Dual Diffusion Model for Single-Cell Recording Data From the Superior Colliculus in a Brightness-Discrimination Task

Ratcliff, Roger; Hasegawa, Yukako T.; Hasegawa, Ryohei; Smith, Philip L.; Segraves, Mark A.

doi:10.1152/jn.00393.2006

Cited by 221 publications

(263 citation statements)

References 99 publications

(136 reference statements)

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“…Similar models have also linked neural activity with RT in motion detection and attentionswitching tasks (Cook and Maunsell, 2002;). Although the model did a good job capturing the behavioral performance and mean RTs in all stimulus conditions, it did not fully capture RT distributions as well as other threshold models (Carpenter and Williams, 1995;Hanes and Schall, 1996;Carpenter, 2004;Smith and Ratcliff, 2004;Ratcliff et al, 2007). However, we do not think that adding free parameters to better account for non-decision or motor delays would have affected the functional link between the model neurons and the motion detection performance of the model.…”

Section: Discussionmentioning

confidence: 82%

The Functional Link between Area MT Neural Fluctuations and Detection of a Brief Motion Stimulus

Smith

Zhan²,

Cook³

2011

J. Neurosci.

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Fluctuations of neural firing rates in visual cortex are known to be correlated with variations in perceptual performance. It is important to know whether these fluctuations are functionally linked to perception in a causal manner or instead reflect non-causal processes that arise after the perceptual decision is made. We recorded from middle temporal (MT) neurons from monkey subjects while they detected the random occurrence of a brief 50 ms motion pulse that occurred in either of two (or simultaneously in both) random dot patches located in the same hemisphere. The receptive field parameters of the motion pulse were matched to that preferred by each MT neuron under study. This task contained uncertainty in both space and time because, on any given trial, the subjects did not know which patch would contain the motion pulse or when the motion pulse would occur. Covariations between MT activity and behavior began just before the motion pulse onset and peaked at the maximum neural response. These neural-behavioral covariations were strongest when only one patch contained the motion pulse and were still weakly present when a patch did not contain a motion pulse. A feedforward temporal integration model with two independent detector channels captured both the detection performance and evolution of the neuralbehavior covariations over time and stimulus condition. The results suggest that, when detecting a brief visual stimulus, there is a causal relationship between fluctuations in neural activity and variations in behavior across trials.

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Section: Discussionmentioning

confidence: 82%

The Functional Link between Area MT Neural Fluctuations and Detection of a Brief Motion Stimulus

Smith

Zhan²,

Cook³

2011

J. Neurosci.

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“…It might appear that a diffusion model (Stone, 1960;Laming, 1968;Ratcliff, 1978;Smith and Ratcliff, 2004;Ratcliff et al, 2007) will predict the same timing in bias-for and bias-against trials because it accumulates the difference in sensory evidence for the two options. However, note that, in bias-for trials, there is no moment in time at which evidence favors the wrong target (i.e., the success probability function never falls below 0.5), and so the difference in evidence is always positive (favoring the correct choice).…”

Section: Control Analyses and Simulationsmentioning

confidence: 99%

“…In particular, assuming that the rate of integration is subject to variability, these models can explain error rates and distributions of reaction times (RTs) in a wide variety of tasks (Ratcliff, 1978;Carpenter and Williams, 1995;Reddi and Carpenter, 2000;Reddi et al, 2003;Smith and Ratcliff, 2004). Furthermore, recent neurophysiological data on decision tasks have provided evidence for accumulation processes in the superior colliculus (Munoz and Wurtz, 1995;Munoz et al, 2000;Ratcliff et al, 2003Ratcliff et al, , 2007Shen and Paré, 2007), the lateral intraparietal area (LIP) (Roitman and Shadlen, 2002;Leon and Shadlen, 2003), the frontal eye fields Shadlen, 2000, 2003), and the prefrontal cortex (Kim and Shadlen, 1999). Finally, integration of samples toward a bound is reminiscent of the "sequential probability ratio test" (SPRT) (Wald, 1945;Bogacz et al, 2006), an optimal procedure for making decisions on the basis of information that arrives over time (Wald and Wolfowitz, 1948).…”

Section: Introductionmentioning

confidence: 99%

Decisions in Changing Conditions: The Urgency-Gating Model

Cisek¹,

Puskas²,

El-Murr³

2009

J. Neurosci.

466

714

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Several widely accepted models of decision making suggest that, during simple decision tasks, neural activity builds up until a threshold is reached and a decision is made. These models explain error rates and reaction time distributions in a variety of tasks and are supported by neurophysiological studies showing that neural activity in several cortical and subcortical regions gradually builds up at a rate related to task difficulty and reaches a relatively constant level of discharge at a time that predicts movement initiation. The mechanism responsible for this buildup is believed to be related to the temporal integration of sequential samples of sensory information. However, an alternative mechanism that may explain the neural and behavioral data is one in which the buildup of activity is instead attributable to a growing signal related to the urgency to respond, which multiplicatively modulates updated estimates of sensory evidence. These models are difficult to distinguish when, as in previous studies, subjects are presented with constant sensory evidence throughout each trial. To distinguish the models, we presented human subjects with a task in which evidence changed over the course of each trial. Our results are more consistent with "urgency gating" than with temporal integration of sensory samples and suggest a simple mechanism for implementing trade-offs between the speed and accuracy of decisions.

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“…With this theoretical framework as a strong guide, signals exhibiting buildto-threshold dynamics have been found in several areas of the monkey brain, including parietal (e.g. Roitman and Shadlen, 2002;Hanks et al, 2006), frontal (Hanes and Schall, 1996;Kim and Shadlen, 1999) and subcortical (Ratcliff et al, 2007;Ding and Gold, 2010) oculomotor areas. This work has paved the way for a broad program of mechanistically principled research into how neural decision signals are constructed and are adapted to account for changing environmental contingencies (e.g.…”

Section: Introductionmentioning

confidence: 99%

The neural processes underlying perceptual decision making in humans: Recent progress and future directions

Kelly

O’Connell

2015

Journal of Physiology-Paris

112

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a b s t r a c tIn the last two decades, animal neurophysiology research has made great strides towards explaining how the brain can enable adaptive action in the face of noisy sensory information. In particular, this work has identified neural signals that perform the role of a 'decision variable' which integrates sensory information in favor of a particular outcome up to an action-triggering threshold, consistent with long-standing predictions from mathematical psychology. This has provoked an intensive search for similar neural processes at work in the human brain. In this paper we review the progress that has been made in tracing the dynamics of perceptual decision formation in humans using functional imaging and electrophysiology. We highlight some of the limitations that non-invasive recording techniques place on our ability to make definitive judgments regarding the role that specific signals play in decision making. Finally, we provide an overview of our own work in this area which has focussed on two perceptual tasks -intensity change detection and motion discrimination -performed under continuous-monitoring conditions, and highlight the insights gained thus far. We show that through simple paradigm design features such as avoiding sudden intensity transients at evidence onset, a neural instantiation of the theoretical decision variable can be directly traced in the form of a centro-parietal positivity (CPP) in the standard eventrelated potential (ERP). We recapitulate evidence for the domain-general nature of the CPP process, being divorced from the sensory and motor requirements of the task, and re-plot data of both tasks highlighting this aspect as well as its relationship to decision outcome and reaction time. We discuss the implications of these findings for mechanistically principled research on normal and abnormal decision making in humans.

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Dual Diffusion Model for Single-Cell Recording Data From the Superior Colliculus in a Brightness-Discrimination Task

Cited by 221 publications

References 99 publications

The Functional Link between Area MT Neural Fluctuations and Detection of a Brief Motion Stimulus

The Functional Link between Area MT Neural Fluctuations and Detection of a Brief Motion Stimulus

Decisions in Changing Conditions: The Urgency-Gating Model

The neural processes underlying perceptual decision making in humans: Recent progress and future directions

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