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MN Shadlen, K. Britten, W. Newsome, J. Movshon (1996)
A computational analysis of the relationship between neuronal and behavioral responses to visual motion, 16
M. Sommer, Robert Wurtz (2000)
Composition and topographic organization of signals sent from the frontal eye field to the superior colliculus.Journal of neurophysiology, 83 4
R. Fisher (1936)
THE USE OF MULTIPLE MEASUREMENTS IN TAXONOMIC PROBLEMSAnnals of Human Genetics, 7
R. Ratcliff (2006)
Modeling response signal and response time dataCognitive Psychology, 53
J. Schall, V. Stuphorn, Joshua Brown (2002)
Monitoring and Control of Action by the Frontal LobesNeuron, 36
Aditya Murthy, K. Thompson, J. Schall (2001)
Dynamic dissociation of visual selection from saccade programming in frontal eye field.Journal of neurophysiology, 86 5
R. Bogacz, E. Brown, J. Moehlis, P. Holmes, J. Cohen (2006)
The physics of optimal decision making: a formal analysis of models of performance in two-alternative forced-choice tasks.Psychological review, 113 4
J. Townsend (1976)
Serial and within-stage independent parallel model equivalence on the minimum completion time ☆Journal of Mathematical Psychology, 14
R. Sayer, M. Friedlander, S. Redman (1990)
The time course and amplitude of EPSPs evoked at synapses between pairs of CA3/CA1 neurons in the hippocampal slice, 10
A. Murthy, Supriya Ray, S. Shorter, Elizabeth Priddy, J. Schall, K. Thompson (2007)
Frontal eye field contributions to rapid corrective saccades.Journal of neurophysiology, 97 2
E. Clayton, J. Rajkowski, J. Cohen, G. Aston-Jones (2004)
Phasic Activation of Monkey Locus Ceruleus Neurons by Simple Decisions in a Forced-Choice TaskThe Journal of Neuroscience, 24
M. Paré, D. Hanes (2003)
Controlled Movement Processing: Superior Colliculus Activity Associated with Countermanded SaccadesThe Journal of Neuroscience, 23
T. Carr, D. Dagenbach (1994)
Inhibitory Processes in Attention, Memory and Language
A. A., J., Marley, McGill (1992)
The “horse race” random utility model for choice probabilities and reaction times, and its competing risks interpretationJournal of Mathematical Psychology, 36
M. Schlag-Rey, J. Schlag, P. Dassonville (1992)
How the frontal eye field can impose a saccade goal on superior colliculus neurons.Journal of neurophysiology, 67 4
DP Munoz, RH Wurtz (1995)
Saccade-related activity in monkey superior colliculus. I. Characteristics of burst and buildup cellsJ Neurophysiol, 73
V. Stuphorn, J. Schall (2006)
Executive control of countermanding saccades by the supplementary eye fieldNature Neuroscience, 9
R. Ratcliff, T. Zandt, G. McKoon (1995)
Process dissociation, single-process theories, and recognition memory.Journal of experimental psychology. General, 124 4
D. Hanes, W. Patterson, J. Schall (1998)
Role of frontal eye fields in countermanding saccades: visual, movement, and fixation activity.Journal of neurophysiology, 79 2
Takashi Sato, A. Murthy, K. Thompson, J. Schall (2001)
Search Efficiency but Not Response Interference Affects Visual Selection in Frontal Eye FieldNeuron, 30
A. Rockel, R. Hiorns, T. Powell (1980)
The basic uniformity in structure of the neocortex.Brain : a journal of neurology, 103 2
RA Fisher (1936)
The use of multiple measurements in taxonomic problemsAnn Eugen, 7
R. Luna, Adrián Hernández, C. Brody, R. Romo (2005)
Neural codes for perceptual discrimination in primary somatosensory cortexNature Neuroscience, 8
R. Andersen, C. Buneo (2002)
Intentional maps in posterior parietal cortex.Annual review of neuroscience, 25
D. Munoz, Robert Wurtz (1995)
Saccade-related activity in monkey superior colliculus. I. Characteristics of burst and buildup cells.Journal of neurophysiology, 73 6
Robert McPeek, E. Keller (2002)
Superior colliculus activity related to concurrent processing of saccade goals in a visual search task.Journal of neurophysiology, 87 4
R. Krauzlis, N. Dill (2002)
Neural Correlates of Target Choice for Pursuit and Saccades in the Primate Superior ColliculusNeuron, 35
R Ratcliff, T Zandt, G McKoon (1995)
Process dissociation, single-process theories, and recognition memoryJ Exp Psychol Gen, 124
Prof. Braitenberg, Priv. Schüz (1991)
Anatomy of the Cortex
CA Scudder, CR Kaneko, AF Fuchs (2002)
The brainstem burst generator for saccadic eye movements: a modern synthesisExp Brain Res, 142
C. Colby, M. Goldberg (1999)
Space and attention in parietal cortex.Annual review of neuroscience, 22
C. Scudder, C. Kaneko, A. Fuchs (2002)
The brainstem burst generator for saccadic eye movementsExperimental Brain Research, 142
V Braitenberg, A Schüz (1991)
Anatomy of the cortex: statistics and geometry
S. Herculano‐Houzel, C. Collins, P. Wong, J. Kaas (2007)
Cellular scaling rules for primate brainsProceedings of the National Academy of Sciences, 104
R. Ratcliff, Anil Cherian, M. Segraves (2003)
A comparison of macaque behavior and superior colliculus neuronal activity to predictions from models of two-choice decisions.Journal of neurophysiology, 90 3
J. Viemari, J. Ramirez (2006)
Norepinephrine differentially modulates different types of respiratory pacemaker and nonpacemaker neurons.Journal of neurophysiology, 95 4
D. Hanes, J. Schall (1995)
Countermanding saccades in macaqueVisual Neuroscience, 12
D. Tolhurst, J. Movshon, A. Dean (1983)
The statistical reliability of signals in single neurons in cat and monkey visual cortexVision Research, 23
GD Logan, WB Cowan (1984)
On the ability to inhibit thought and action: a theory of an act of controlPsychol Rev, 91
K. Britten, MN Shadlen, W. Newsome, J. Movshon (1992)
The analysis of visual motion: a comparison of neuronal and psychophysical performance, 12
GF Woodman, MS Kang, K Thompson, JD Schall (2008)
The effect of visual search efficiency on response preparation: neurophysiological evidence for discrete flowPsychol Sci, 19
Clay Holroyd, N. Yeung, M. Coles, J. Cohen (2005)
A mechanism for error detection in speeded response time tasks.Journal of experimental psychology. General, 134 2
S. Sternberg (2001)
Separate modifiability, mental modules, and the use of pure and composite measures to reveal them.Acta psychologica, 106 1-2
M. Usher, James McClelland (2001)
The time course of perceptual choice: the leaky, competing accumulator model.Psychological review, 108 3
Philip Smith, R. Ratcliff (2004)
Psychology and neurobiology of simple decisionsTrends in Neurosciences, 27
R. Ratcliff, Philip Smith (2004)
A comparison of sequential sampling models for two-choice reaction time.Psychological review, 111 2
J. Roitman, M. Shadlen (2002)
Response of Neurons in the Lateral Intraparietal Area during a Combined Visual Discrimination Reaction Time TaskThe Journal of Neuroscience, 22
M. Sommer, R. Wurtz (2004)
What the brain stem tells the frontal cortex. I. Oculomotor signals sent from superior colliculus to frontal eye field via mediodorsal thalamus.Journal of neurophysiology, 91 3
N. Bichot, K. Thompson, S. Rao, J. Schall (2001)
Reliability of Macaque Frontal Eye Field Neurons Signaling Saccade Targets during Visual SearchThe Journal of Neuroscience, 21
G. Aston-Jones, J. Cohen (2005)
An integrative theory of locus coeruleus-norepinephrine function: adaptive gain and optimal performance.Annual review of neuroscience, 28
K. Thompson, D. Hanes, N. Bichot, J. Schall (1996)
Perceptual and motor processing stages identified in the activity of macaque frontal eye field neurons during visual search.Journal of neurophysiology, 76 6
E. Cook, J. Maunsell (2002)
Dynamics of neuronal responses in macaque MT and VIP during motion detectionNature Neuroscience, 5
Duncan Luce (1986)
Response Times: Their Role in Inferring Elementary Mental Organization
G. Logan (1984)
On the ability to inhibit thought and action
G. Woodman, Min-Suk Kang, K. Thompson, J. Schall (2008)
The Effect of Visual Search Efficiency on Response PreparationPsychological Science, 19
E. Dzhafarov (1993)
Grice-representability of response time distribution familiesPsychometrika, 58
(2008)
Exp Brain Res
AA Marley, H Colonius (1992)
The “horse race” random utility model for choice probabilities and reaction times, and its competing risks interpretationJ Math Psychol, 36
J. Schall (2003)
Neural correlates of decision processes: neural and mental chronometryCurrent Opinion in Neurobiology, 13
(2001)
Reliability of macaque FEF but not SEF movement neurons predicting saccade initiation
O. Hikosaka, Y. Takikawa, R. Kawagoe (2000)
Role of the basal ganglia in the control of purposive saccadic eye movements.Physiological reviews, 80 3
D. Hanes, J. Schall (1996)
Neural Control of Voluntary Movement InitiationScience, 274
The countermanding (or stop signal) task probes the control of the initiation of a movement by measuring subjects’ ability to withhold a movement in various degrees of preparation in response to an infrequent stop signal. Previous research found that saccades are initiated when the activity of movement-related neurons reaches a threshold, and saccades are withheld if the growth of activity is interrupted. To extend and evaluate this relationship of frontal eye field (FEF) activity to saccade initiation, two new analyses were performed. First, we fit a neurometric function that describes the proportion of trials with a stop signal in which neural activity exceeded a criterion discharge rate as a function of stop signal delay, to the inhibition function that describes the probability of producing a saccade as a function of stop signal delay. The activity of movement-related but not visual neurons provided the best correspondence between neurometric and inhibition functions. Second, we determined the criterion discharge rate that optimally discriminated between the distributions of discharge rates measured on trials when saccades were produced or withheld. Differential activity of movement-related but not visual neurons could distinguish whether a saccade occurred. The threshold discharge rates determined for individual neurons through these two methods agreed. To investigate how reliably movement-related activity predicted movement initiation; the analyses were carried out with samples of activity from increasing numbers of trials from the same or from different neurons. The reliability of both measures of initiation threshold improved with number of trials and neurons to an asymptote of between 10 and 20 movement-related neurons. Combining the activity of visual neurons did not improve the reliability of predicting saccade initiation. These results demonstrate how the activity of a population of movement-related but not visual neurons in the FEF contributes to the control of saccade initiation. The results also validate these analytical procedures for identifying signals that control saccade initiation in other brain structures.
Experimental Brain Research – Springer Journals
Published: Sep 1, 2008
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