Prior expectations evoke stimulus-specific activity in the deep layers of the primary visual cortex

Aitken, Fraser; Menelaou, Georgios; Warrington, Oliver; Koolschijn, Renée S.; Corbin, Nadège; Callaghan, Martina F.; Kok, Peter

doi:10.1371/journal.pbio.3001023

Cited by 61 publications

(65 citation statements)

References 93 publications

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“…Importantly, for the first time we resolved the depth-profile of such sequence-level information. In accordance with predictive coding and the notion that predictive top-down information should be strongest in deeper layers (Kok et al 2016; de Lange et al 2018; Aitken et al 2020), we found the significant difference with ISC intact > ISC scrambled to be observed in the deeper half of PFt, peaking at a depth that aligns with layer V in postmortem histological examinations of the brains of other individual(Caspers et al 2006). In line with anatomical tracing studies in monkeys, suggesting that feedback connections from BA44 to PFt should terminate in layer III in addition to layers V/VI, this increased ISC was significant also at depth compatible with the location of layer III.…”

Section: Discussionsupporting

confidence: 86%

“…Because this increased ISFC is calculated across different subjects, it indicates that it is signal relating to the intactness of the sequence in the stimuli that synchronizes across BA44 and PFt (Simony et al 2016; Nastase et al 2019). The depth of this channel of increased ISFC dovetails remarkably well with recent observations that predictive processes in other domains of visual processing are accompanied by an increased recruitment of the deeper layers of the cortical visual system (Kok et al 2016; de Lange et al 2018; Aitken et al 2020), and with anatomical consideration that the dominant origin of feedback originates from deep layers in higher cortical region(Shipp 2007).…”

Section: Discussionsupporting

confidence: 84%

“…After we found evidence for differential ISC values for Intact and Scrambled movies at different cortical depth within PFt, we probed the interaction between PFt and either BA44 or latOCC in the two conditions. We hypothesized that during the observation of Intact movies, brain activity would be more enhanced in the feed-back stream from BA44 to PFt, terminating at depth aligning with layers V/VI and III (Gerbella et al 2011), with the deep-layers particularly associated with predictive brain activity (Shipp 2007; Kok et al 2016; de Lange et al 2018; Aitken et al 2020). In contrast, for the information transfer across latOCC and PFt, because the latOCC appears to represent information at the short temporal scale of acts, too fast for the the Nyquist limit of our acquisition, we do not expect measurable changes in ISFC.…”

Section: Resultsmentioning

confidence: 99%

“…Pioneering studies in the early visual cortex have shown that acquiring fMRI at submillimeter resolution at high-field strength (≥7T) can indeed test predictive coding hypotheses (Kok et al 2016; Lawrence et al 2018, 2019a, b; Finn et al 2020; Aitken et al 2020). Recent work in particular confirms that activations in deep layers is indeed measurable when feedback predictions about upcoming sensory events are likely to occur in the visual system (Kok et al 2016; de Lange et al 2018; Aitken et al 2020), while activation in superficial layers seem to be measured when there is a mismatch between predicted and observed input and attentional signals (de Lange et al 2018). Unfortunately, experiments testing whether deep layers carry signals that could be related to predictions have so far been restricted to early visual cortices and we do not know whether the same might be observed in parietal and premotor regions (Finn et al 2020).…”

Section: Introductionmentioning

confidence: 99%

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Predictive coding during action observation - a depth-resolved intersubject functional correlation study at 7T

Cerliani

Bhandari

Angelis

et al. 2021

Preprint

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While the brain regions involved in action observation are relatively well documented in humans and primates, how these regions communicate to help understand and predict actions remains poorly understood. Traditional views emphasized a feed-forward architecture in which visual features are organized into increasingly complex representations that feed onto motor programs in parietal and then premotor cortices where the matching of observed actions upon the observer's own motor programs contributes to action understanding. Predictive coding models place less emphasis on feed-forward connections and propose that feed-back connections from premotor regions back to parietal and visual neurons represent predictions about upcoming actions that can supersede visual inputs when actions become predictable, with visual input then merely representing prediction errors. Here we leverage the notion that feed-back connections target deeper cortical layers than feed-forward connections to help adjudicate across these views. Specifically, we test whether observing sequences of hand actions in their natural order, which permits participants to predict upcoming actions, triggers more feed-back input to parietal regions than seeing the same actions in a scrambled sequence that hinders making predictions. Using submillimeter fMRI acquisition at 7T, we find that watching predictable sequences triggers more action-related activity (as measured using intersubject functional correlation) in deep layers of the parietal cortical area PFt than watching the exact same actions in scrambled and hence unpredictable sequence. In addition, functional connectivity analysis performed using intersubject functional connectivity confirms that this deep, action-related signals in PFt could originate from ventral premotor region BA44. This data showcases the utility of intersubject functional correlation in combination with 7T MRI to explore the architecture of social cognition under more naturalistic conditions, and provides evidence for models that emphasize the importance of feed-back connections in action prediction.

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Section: Discussionsupporting

confidence: 86%

Section: Discussionsupporting

confidence: 84%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Predictive coding during action observation - a depth-resolved intersubject functional correlation study at 7T

Cerliani

Bhandari

Angelis

et al. 2021

Preprint

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“…The behavioural signature of statistical distractor-location learning has been well documented recently: RT interference is reduced for distractors occurring at frequent versus rare locations, and this is associated with reduced capture of the first saccade by distractors at frequent locations (Di Caro et al 2019;Wang et al 2019a;Sauter et al 2020). Together with an ERP component interpreted in terms of distractor suppression (Wang et al 2019b), this has been taken as evidence that observers learn to down-modulate the attentional priority signals (Itti and Koch 2001;Fecteau and Munoz 2006;Wolfe and Gray 2007;Kok et al 2012;Aitken et al 2020) generated by distractors at frequent locations, thus reducing their potential to capture attention and cause interference. In line with this, we found that early visual-cortex signalling was reduced for distractors occurring in the frequent versus rare region.…”

Section: Discussionmentioning

confidence: 88%

Statistical learning of frequent distractor locations in visual search involves regional signal suppression in early visual cortex

Zhang

Weidner

Allenmark

et al. 2021

Preprint

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Observers can learn the locations where salient distractors appear frequently to reduce potential interference - an effect attributed to better suppression of distractors at frequent locations. But how distractor suppression is implemented in the visual cortex and frontoparietal attention networks remains unclear. We used fMRI and a regional distractor-location learning paradigm (Sauter et al. 2018, 2020) with two types of distractors defined in either the same (orientation) or a different (colour) dimension to the target to investigate this issue. fMRI results showed that BOLD signals in early visual cortex were significantly reduced for distractors (as well as targets) occurring at the frequent versus rare locations, mirroring behavioural patterns. This reduction was more robust with same-dimension distractors. Crucially, behavioural interference was correlated with distractor-evoked visual activity only for same- (but not different-) dimension distractors. Moreover, with different- (but not same-) dimension distractors, a colour-processing area within the fusiform gyrus was activated more when a colour distractor was present versus absent and with a distractor occurring at a rare versus frequent location. These results support statistical learning of frequent distractor locations involving regional suppression in the early visual cortex and point to differential neural mechanisms of distractor handling with different- versus same-dimension distractors.

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Modelling the depth‐dependent VASO and BOLD responses in human primary visual cortex

Akbari

Bollmann

Ali

et al. 2022

Human Brain Mapping

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Functional magnetic resonance imaging (fMRI) using a blood‐oxygenation‐level‐dependent (BOLD) contrast is a common method for studying human brain function noninvasively. Gradient‐echo (GRE) BOLD is highly sensitive to the blood oxygenation change in blood vessels; however, the spatial signal specificity can be degraded due to signal leakage from activated lower layers to superficial layers in depth‐dependent (also called laminar or layer‐specific) fMRI. Alternatively, physiological variables such as cerebral blood volume using the VAscular‐Space‐Occupancy (VASO) contrast have shown higher spatial specificity compared to BOLD. To better understand the physiological mechanisms such as blood volume and oxygenation changes and to interpret the measured depth‐dependent responses, models are needed which reflect vascular properties at this scale. For this purpose, we extended and modified the “cortical vascular model” previously developed to predict layer‐specific BOLD signal changes in human primary visual cortex to also predict a layer‐specific VASO response. To evaluate the model, we compared the predictions with experimental results of simultaneous VASO and BOLD measurements in a group of healthy participants. Fitting the model to our experimental data provided an estimate of CBV change in different vascular compartments upon neural activity. We found that stimulus‐evoked CBV change mainly occurs in small arterioles, capillaries, and intracortical arteries and that the contribution from venules and ICVs is smaller. Our results confirm that VASO is less susceptible to large vessel effects compared to BOLD, as blood volume changes in intracortical arteries did not substantially affect the resulting depth‐dependent VASO profiles, whereas depth‐dependent BOLD profiles showed a bias towards signal contributions from intracortical veins.

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Prior expectations evoke stimulus-specific activity in the deep layers of the primary visual cortex

Cited by 61 publications

References 93 publications

Predictive coding during action observation - a depth-resolved intersubject functional correlation study at 7T

Predictive coding during action observation - a depth-resolved intersubject functional correlation study at 7T

Statistical learning of frequent distractor locations in visual search involves regional signal suppression in early visual cortex

Modelling the depth‐dependent VASO and BOLD responses in human primary visual cortex

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