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1. Dissociable Roles of the Dorsolateral and Ventromedial Prefrontal Cortex in Human Categorization

   https://doi.org/10.1523/JNEUROSCI.2343-23.2024  

   Broschard, Matthew_B; Turner, Brandon_M; Tranel, Daniel; Freeman, John_H (July 2024, The Journal of Neuroscience)

   Models of human categorization predict the prefrontal cortex (PFC) serves a central role in category learning. The dorsolateral prefrontal cortex (dlPFC) and ventromedial prefrontal cortex (vmPFC) have been implicated in categorization; however, it is unclear whether both are critical for categorization and whether they support unique functions. We administered three categorization tasks to patients with PFC lesions (mean age, 69.6 years; 5 men, 5 women) to examine how the prefrontal subregions contribute to categorization. These included a rule-based (RB) task that was solved via a unidimensional rule, an information integration (II) task that was solved by combining information from two stimulus dimensions, and a deterministic/probabilistic (DP) task with stimulus features that had varying amounts of category-predictive information. Compared with healthy comparison participants, both patient groups had impaired performance. Impairments in the dlPFC patients were largest during the RB task, whereas impairments in the vmPFC patients were largest during the DP task. A hierarchical model was fit to the participants’ data to assess learning deficits in the patient groups. PFC damage was correlated with a regularization term that limited updates to attention after each trial. Our results suggest that the PFC, as a whole, is important for learning to orient attention to relevant stimulus information. The dlPFC may be especially important for rule-based learning, whereas the vmPFC may be important for focusing attention on deterministic (highly diagnostic) features and ignoring less predictive features. These results support overarching functions of the dlPFC in executive functioning and the vmPFC in value-based decision-making. 

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2. Thalamo-Prefrontal Connectivity Correlates With Early Command-Following After Severe Traumatic Brain Injury

   https://doi.org/10.3389/fneur.2022.826266  

   Cosgrove, Megan E.; Saadon, Jordan R.; Mikell, Charles B.; Stefancin, Patricia L.; Alkadaa, Leor; Wang, Zhe; Saluja, Sabir; Servider, John; Razzaq, Bayan; Huang, Chuan; et al (February 2022, Frontiers in Neurology)

   Recovery of consciousness after traumatic brain injury (TBI) is heterogeneous and difficult to predict. Structures such as the thalamus and prefrontal cortex are thought to be important in facilitating consciousness. We sought to investigate whether the integrity of thalamo-prefrontal circuits, assessed via diffusion tensor imaging (DTI), was associated with the return of goal-directed behavior after severe TBI. We classified a cohort of severe TBI patients ( N = 25, 20 males) into Early and Late/Never outcome groups based on their ability to follow commands within 30 days post-injury. We assessed connectivity between whole thalamus, and mediodorsal thalamus (MD), to prefrontal cortex (PFC) subregions including dorsolateral PFC (dlPFC), medial PFC (mPFC), anterior cingulate (ACC), and orbitofrontal (OFC) cortices. We found that the integrity of thalamic projections to PFC subregions (L OFC, L and R ACC, and R mPFC) was significantly associated with Early command-following. This association persisted when the analysis was restricted to prefrontal-mediodorsal (MD) thalamus connectivity. In contrast, dlPFC connectivity to thalamus was not significantly associated with command-following. Using the integrity of thalamo-prefrontal connections, we created a linear regression model that demonstrated 72% accuracy in predicting command-following after a leave-one-out analysis. Together, these data support a role for thalamo-prefrontal connectivity in the return of goal-directed behavior following TBI. 

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3. Evidence for thalamic regulation of frontal interactions in human cognitive flexibility

   Hummos, Ali; Wang, Bin; Drammis, Sabrina; Halassa, Michael M.; Pleger, Burkhard (January 2022, PLOS computational biology)

   Interactions across frontal cortex are critical for cognition. Animal studies suggest a role for mediodorsal thalamus (MD) in these interactions, but the computations performed and direct relevance to human decision making are unclear. Here, inspired by animal work, we extended a neural model of an executive frontal-MD network and trained it on a human decision-making task for which neuroimaging data were collected. Using a biologically-plausible learning rule, we found that the model MD thalamus compressed its cortical inputs (dorsolateral prefrontal cortex, dlPFC) underlying stimulus-response representations. Through direct feedback to dlPFC, this thalamic operation efficiently partitioned cortical activity patterns and enhanced task switching across different contingencies. To account for interactions with other frontal regions, we expanded the model to compute higher-order strategy signals outside dlPFC, and found that the MD offered a more efficient route for such signals to switch dlPFC activity patterns. Human fMRI data provided evidence that the MD engaged in feedback to dlPFC, and had a role in routing orbitofrontal cortex inputs when subjects switched behavioral strategy. Collectively, our findings contribute to the emerging evidence for thalamic regulation of frontal interactions in the human brain. 

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4. Computational Insights into Schizophrenia: Linking Hyperactive D2 Receptors with Belief Updating Impairments

   Wang, Mien Brabeeba; Lynch, Nancy; Halassa, Michael (June 2024, 10th Workshop on Biological Distributed Algorithms (BDA))

   Genetics are recognized as a significant risk factor in schizophrenia [1], and computational modeling studies have highlighted deficits in belief updating as a key aspect of the disorder and an underlying cause of delusion [2]. In particular, the patients often show strong priors on envi- ronmental volatility. However, the intricate mechanisms bridging these genetic risk factors and belief updating deficits remain poorly understood. Our challenge here was to build a biologically plausible neural network that provides a link between genetic risk factors and impaired belief updating. In constructing our schizophrenia model, we first focused on the prefrontal cortex (PFC)- mediodorsal thalamus (MD) circuit, given mounting evidence implicating alterations in these regions in schizophrenia pathology [3]. Drawing from experimental findings demonstrating the involvement of MD neurons expressing D2 receptors in cognitive flexibility [4], the known asso- ciation of D2 receptor genes with heightened schizophrenia risk [5], and the predominant mode of action of antipsychotic treatments as dopamine antagonists at D2 receptors [6], we simulated schizophrenia by reducing the excitability of MD neurons to mimic the hyperactive D2 receptors in Schizophrenia. To investigate the belief updating process, we consider a probability reversal task, in which the reward structure switches in blocks for every 200 trials. Our normal thalamocortical model is capable of flexibly switching across blocks and its PFC-MD connections learn the contextual model of the world, a neural signature for continual learning. We further mathematically analyze the model and deduce that under mild assumptions, the model approximates CUSUM algorithm, an algorithm known for its optimality in detecting environmental changes [7]. On the other hand, our schizophrenia model exhibited a stronger bias towards environmental volatility, prompting exploratory behaviors following contextual switches. By mathematical analysis, we deduce that the decreased excitability makes the evidence accumulation dynamics leaky and therefore the model can sporadically switch, consistent with the qualitative results in Schizophrenia patients [2]. Additionally, decreased excitability in MD compromised the ability of PFC-MD connections to accurately learn the environmental model. To address this impairment, we applied current injections to MD to restore activity levels to a range conducive to Hebbian plasticity. Remarkably, the rescue model demonstrated reduced exploratory behavior following switches and exhibited a higher threshold for MD activity switching, indicative of a diminished bias towards environmental volatility. Moreover, the rescue model exhibited improved learning of the environmental model within its PFC-MD connections. These findings suggest a potential mechanism for utilizing deep brain stimulation at a novel site to mitigate schizophrenia symptoms. 

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5. Neuromodulation of prefrontal cortex cognitive function in primates: the powerful roles of monoamines and acetylcholine

   https://doi.org/10.1038/s41386-021-01100-8  

   Cools, Roshan; Arnsten, Amy F. (January 2022, Neuropsychopharmacology)

   Abstract The primate prefrontal cortex (PFC) subserves our highest order cognitive operations, and yet is tremendously dependent on a precise neurochemical environment for proper functioning. Depletion of noradrenaline and dopamine, or of acetylcholine from the dorsolateral PFC (dlPFC), is as devastating as removing the cortex itself, and serotonergic influences are also critical to proper functioning of the orbital and medial PFC. Most neuromodulators have a narrow inverted U dose response, which coordinates arousal state with cognitive state, and contributes to cognitive deficits with fatigue or uncontrollable stress. Studies in monkeys have revealed the molecular signaling mechanisms that govern the generation and modulation of mental representations by the dlPFC, allowing dynamic regulation of network strength, a process that requires tight regulation to prevent toxic actions, e.g., as occurs with advanced age. Brain imaging studies in humans have observed drug and genotype influences on a range of cognitive tasks and on PFC circuit functional connectivity, e.g., showing that catecholamines stabilize representations in a baseline-dependent manner. Research in monkeys has already led to new treatments for cognitive disorders in humans, encouraging future research in this important field. 

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