Browsing by Author "Liao, Isaac"
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Item Chemogenetic Inhibition of Ventral Tegmental Area Dopamine Neurons Does Not Affect Cue-elicited Alcohol Seeking(2023-09-23) Liao, Isaac; Remde, Paige; Richard, Jocelyn MAlcohol use disorder (AUD) is characterized by an impaired ability to control alcohol use despite negative consequences. Individuals with AUD often have significant physiological and subjective reactions to presentations of cues associated with alcohol availability. Alcohol-predictive cues evoke a conditioned motivational state that elicits alcohol-seeking behaviors, which can then drive other aspects of addiction, such as compulsive drinking and relapse. Previous rat studies found that dopamine neurons in the ventral tegmental area (VTA) play a key role in cue-elicited reward seeking (Halbout et al., 2019). A recent study showed that chemogenetic inhibition of VTA dopamine neurons reduces alcohol seeking in a Pavlovian paradigm (Valyear et al., 2020), where alcohol and cues were delivered simultaneously. However, it remains controversial to what extent the activity of VTA dopamine neurons encodes the motivational properties of alcohol-predictive cues. Here, we tested whether cue-elicited alcohol seeking is reduced when VTA dopamine neurons are chemogenetically inhibited. Fifteen TH-Cre-positive rats (females = 8, males = 7) were intermittently exposed to 15% ethanol. They underwent training to associate an auditory cue with alcohol. Cue-elicited alcohol seeking is measured by port entry probability and latency in response to cues. After training, the rats received hM4Di-DREADD or control virus infusion surgery to suppress VTA dopamine neurons bilaterally. They were then given ligand or vehicle injections and tested responses to cues under extinction and test conditions. After the tests, their brain tissues were examined for viral and cFos expressions. Overall, chemogenetic inhibition of VTA dopamine neurons has no effect on cue-elicited alcohol seeking. Such a diverging result may be driven by task differences between Pavlovian and operant conditioning. This suggests that different neural systems may underlie the conditioned motivational state evoked by a cue depending on the time of the cue’s presentation relative to reward delivery.Item Face Processing in Natural Scenes: A Posterior-to-anterior Gradient of Sensitivity to “Faceness”(2024-04-18) Liao, IsaacFaces are among the most important visual stimuli that we encounter every day. A glance at a face can often tell us their identity, sex, age, race, emotional expression, and direction of gaze (Tsao & Livingstone, 2008). Previous fMRI studies in macaques have shown that face selectivity increases from the posterior to the anterior regions of face areas (Freiwald, 2020; Weiner & Grill-Spector, 2010). However, the neural basis of face processing in humans remains unknown, particularly in a naturalistic context. Here we tested whether there is a similar posterior-to-anterior gradient of sensitivity to faces in the human brain. Ten participants viewed 1000 natural scene images under central fixation and made a judgment on their level of face perception for each image. We asked participants to judge as quickly and accurately as they can based on whether (1) there is at least one face that they can identify (if they see it again), (2) there is at least one face with some facial features (that they can see clearly), (3) there is at least one head of an animate thing, and (4) there is none of the above. The “faceness” ratings obtained were used to analyze fMRI responses of face-selective regions as provided by the Natural Scenes Dataset (NSD) (Allen et al., 2022). We found an increasing, posterior-to-anterior gradient of sensitivity to “faceness” along the face-selective regions of the lateral ventral temporal cortex. Our results suggest that (a) face-selective regions are involved in different functional components of face processing and that (b) broadly-tuned face detection begins in the anterior regions and increasingly becomes fine-tuned for face recognition in the posterior regions.Item Natural Scene Statistics for Understanding Face Perception Mechanisms(2023-04) Liao, IsaacItem Natural Scene Statistics for Understanding Face Perception Mechanisms(2023-04) Liao, IsaacThe human visual system is capable of rapidly translating an abundance of visual inputs into meaningful representations. For example, a single glance is sufficient for observers to recognize a typical natural scene with cars in the street, surrounded by houses, as a “town.” While much prior work has studied visual processing using simple artificial stimuli, little is known about how the visual system extracts information from significantly more complex natural scenes to form representations. In this study, we focus on the question of face representation and in what ways the visual system represents faces present in realistic naturalistic contexts. Here, we developed behavioral measurements of scene statistics that can be used to analyze and interpret the fMRI data provided by the large-scale 7T Natural Scenes Dataset (NSD) (Allen et al. 2022). Ten participants viewed 1000 natural scene images under central fixation and made a judgment on their level of face perception for each image. We asked participants to judge as quickly and accurately as they can based on whether (1) there is at least one face that they can identify (if they see it again), (2) there is at least one face with some facial features (that they can see clearly), (3) there is at least one head of an animate thing, and (4) there is no face present. The participants then viewed and made judgments on a selected set of 100 repeated images to measure their test-retest reliability. Their responses and reaction times were recorded. We found that participants take significantly longer times to recognize faces, identify faces, and identify animate objects as compared to identifying scenes without faces or animate objects. There is a high across-subject test-retest reliability (r = 0.85) even when the effect of the high agreement on control images between the participants is removed (r = 0.69). It is now possible to analyze and interpret fMRI data from NSD to elucidate mechanisms of face perception.