Having More Choices Changes How Human Observers Weight Stable Sensory Evidence

Itthipuripat, Sirawaj; Cha, Kexin; Deering, Sean; Salazar, Annalisa; Serences, John T.

doi:10.1523/jneurosci.0440-18.2018

Cited by 16 publications

(18 citation statements)

References 135 publications

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“…Attention has been shown to change the neural CRFs measured in visual cortex in many different ways (Figure 7, left panels). These include (a) contrast gain by which attention shifts the horizontal position of neural CRFs, (b) response gain by which attention scales neural activity multiplicatively, (c) baseline input increases by which attention predominantly enhances the baseline input of the neural CRFs without mediating neural responses at high contrasts, and (d) additive baseline shifts by which attention increases the magnitude of sensory signals equally across all contrast levels (Buracas & Boynton, 2007; Di Russo, Spinelli, & Morrone, 2001; Hara & Gardner, 2014; Itthipuripat et al, 2017; Itthipuripat, Cha, Deering, Salazar, & Serences, 2018; Itthipuripat, Ester, Deering, & Serences, 2014; Itthipuripat, Garcia, et al, 2014; Itthipuripat et al, 2019; Kim et al, 2007; Lee & Maunsell, 2009; Li, Lu, Tjan, Dosher, & Chu, 2008; Murray, 2008; Pestilli et al, 2011; Pooresmaeili, Poort, Thiele, & Roelfsema, 2010; Reynolds & Heeger, 2009; Reynolds, Pasternak, & Desimone, 2000; Sprague, Itthipuripat, Vo, & Serences, 2018; Sundberg, Mitchell, & Reynolds, 2009; Treue & Martinez-Trujillo, 1999; Wang & Wade, 2011; Williford & Maunsell, 2006).…”

Section: Discussionmentioning

confidence: 99%

Stimulus visibility and uncertainty mediate the influence of attention on response bias and visual contrast appearance

Itthipuripat

Chang

et al. 2019

Journal of Vision

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Although attention is known to improve the efficacy of sensory processing, the impact of attention on subjective visual appearance is still a matter of debate. Although recent studies suggest that attention can alter the appearance of stimulus contrast, others argue that these changes reflect response bias induced by attention cues. Here, we provide evidence that attention has effects on both appearance and response bias. In a comparative judgment task in which subjects reported whether the attended or unattended visual stimulus had a higher perceived contrast, attention induced substantial baseline-offset response bias as well as small but significant changes in subjective contrast appearance when subjects viewed near-threshold stimuli. However, when subjects viewed suprathreshold stimuli, baseline-offset response bias decreased and attention primarily changed contrast appearance. To address the possibility that these changes in appearance might be influenced by uncertainty due to the attended and unattended stimuli having similar physical contrasts, subjects performed an equality judgment task in which they reported if the contrast of the two stimuli was the same or different. We found that, although there were still attention-induced changes in contrast appearance at lower contrasts, the robust changes in contrast appearance at higher contrasts observed in the comparative judgment task were diminished in the equality judgment task. Together, these results suggest that attention can impact both response bias and appearance, and these two types of attention effects are differentially mediated by stimulus visibility and uncertainty. Collectively, these findings help constrain arguments about the cognitive penetrability of perception.

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Section: Discussionmentioning

confidence: 99%

Stimulus visibility and uncertainty mediate the influence of attention on response bias and visual contrast appearance

Itthipuripat

Chang

et al. 2019

Journal of Vision

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“…Although there are many variants of the Naka-Rushton equation, we decided to use this version (Eq. 6) to make contact with the large number of past studies that have also used this Naka-Rushton equation to fit contrast response functions measured using a variety of measurement techniques (e.g., psychophysics, single-unit electrophysiology, EEG, and fMRI; Martínez-Trujillio andTreue, 2002, Kim et al, 2007;Herrmann et al, 2010;Pestilli et al, 2011;Carandini and Heeger, 2011;Itthipuripat et al, 2014aItthipuripat et al, ,b, 2017Itthipuripat et al, , 2018Reynolds and Heeger, 2009). Because the G r and G c parameters control the response and contrast gain of the function where the contrast axis ranges from zero to ϱ, the G r and G c parameters could in principle exceed the realistic range of stimulus contrast (0 -100% contrast).…”

Section: Stimulusmentioning

confidence: 99%

“…Discrepancies between fMRI and EEG measures of early stimulus-evoked responses (SSVEP, P1, and LPD/P3) left us wondering whether we could find any similarity in attentional modulations measured with these two methods. We first examined the contralateral slow negative-going wave that emerged ϳ800 -2000 ms after stimulus onset (termed here as the CLN), which has been recently found to track the focus of spatial atten- tion (Itthipuripat et al, 2018;Hakim et al, 2019). The CLN component has a characteristic (e.g., temporal window, polarity, and electrode location) that resembles the contralateral delay activity, which is a marker of the active maintenance of attention during visual search and the maintenance of information in working memory (Woodman and Luck, 1999;Vogel and Machizawa, 2004;Vogel et al, 2005;Woodman et al, 2009;Carlisle et al, 2011;Kuo et al, 2012;Tsubomi et al, 2013).…”

Section: Late Slow-going Erpmentioning

confidence: 99%

“…Results from fMRI often support a mechanism whereby attention increases the evoked response to all stimuli equally, regardless of their contrast, called an "additive shift" (Buracas and Boynton, 2007;Murray, 2008; but see Li et al, 2008;Pestilli et al, 2011;Sprague et al, 2018b). In contrast, results from EEG and other electrophysiological measurements in visual cortex often support a contrast-dependent response modulation (either a horizontal shift of the CRF, called "contrast gain", or a multiplicative scaling of the CRF, called "response gain": Reynolds et al, 2000;Di Russo et al, 2001;Martínez-Trujillo and Treue, 2002; but see Williford and Maunsell, 2006;Kim et al, 2007;Lee and Maunsell, 2009;Lauritzen et al, 2010;Wang and Wade, 2011;Andersen et al, 2012;Itthipuripat et al, 2014aItthipuripat et al, ,b, 2017Itthipuripat et al, , 2018. Although these different types of attention effects could be because of differences in task designs, stimulus properties, recording sites, training duration, cognitive demand, and subjects' attentional strategy and expertise (Reynolds and Heeger, 2009;Herrmann et al, 2010;Itthipuripat et al, 2014aItthipuripat et al, , 2017Cohen, 2014, 2016;Zhang et al, 2016;Maniglia and Seitz, 2018;Ni et al, 2018), another reasonable source of divergence is the neural response properties to which each measurement is most sensitive (Boynton, 2011; Itthipuripat and Serences, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Functional MRI and EEG Index Complementary Attentional Modulations

2019

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Functional magnetic resonance imaging (fMRI) and electroencephalography (EEG) are two noninvasive methods commonly used to study neural mechanisms supporting visual attention in humans. Studies using these tools, which have complementary spatial and temporal resolutions, implicitly assume they index similar underlying neural modulations related to external stimulus and internal attentional manipulations. Accordingly, they are often used interchangeably for constraining understanding about the impact of bottom-up and top-down factors on neural modulations. To test this core assumption, we simultaneously manipulated bottom-up sensory inputs by varying stimulus contrast and top-down cognitive modulations by changing the focus of spatial attention. Each of the male and female subjects participated in both fMRI and EEG sessions performing the same experimental paradigm. We found categorically different patterns of attentional modulation on fMRI activity in early visual cortex and early stimulus-evoked potentials measured via EEG (e.g., the P1 component and steady-state visually-evoked potentials): fMRI activation scaled additively with attention, whereas evoked EEG components scaled multiplicatively with attention. However, across longer time scales, a contralateral negative-going potential and oscillatory EEG signals in the alpha band revealed additive attentional modulation patterns like those observed with fMRI. These results challenge prior assumptions that fMRI and early stimulus-evoked potentials measured with EEG can be interchangeably used to index the same neural mechanisms of attentional modulations at different spatiotemporal scales. Instead, fMRI measures of attentional modulations are more closely linked with later EEG components and alpha-band oscillations. Considered together, hemodynamic and electrophysiological signals can jointly constrain understanding of the neural mechanisms supporting cognition.

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“…First, they avoid a critical downside of binary decision tasks, which are biased by a confirmation/exclusion criterion, as the exclusion of one option inherently implies the only alternative available is the correct choice to make. Second, despite the significant increase in computational demands associated with 3-options tasks (Churchland et al, 2008; Churchland and Ditterich, 2012; Itthipuripat et al, 2018; Tajima et al, 2019), the tasks used for this study rely on a simple set of rules, easy-to-compute stochastic associations (80% for the most prevalent bead in a jar and for the most likely outcome value associated to a card) and only three types of discrete evidence (i.e. the three feedback values or the three bead colors), reducing the effect of second-order uncertainty (Fleming and Dolan, 2012; Fleming and Daw, 2017).…”

Section: Discussionmentioning

confidence: 99%

Similar network compositions, but distinct neural dynamics underlying belief updating in environments with and without explicit outcomes

Fiore¹,

Gu²

2019

Preprint

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Beliefs about action-outcomes contingencies are often updated in opaque environments where feedbacks might be inaccessible and agents might need to rely on other information for evidence accumulation. It remains unclear, however, whether and how the neural dynamics subserving confidence and uncertainty during belief updating might be context-dependent. Here, we applied a Bayesian model to estimate uncertainty and confidence in healthy humans (n=28) using two multi-option fMRI tasks, one with and one without feedbacks. We found that across both tasks, uncertainty was computed in the anterior insular, anterior cingulate, and dorsolateral prefrontal cortices, whereas confidence was encoded in anterior hippocampus, amygdala and medial prefrontal cortex. However, dynamic causal modelling (DCM) revealed a critical divergence between how effective connectivity in these networks was modulated by the available information. Specifically, there was directional influence from the anterior insula to other regions during uncertainty encoding, independent of outcome availability. Conversely, the network computing confidence was driven either by the anterior hippocampus when outcomes were not available, or by the medial prefrontal cortex and amygdala when feedbacks were immediately accessible. These findings indicate that confidence encoding might largely rely on evidence accumulation and therefore dynamically changes as a function of the available sensory information (i.e. symbolic sequences monitored by the hippocampus, and monetary feedbacks computed by amygdala and medial prefrontal cortex). In contrast, uncertainty could be triggered by any information that disputes existing beliefs (i.e. processed in the insula), independent of its content.Significance StatementOur choices are guided by our beliefs about action-outcome contingencies. In environments where only one action leads to a desired outcome, high estimated action-outcome probabilities result in confidence, whereas low probabilities distributed across multiple choices result in uncertainty. These estimations are continuously updated, sometimes based on feedbacks provided by the environment, but sometimes this update takes place in opaque environments where feedbacks are not readily available. Here, we show that uncertainty computations are driven by the anterior insula, independent of feedback availability. Conversely, confidence encoding dynamically adapts to the information available, as we found it was driven either by the anterior hippocampus, when feedback was absent, or by the medial prefrontal cortex and amygdala, otherwise.

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Having More Choices Changes How Human Observers Weight Stable Sensory Evidence

Cited by 16 publications

References 135 publications

Stimulus visibility and uncertainty mediate the influence of attention on response bias and visual contrast appearance

Stimulus visibility and uncertainty mediate the influence of attention on response bias and visual contrast appearance

Functional MRI and EEG Index Complementary Attentional Modulations

Similar network compositions, but distinct neural dynamics underlying belief updating in environments with and without explicit outcomes

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