The Department of Cognitive and Psychological Sciences (CoPsy) at Brown University invites applications for a tenure-track Assistant or tenured Associate Professor beginning July 1, 2025. We anticipate hiring up to two candidates with the area open. However, candidates' research must focus on one of the following research themes: (1) the interface between artificial intelligence and cognition, (2) collective cognition and behavior, and/or (3) mechanisms of mental and brain health. In addition to building an externally funded nationally recognized research program, a successful candidate will provide effective instruction and advising to a diverse group of graduate and undergraduate students, and be willing to interact with colleagues from a wide range of disciplines and academic backgrounds. The CoPsy department is committed to creating a welcoming and supportive environment that values diversity. The department strongly encourages qualified candidates who can contribute to equity, diversity, and inclusion through their teaching, mentoring, service and research. Successful candidates are expected to have (1) a track record of excellence in research, (2) a well-specified research plan that is likely to lead to research funding, and (3) a readiness to contribute to teaching and mentoring at both the undergraduate and graduate level. The CoPsy department has a highly interdisciplinary research environment in the study of mind, brain, and behavior, offering curricular programs in Psychology, Cognitive Science, Cognitive Neuroscience, and Behavioral Decision Sciences. The Department is located in the heart of campus, and is associated with many Centers and Initiatives at the University, including the Carney Institute for Brain Science, Watson Institute for International and Public Affairs, Data Science Initiative, Center for the Study of Race and Ethnicity in America.

The regulation of body weight relies on homeostatic mechanisms that use a combination of internal signals and external cues to initiate and terminate food intake. Homeostasis depends on intricate communication between the body and the hypothalamus involving numerous neural and hormonal signals. However, there is growing evidence that higher-level cognitive function may also influence energy balance. For instance, research has shown that BMI is consistently linked to various brain, cognitive, and personality measures, implicating executive, reward, and attentional systems. Moreover, the rise in obesity rates over the past half-century is attributed to the affordability and widespread availability of highly processed foods, a phenomenon that contradicts the idea that food intake is solely regulated by homeostasis. I will suggest that prefrontal systems involved in value computation and motivation act to limit food overconsumption when food is scarce or expensive, but promote over-eating when food is abundant, an optimum strategy from an economic standpoint. I will review the genetic and neuroscience literature on the CNS control of body weight. I will present recent studies supporting a role of prefrontal systems in weight control. I will also present contradictory evidence showing that frontal executive and cognitive findings in obesity may be a consequence not a cause of increased hunger. Finally I will review the effects of obesity on brain anatomy and function. Chronic adiposity leads to cerebrovascular dysfunction, cortical thinning, and cognitive impairment. As the most common preventable risk factor for dementia, obesity poses a significant threat to brain health. I will conclude by reviewing evidence for treatment of obesity in adults to prevent brain disease.

Dr. Ryan C.N. D’Arcy is a Canadian neuroscientist, researcher, innovator and entrepreneur. Dr. D'Arcy co-founded HealthTech Connex Inc. and serves as President and Chief Scientific Officer. HealthTech Connex translates neuroscience advances into health technology breakthroughs. D'Arcy is most known for coining the term "brain vital signs" and for leading the research and development of the brain vital signs framework. Dr. D’Arcy also holds a BC Leadership Chair in Medical Technology, is a full Professor at Simon Fraser University, and a member of the DM Centre for Brain Health at the University of British Columbia. He has published more than 260 academic works, attracted more than $85 Million CAD in competitive research and innovation funding, and been recognized through numerous awards and distinctions. Please join us for an exciting virtual talk with Dr. D'Arcy who will speak on some of the current research he is involved in, how he is translating this research into real-life applications, and the development of HealthTech Connects Inc.

Every year around 100,000 people in the UK will have a stroke. Stroke is a leading cause of adult disability, and cerebrovascular disease more broadly is a major cause of dementia. Understanding these diseases – both acute and chronic manifestations of cerebrovascular disease – requires consideration not only of the brain itself, but also the blood vessels supplying it. Atherosclerosis – the hardening of arteries as we age – may predispose to stroke by triggering the formation of blood clots that block the blood supply to the brain, but also involves inflammation that may cause chronic damage to the brain and prime both the brain and body for injury. Understanding this interaction between systemic disease and brain health may have important implications for our understanding of healthy ageing and provide novel therapeutic approaches for reducing the burden of cerebrovascular disease. This talk will consider how advances in imaging may facilitate our understanding of the processes underlying atherosclerosis and how it affects the brain in stroke, as well as work currently underway to translate this understanding into improving treatments for stroke.

Environmental insults alter brain function and behaviour inboth rodents and people. One putative underlying mechanism that has receivedsubstantial attention recently is the gut microbiota, the ecosystem ofsymbiotic microorganisms that populate the intestinal tract, which is known toplay a role in brain health and function via the gut-brain axis. Two keyenvironmental insults known to affect both brain function and behaviour, andthe gut microbiome, are poor diet and psychological stress. While there isstrong evidence for interactions between the microbiome and host physiology inthe context of chronic stress, little is known about the role of the microbiomein the host response to acute stress. Determining the underlying mechanisms bywhich stress may provoke functional changes in the gut and brain is criticalfor developing therapeutics to alleviate adverse consequences of traumaticstress.

The analysis of functional magnetic resonance imaging (fMRI) data can greatly benefit from flexible analytic approaches. In particular, the advent of data-driven approaches to identify whole-brain time-varying connectivity and activity has revealed a number of interesting relevant variation in the data which, when ignored, can provide misleading information. In this lecture I will provide a comparative introduction of a range of data-driven approaches to estimating time-varying connectivity. I will also present detailed examples where studies of both brain health and disorder have been advanced by approaches designed to capture and estimate time-varying information in resting fMRI data. I will review several exemplar data sets analyzed in different ways to demonstrate the complementarity as well as trade-offs of various modeling approaches to answer questions about brain function. Finally, I will review and provide examples of strategies for validating time-varying connectivity including simulations, multimodal imaging, and comparative prediction within clinical populations, among others. As part of the interactive aspect I will provide a hands-on guide to the dynamic functional network connectivity toolbox within the GIFT software, including an online didactic analytic decision tree to introduce the various concepts and decisions that need to be made when using such tools

Exposure to proper environment during early development is essential for brain maturation. Impaired sensory input or abnormal experiences can have long-term negative consequences on brain health. We seek to define the precise synaptic aberrations caused by abnormal visual experiences early in life, and how these can be remedied through viral, genetic and environmental approaches. Resulting knowledge will contribute to the development of new approaches to mitigate nervous system damage caused by abnormal early life experience.