Circuits for presaccadic visual remapping

Journal of Neurophysiology

Volumn 116, Issue 6, 2016, Pages 2624-2636

  Rao, Hrishikesh M ^a   Mayo, J Patrick ^b   Sommer, Marc A ^a,b,c  

^a Duke University   (United States)

^b DUKE UNIVERSITY SCHOOL OF MEDICINE   (United States)

^c DUKE UNIVERSITY   (United States)

Author keywords

Eye movements; Perception; Remapping; Saccades; Vision

Indexed keywords

BRAIN MAPPING; EYE MOVEMENT CONTROL; FRONTAL EYE FIELD; HUMAN; MONOSYNAPTIC REFLEX; NONHUMAN; PRIORITY JOURNAL; RECEPTIVE FIELD; REVIEW; SACCADIC EYE MOVEMENT; SACCADIC SUPPRESSION; SUPERIOR COLLICULUS; THALAMUS; VISION; VISUAL CORTEX; VISUAL INFORMATION; VISUAL STIMULATION; ANIMAL; BRAIN; NERVE CELL NETWORK; PHOTOSTIMULATION; PHYSIOLOGY; VISUAL FIELD; VISUAL SYSTEM;

ANIMALS; BRAIN; BRAIN MAPPING; HUMANS; NERVE NET; PHOTIC STIMULATION; SACCADES; VISUAL FIELDS; VISUAL PATHWAYS;

EID: 85002373963     PISSN: 00223077     EISSN: 15221598     Source Type: Journal    
DOI: 10.1152/jn.00182.2016     Document Type: Review

References (153)

1. Adams MM, Hof PR, Gattass R, Webster MJ, Ungerleider LG. Visual cortical projections and chemoarchitecture of macaque monkey pulvinar. J Comp Neurol 419: 377-393, 2000.
2. Aizawa H, Wurtz RH. Reversible inactivation of monkey superior colliculus. I. Curvature of saccadic trajectory. J Neurophysiol 79: 2082-2096, 1998.
3. Angelucci A, Levitt JB, Walton EJ, Hupe JM, Bullier J, Lund JS. Circuits for local and global signal integration in primary visual cortex. J Neurosci 22: 8633-8646, 2002.
4. Arcizet F, Mirpour K, Bisley JW. A pure salience response in posterior parietal cortex. Cereb Cortex 21: 2498-2506, 2011.
5. Atsma J, Maij F, Corneil BD, Medendorp WP. No perisaccadic mislocal-ization with abruptly cancelled saccades. J Neurosci 34: 5497-5504, 2014.
6. Bair W, Cavanaugh JR, Movshon JA. Time course and time-distance relationships for surround suppression in macaque V1 neurons. J Neurosci 23: 7690-7701, 2003.
7. Bansal S, Jayet Bray LC, Peterson MS, Joiner WM. The effect of saccade metrics on the corollary discharge contribution to perceived eye location. J Neurophysiol 113: 3312-3322, 2015.
8. Barash S, Bracewell RM, Fogassi L, Gnadt JW, Andersen RA. Saccade-related activity in the lateral intraparietal area. I. Temporal properties; comparison with area 7a. J Neurophysiol 66: 1095-1108, 1991a.
9. Barash S, Bracewell RM, Fogassi L, Gnadt JW, Andersen RA. Saccade-related activity in the lateral intraparietal area. II. Spatial properties. J Neurophysiol 66: 1109-1124, 1991b.
10. Barbas H, Mesulam MM. Organization of afferent input to subdivisions of area 8 in the rhesus monkey. J Comp Neurol 200: 407-431, 1981.
11. Benevento LA, Fallon JH. The ascending projections of the superior collicu-lus in the rhesus monkey (Macaca mulatto). J Comp Neurol 160: 339-361, 1975.
12. Benevento LA, Rezak M. The cortical projections of the inferior pulvinar and adjacent lateral pulvinar in the rhesus monkey (Macaca mulatta): an autoradiographic study. Brain Res 108: 1-24, 1976.
13. Bichot NP, Schall JD, Thompson KG. Visual feature selectivity in frontal eye fields. Nature 381: 697-699, 1996.
14. Binda P, Cicchini GM, Burr DC, Morrone MC. Spatiotemporal distortions of visual perception at the time of saccades. J Neurosci 29: 13147-13157, 2009.
15. Bisley JW, Goldberg ME. Attention, intention, and priority in the parietal lobe. Annu Rev Neurosci 33: 1-21, 2010.
16. Blatt GJ, Andersen RA, Stoner GR. Visual receptive field organization and cortico-cortical connections of the lateral intraparietal area (area LIP) in the macaque. J Comp Neurol 299: 421-445, 1990.
17. Bozis A, Moschovakis AK. Neural network simulations of the primate oculomotor system. III. A one-dimensional, one-directional model of the superior colliculus. Biol Cybern 79: 215-230, 1998.
18. Bridgeman B, Hendry D, Stark L. Failure to detect displacement of the visual world during saccadic eye movements. Vision Res 15: 719-722, 1975.
19. Bringuier V, Chavane F, Glaeser L, Fregnac Y. Horizontal propagation of visual activity in the synaptic integration field of area 17 neurons. Science 283: 695-699, 1999.
20. Bruce CJ, Goldberg ME. Primate frontal eye fields. I. Single neurons discharging before saccades. J Neurophysiol 53: 603-635, 1985.
21. Bruce CJ, Goldberg ME, Bushnell MC, Stanton GB. Primate frontal eye fields. II. Physiological and anatomical correlates of electrically evoked eye movements. J Neurophysiol 54: 714-734, 1985.
22. Bullier J, Schall JD, Morel A. Functional streams in occipito-frontal connections in the monkey. Behav Brain Res 76: 89-97, 1996.
23. Cavanagh P, Hunt AR, Afraz A, Rolfs M. Visual stability based on remapping of attention pointers. Trends Cogn Sci 14: 147-153, 2010.
24. Cavanaugh J, Berman RA, Joiner WM, Wurtz RH. Saccadic corollary discharge underlies stable visual perception. J Neurosci 36: 31-42, 2016.
25. Chafee MV, Goldman-Rakic PS. Matching patterns of activity in primate prefrontal area 8a and parietal area 7ip neurons during a spatial working memory task. J Neurophysiol 79: 2919-2940, 1998.
26. Chafee MV, Goldman-Rakic PS. Inactivation of parietal and prefrontal cortex reveals interdependence of neural activity during memory-guided saccades. J Neurophysiol 83: 1550-1566, 2000.
27. Chen Y, Martinez-Conde S, Macknik SL, Bereshpolova Y, Swadlow HA, Alonso JM. Task difficulty modulates the activity of specific neuronal populations in primary visual cortex. Nat Neurosci 11: 974-982, 2008.
28. Churan J, Guitton D, Pack CC. Context dependence of receptive field remapping in superior colliculus. J Neurophysiol 106: 1862-1874, 2011.
29. Churan J, Guitton D, Pack CC. Perisaccadic remapping and rescaling of visual responses in macaque superior colliculus. PloS One 7: e52195, 2012.
30. Clower DM, West RA, Lynch JC, Strick PL. The inferior parietal lobule is the target of output from the superior colliculus, hippocampus, and cerebellum. J Neurosci 21: 6283-6291, 2001.
31. Cohen JY, Pouget P, Heitz RP, Woodman GF, Schall JD. Biophysical support for functionally distinct cell types in the frontal eye field. J Neurophysiol 101: 912-916, 2009.
32. Collins T, Rolfs M, Deubel H, Cavanagh P. Post-saccadic location judgments reveal remapping of saccade targets to non-foveal locations. J Vis 9: 5, 2009.
33. Connor CE, Gallant JL, Preddie DC, Van Essen DC. Responses in area V4 depend on the spatial relationship between stimulus and attention. J Neurophysiol 75: 1306-1308, 1996.
34. Connor CE, Preddie DC, Gallant JL, Van Essen DC. Spatial attention effects in macaque area V4. J Neurosci 17: 3201-3214, 1997.
35. Constantinidis C, Goldman-Rakic PS. Correlated discharges among putative pyramidal neurons and interneurons in the primate prefrontal cortex. J Neurophysiol 88: 3487-3497, 2002.
36. Crapse TB, Sommer MA. The frontal eye field as a prediction map. Prog Brain Res 171: 383-390, 2008.
37. Crapse TB, Sommer MA. Frontal eye field neurons with spatial representations predicted by their subcortical input. J Neurosci 29: 5308-5318, 2009.
38. Crapse TB, Sommer MA. Frontal eye field activity predicts performance in a visual stability judgment task (Abstract). Neuroscience Meeting Planner 2010: Program No. 280.20, 2010a.
39. Crapse TB, Sommer MA. Translation of a visual stimulus during a saccade is more detectable if it moves perpendicular, rather than parallel, to the saccade. J Vis 10: 521, 2010b.
40. Crapse TB, Sommer MA. Frontal eye field neurons assess visual stability across saccades. J Neurosci 32: 2835-2845, 2012.
41. Deneve S, Duhamel JR, Pouget A. Optimal sensorimotor integration in recurrent cortical networks: a neural implementation of Kalman filters. J Neurosci 27: 5744-5756, 2007.
42. Deubel H, Bridgeman B, Schneider WX. Immediate post-saccadic information mediates space constancy. Vision Res 38: 3147-3159, 1998.
43. Deubel H, Schneider WX. Saccade target selection and object recognition: evidence for a common attentional mechanism. Vision Res 36: 1827-1837, 1996.
44. Dias EC, Kiesau M, Segraves MA. Acute activation and inactivation of macaque frontal eye field with GABA-related drugs. J Neurophysiol 74: 2744-2748, 1995.
45. Dias EC, Segraves MA. Muscimol-induced inactivation of monkey frontal eye field: effects on visually and memory-guided saccades. J Neurophysiol 81: 2191-2214, 1999.
46. Douglas RJ, Martin KA. Neuronal circuits of the neocortex. Annu Rev Neurosci 27: 419-451, 2004.
47. Droulez J, Berthoz A. A neural network model of sensoritopic maps with predictive short-term memory properties. Proc Natl Acad Sci USA 88: 9653-9657, 1991.
48. Duhamel JR, Colby CL, Goldberg ME. The updating of the representation of visual space in parietal cortex by intended eye movements. Science 255: 90-92, 1992.
49. Fecteau JH, Munoz DP. Salience, relevance, and firing: a priority map for target selection. Trends Cogn Sci 10: 382-390, 2006.
50. Ferraina S, Pare M, Wurtz RH. Comparison of cortico-cortical and cortico-collicular signals for the generation of saccadic eye movements. J Neurophysiol 87: 845-858, 2002.
51. Fries W. Cortical projections to the superior colliculus in the macaque monkey: a retrograde study using horseradish peroxidase. J Comp Neurol 230: 55-76, 1984.
52. Giguere M, Goldman-Rakic PS. Mediodorsal nucleus: areal, laminar, and tangential distribution of afferents and efferents in the frontal lobe of rhesus monkeys. J Comp Neurol 277: 195-213, 1988.
53. Gilbert CD, Das A, Ito M, Kapadia M, Westheimer G. Spatial integration and cortical dynamics. Proc Natl Acad Sci USA 93: 615-622, 1996.
54. Goldberg ME, Bruce CJ. Primate frontal eye fields. III. Maintenance of a spatially accurate saccade signal. J Neurophysiol 64: 489-508, 1990.
55. Goldman-Rakic PS, Porrino LJ. The primate mediodorsal (MD) nucleus and its projection to the frontal lobe. J Comp Neurol 242: 535-560, 1985.
56. Graf AB, Andersen RA. Inferring eye position from populations of lateral intraparietal neurons. Elife 3: e02813, 2014.
57. Hall NJ, Colby CL. Remapping for visual stability. Philos Trans R Soc Lond B Biol Sci 366: 528-539, 2011.
58. Hamker FH, Zirnsak M. V4 receptive field dynamics as predicted by a systems-level model of visual attention using feedback from the frontal eye field. Neural Netw 19: 1371-1382, 2006.
59. Hangya B, Pi HJ, Kvitsiani D, Ranade SP, Kepecs A. From circuit motifs to computations: mapping the behavioral repertoire of cortical interneurons. Curr Opin Neurobiol 26: 117-124, 2014.
60. Hartmann TS, Bremmer F, Albright TD, Krekelberg B. Receptive field positions in area MT during slow eye movements. J Neurosci 31: 10437-10444, 2011.
61. Heider B, Nathanson JL, Isacoff EY, Callaway EM, Siegel RM. Two-photon imaging of calcium in virally transfected striate cortical neurons of behaving monkey. PloS One 5: e13829, 2010.
62. Heiser LM, Colby CL. Spatial updating in area LIP is independent of saccade direction. J Neurophysiol 95: 2751-2767, 2006.
63. Von Helmholtz H. Helmholtz’s Treatise on Physiological Optics. New York: Dover, 1962, vol. 2, p. 3.
64. Honda H. The time courses of visual mislocalization and of extraretinal eye position signals at the time of vertical saccades. Vision Res 31: 1915-1921, 1991.
65. Huerta MF, Krubitzer LA, Kaas JH. Frontal eye field as defined by intracortical microstimulation in squirrel monkeys, owl monkeys, and macaque monkeys. I. Subcortical connections. J Comp Neurol 253: 415-439, 1986.
66. Ibbotson M, Krekelberg B. Visual perception and saccadic eye movements. Curr Opin Neurobiol 21: 553-558, 2011.
67. Inaba N, Kawano K. Neurons in cortical area MST remap the memory trace of visual motion across saccadic eye movements. Proc Natl Acad Sci USA 111: 7825-7830, 2014.
68. Jayet Bray LC, Bansal S, Joiner WM. Quantifying the spatial extent of the corollary discharge benefit to transsaccadic visual perception. J Neurophysiol 115: 1132-1145, 2016.
69. Jia H, Rochefort NL, Chen X, Konnerth A. Dendritic organization of sensory input to cortical neurons in vivo. Nature 464: 1307-1312, 2010.
70. Joiner WM, Cavanaugh J, FitzGibbon EJ, Wurtz RH. Corollary discharge contributes to perceived eye location in monkeys. J Neurophysiol 110: 2402-2413, 2013a.
71. Joiner WM, Cavanaugh J, Wurtz RH. Compression and suppression of shifting receptive field activity in frontal eye field neurons. J Neurosci 33: 18259-18269, 2013b.
72. Keith GP, Blohm G, Crawford JD. Influence of saccade efference copy on the spatiotemporal properties of remapping: a neural network study. J Neurophysiol 103: 117-139, 2010.
73. Keith GP, Crawford JD. Saccade-related remapping of target representations between topographic maps: a neural network study. J Comput Neurosci 24: 157-178, 2008.
74. Kievit J, Kuypers HG. Organization of the thalamo-cortical connexions to the frontal lobe in the rhesus monkey. Exp Brain Res 29: 299-322, 1977.
75. Kowler E, Anderson E, Dosher B, Blaser E. The role of attention in the programming of saccades. Vision Res 35: 1897-1916, 1995.
76. Kusunoki M, Goldberg ME. The time course of perisaccadic receptive field shifts in the lateral intraparietal area of the monkey. J Neurophysiol 89: 1519-1527, 2003.
77. Leichnetz GR. Connections of the medial posterior parietal cortex (area 7m) in the monkey. Anat Rec 263: 215-236, 2001.
78. Lynch JC, Hoover JE, Strick PL. Input to the primate frontal eye field from the substantia nigra, superior colliculus, and dentate nucleus demonstrated by transneuronal transport. Exp Brain Res 100: 181-186, 1994.
79. Lyon DC, Nassi JJ, Callaway EM. A disynaptic relay from superior collicu-lus to dorsal stream visual cortex in macaque monkey. Neuron 65: 270-279, 2010.
80. Marino AC, Mazer JA. Perisaccadic updating of visual representations and attentional states: linking behavior and neurophysiology. Front Syst Neuro-sci 10: 3, 2016.
81. Mayo JP, DiTomasso AR, Sommer MA, Smith MA. Dynamics of visual receptive fields in the macaque frontal eye field. J Neurophysiol 114: 3201-3210, 2015.
82. Mayo JP, Morrison RM, Smith MA. A probabilistic approach to receptive field mapping in the frontal eye fields. Front Syst Neurosci 10: 25, 2016.
83. Mayo JP, Sommer MA. Neuronal adaptation caused by sequential visual stimulation in the frontal eye field. J Neurophysiol 100: 1923-1935, 2008.
84. Mayo JP, Sommer MA. Shifting attention to neurons. Trends Cogn Sci 14: 389, 2010.
85. Mayo JP, Verhoef BE. Feature-specific clusters of neurons and decision-related neuronal activity. J Neurosci 34: 8385-8386, 2014.
86. Mays LE, Sparks DL. Dissociation of visual and saccade-related responses in superior colliculus neurons. J Neurophysiol 43: 207-232, 1980.
87. Melcher D. Predictive remapping of visual features precedes saccadic eye movements. Nat Neurosci 10: 903-907, 2007.
88. Melcher D, Colby CL. Trans-saccadic perception. Trends Cogn Sci 12: 466-473, 2008.
89. Mendoza G, Merchant H. Motor system evolution and the emergence of high cognitive functions. Prog Neurobiol 122: 73-93, 2014.
90. Merriam EP, Genovese CR, Colby CL. Remapping in human visual cortex. J Neurophysiol 97: 1738-1755, 2007.
91. Mirpour K, Bisley JW. Anticipatory remapping of attentional priority across the entire visual field. J Neurosci 32: 16449-16457, 2012.
92. Mirpour K, Bisley JW. Remapping, spatial stability, and temporal continuity: from the pre-saccadic to postsaccadic representation of visual space in LIP. Cereb Cortex 26: 3183-3195, 2016.
93. Mishkin M, Ungerleider LG, Macko KA. Object vision and spatial vision: two cortical pathways. Trends Neurosci 6: 414-417, 1983.
94. Mohler CW, Goldberg ME, Wurtz RH. Visual receptive fields of frontal eye field neurons. Brain Res 61: 385-389, 1973.
95. Morris AP, Bremmer F, Krekelberg B. The dorsal visual system predicts future and remembers past eye position. Front Syst Neurosci 10: 9, 2016.
96. Morris AP, Kubischik M, Hoffmann KP, Krekelberg B, Bremmer F. Dynamics of eye-position signals in the dorsal visual system. Curr Biol 22: 173-179, 2012.
97. Nakamura K, Colby CL. Updating of the visual representation in monkey striate and extrastriate cortex during saccades. Proc Natl Acad Sci USA 99: 4026-4031, 2002.
98. Neupane S, Guitton D, Pack CC. Dissociation of forward and convergent remapping in primate visual cortex. Curr Biol 26: R491-R492, 2016a.
99. Neupane S, Guitton D, Pack CC. Two distinct types of remapping in primate cortical area V4. Nat Commun 7: 10402, 2016b.
100. Ong WS, Bisley JW. A lack of anticipatory remapping of retinotopic receptive fields in the middle temporal area. J Neurosci 31: 10432-10436, 2011.
101. Pare M, Wurtz RH. Monkey posterior parietal cortex neurons antidromically activated from superior colliculus. J Neurophysiol 78: 3493-3497, 1997.
102. Pare M, Wurtz RH. Progression in neuronal processing for saccadic eye movements from parietal cortex area LIP to superior colliculus. J Neurophysiol 85: 2545-2562, 2001.
103. Peng X, Sereno ME, Silva AK, Lehky SR, Sereno AB. Shape selectivity in primate frontal eye field. J Neurophysiol 100: 796-814, 2008.
104. Petrides M, Pandya DN. Projections to the frontal cortex from the posterior parietal region in the rhesus monkey. J Comp Neurol 228: 105-116, 1984.
105. Pouget A, Deneve S, Duhamel JR. A computational perspective on the neural basis of multisensory spatial representations. Nat Rev Neurosci 3: 741-747, 2002.
106. Quaia C, Aizawa H, Optican LM, Wurtz RH. Reversible inactivation of monkey superior colliculus. II. Maps of saccadic deficits. J Neurophysiol 79: 2097-2110, 1998a.
107. Quaia C, Optican LM, Goldberg ME. The maintenance of spatial accuracy by the perisaccadic remapping of visual receptive fields. Neural Netw 11: 1229-1240, 1998b.
108. Rao HM, Abzug ZM, Sommer MA. Visual continuity across saccades is influenced by expectations. J Vis 16: 7, 2016a.
109. Rao HM, Juan SM, Shen FY, Villa JE, Rafie KS, Sommer MA. Neural network evidence for the coupling of presaccadic visual remapping to predictive eye position updating. Front Comput Neurosci 10: 52, 2016b.
110. Richmond BJ, Wurtz RH. Vision during saccadic eye movements. II. A corollary discharge to monkey superior colliculus. J Neurophysiol 43: 1156-1167, 1980.
111. Robinson DL, Wurtz RH. Use of an extraretinal signal by monkey superior colliculus neurons to distinguish real from self-induced stimulus movement. J Neurophysiol 39: 852-870, 1976.
112. Salinas E, Sejnowski TJ. Gain modulation in the central nervous system: where behavior, neurophysiology, and computation meet. Neuroscientist 7: 430-440, 2001.
113. Schall JD. The neural selection and control of saccades by the frontal eye field. Philos Trans R Soc Lond B Biol Sci 357: 1073-1082, 2002.
114. Schall JD. Production, control, and visual guidance of saccadic eye movements. ISRNNeurol 2013: 1-17, 2013.
115. Schall JD, Morel A, King DJ, Bullier J. Topography of visual cortex connections with frontal eye field in macaque: convergence and segregation of processing streams. J Neurosci 15: 4464-4487, 1995.
116. Schlag-Rey M, Schlag J. Visuomotor functions of central thalamus in monkey. I. Unit activity related to spontaneous eye movements. J Neurophysiol 51: 1149-1174, 1984.
117. Sereno AB, Sereno ME, Lehky SR. Recovering stimulus locations using populations of eye-position modulated neurons in dorsal and ventral visual streams of non-human primates. Front Integr Neurosci 8: 28, 2014.
118. Shin S, Sommer MA. Division of labor in frontal eye field neurons during presaccadic remapping of visual receptive fields. J Neurophysiol 108: 2144-2159, 2012.
119. Sommer MA, Tehovnik EJ. Reversible inactivation of macaque frontal eye field. Exp Brain Res 116: 229-249, 1997.
120. Sommer MA, Wurtz RH. Frontal eye field neurons orthodromically activated from the superior colliculus. J Neurophysiol 80: 3331-3335, 1998.
121. Sommer MA, Wurtz RH. Composition and topographic organization of signals sent from the frontal eye field to the superior colliculus. J Neurophysiol 83: 1979-2001, 2000.
122. Sommer MA, Wurtz RH. Frontal eye field sends delay activity related to movement, memory, and vision to the superior colliculus. J Neurophysiol 85: 1673-1685, 2001.
123. Sommer MA, Wurtz RH. A pathway in primate brain for internal monitoring of movements. Science 296: 1480-1482, 2002.
124. Sommer MA, Wurtz RH. What the brain stem tells the frontal cortex. I. Oculomotor signals sent from superior colliculus to frontal eye field via mediodorsal thalamus. J Neurophysiol 91: 1381-1402, 2004a.
125. Sommer MA, Wurtz RH. What the brain stem tells the frontal cortex. II. Role of the SC-MD-FEF pathway in corollary discharge. J Neurophysiol 91: 1403-1423, 2004b.
126. Sommer MA, Wurtz RH. Influence of the thalamus on spatial visual processing in frontal cortex. Nature 444: 374-377, 2006.
127. Sommer MA, Wurtz RH. Brain circuits for the internal monitoring of movements. Annu Rev Neurosci 31: 317-338, 2008a.
128. Sommer MA, Wurtz RH. Visual perception and corollary discharge. Perception 37: 408-418, 2008b.
129. Song JH, McPeek RM. Roles of narrow-and broad-spiking dorsal premotor area neurons in reach target selection and movement production. J Neurophysiol 103: 2124-2138, 2010.
130. Sperry RW. Neural basis of the spontaneous optokinetic response produced by visual inversion. J Comp Physiol Psychol 43: 482-489, 1950.
131. Stanton GB, Bruce CJ, Goldberg ME. Topography of projections to posterior cortical areas from the macaque frontal eye fields. J Comp Neurol 353: 291-305, 1995.
132. Stanton GB, Goldberg ME, Bruce CJ. Frontal eye field efferents in the macaque monkey. I. Subcortical pathways and topography of striatal and thalamic terminal fields. J Comp Neurol 271: 473-492, 1988.
133. Subramanian J, Colby CL. Shape selectivity and remapping in dorsal stream visual area LIP. J Neurophysiol 111: 613-627, 2014.
134. Tan AY, Chen Y, Scholl B, Seidemann E, Priebe NJ. Sensory stimulation shifts visual cortex from synchronous to asynchronous states. Nature 509: 226-229, 2014.
135. Tanaka M. Inactivation of the central thalamus delays self-timed saccades. Nat Neurosci 9: 20-22, 2006.
136. Tanaka M. Spatiotemporal properties of eye position signals in the primate central thalamus. Cereb Cortex 17: 1504-1515, 2007.
137. Tolias AS, Moore T, Smirnakis SM, Tehovnik EJ, Siapas AG, Schiller PH. Eye movements modulate visual receptive fields of V4 neurons. Neuron 29: 757-767, 2001.
138. Treue S. Visual attention: the where, what, how and why of saliency. Curr Opin Neurobiol 13: 428-432, 2003.
139. Umeno MM, Goldberg ME. Spatial processing in the monkey frontal eye field. I Predictive visual responses. J Neurophysiol 78: 1373-1383, 1997.
140. Umeno MM, Goldberg ME. Spatial processing in the monkey frontal eye field. II. Memory responses. J Neurophysiol 86: 2344-2352, 2001.
141. Von Holst E, Mittelstaedt H. Das Reafferenzprinzip. Wechselwirkungen zwischen Zentralnervensystem und Peripherie. Naturwissenschaften 37: 464-476, 1950.
142. Walker MF, Fitzgibbon EJ, Goldberg ME. Neurons in the monkey superior colliculus predict the visual result of impending saccadic eye movements. J Neurophysiol 73: 1988-2003, 1995.
143. Wang X, Fung CA, Guan S, Wu S, Goldberg ME, Zhang M. Perisaccadic receptive field expansion in the lateral intraparietal area. Neuron 90: 400-409, 2016.
144. White RL, Snyder LH. A neural network model of flexible spatial updating. J Neurophysiol 91: 1608-1619, 2004.
145. Wilson NR, Runyan CA, Wang FL, Sur M. Division and subtraction by distinct cortical inhibitory networks in vivo. Nature 488: 343-348, 2012.
146. Wurtz RH, Sommer MA. Identifying corollary discharges for movement in the primate brain. Prog Brain Res 144: 47-60, 2004.
147. Wurtz RH, Sommer MA, Pare M, Ferraina S. Signal transformations from cerebral cortex to superior colliculus for the generation of saccades. Vision Res 41: 3399-3412, 2001.
148. Wyder MT, Massoglia DP, Stanford TR. Quantitative assessment of the timing and tuning of visual-related, saccade-related, and delay period activity in primate central thalamus. J Neurophysiol 90: 2029-2052, 2003.
149. Xing J, Andersen RA. Memory activity of LIP neurons for sequential eye movements simulated with neural networks. J Neurophysiol 84: 651-665,2000.
150. Yao T, Treue S, Krishna BS. An attention-sensitive memory trace in macaque MT following saccadic eye movements. PLoS Biol 14: e1002390, 2016.
151. Zhou H, Desimone R. Feature-based attention in the frontal eye field and area V4 during visual search. Neuron 70: 1205-1217, 2011.
152. Zirnsak M, Lappe M, Hamker FH. The spatial distribution of receptive field changes in a model of peri-saccadic perception: predictive remapping and shifts towards the saccade target. Vision Res 50: 1328-1337, 2010.
153. Zirnsak M, Steinmetz NA, Noudoost B, Xu KZ, Moore T. Visual space is compressed in prefrontal cortex before eye movements. Nature 507: 504507, 2014.