural model of the frontal eye fields. JF Mitchell and D Zipser. Vision Research, 2003, 43. 2669-2695. | pdf
Attentional selection of superimposed surfaces cannot be explained by modulation of the gain of color channels. JF Mitchell, GR Stoner, M Fallah, and JH Reynolds. Vision Research, 2003, 43(12). 1323-8. | pdf
A model of visual-spatial memory across saccades. JF Mitchell and D Zipser. Vision Research 41(2001): 1575-1592. | pdf
Age-independent stability, prevision, and near-24-hour period of the human circadian pacemaker. Czeisler CA, Duffy JF, Shanahan TL, Brown EN, Mitchell JF, Rimmer DW, Ronda JM, Silva EJ, Allan JS, Emens JS, Dijk DJ, Kronauer RE. Science, 1999, June, 284: 1-5. | pdf