Nervous system

Feeding and anxiety are two conserved behaviors critical to survival and health in all mammals. These two behaviors are interacting with each other in health and disease. Patients with abnormal feeding behaviors during eating disorders or obesity are usually associated with anxiety and depression. These two behaviors are controlled by distinct neural circuits distributed across multiple brain regions. However, whether the neural circuits underlying these two behaviors have overlap or interactions is still unknown. The lab of Dr. Haijiang Cai studies the neural circuits of animal behaviors, with a focus on understanding how the neural circuits regulate feeding and emotional behaviors. The recent work from his lab identified a specific population of neurons in the amygdala, a brain region well known for emotion control, also plays important roles in appetite control. His lab is using state-of-the-art optogenetics, chemogenetics, electrophysiology and in vivo microendoscope calcium imaging to dissect the neural circuits. This research will help understand how feeding and anxiety interact with each other, and provide new insight in developing drugs to treat eating and emotional disorders with fewer side effect. Keywords: Neural circuits, Behavior, Feeding, Anxiety

My work investigates the molecular mechanisms of axon degeneration, a molecular program triggered by toxic, metabolic, or traumatic stress to the axonal compartment of neurons. I use both fruit fly and mouse tools to ask questions about genes involved in axon degeneration and to place these genes in the context of pathways required for axon and synapse maintenance in the face of insults. I have discovered a number of axon degeneration mediators, including MORN4 and TMEM184b as well as others, and am currently following up on their roles within neurons during normal neuronal functioning and in the context of neurodegenerative disorders such as ALS and Alzheimer’s Disease. Keywords: Neurodegeneration, Neurogenetics, Behavior

Dr. Allen’s research spans several areas, but the main focus is the etiology and treatment of mood and anxiety disorders. His work focuses on identifying risk factors for depression using electroencephalographic and autonomic psychophysiological measures, especially EEG asymmetry, resting state fMRI connectivity, and cardiac vagal control. Based on these findings, he is developing novel and neurally-informed treatments for mood and anxiety disorders, including Transcranial Ultrasound, EEG biofeedback, and Transcranial Direct Current and Transcranial Alternating Current stimulation. Other work includes understanding how emotion and emotional disorders influence the way we make decisions and monitor our actions. Keywords: Depression, Neuromodulation, EEG, Resting-state fMRI

Dr. Alexander is Professor in the Departments of Psychology and Psychiatry, the Evelyn F. McKnight Brain Institute, and the Neuroscience and Physiological Sciences Graduate Interdisciplinary Programs of the University of Arizona. He is Director of the Brain Imaging, Behavior and Aging Lab, a member of the Internal Scientific Advisory Committee for the Arizona Alzheimer’s Consortium, and a member of the Scientific Advisory Board for the Arizona Evelyn F. McKnight Brain Institute. He received his post-doctoral training in neuroimaging and neuropsychology at Columbia University Medical Center and the New York State Psychiatric Institute. Prior to coming to Arizona, Dr. Alexander was Chief of the Neuropsychology Unit in the Laboratory of Neurosciences in the Intramural Research Program at the National Institute on Aging. Dr. Alexander has over 20 years experience as a neuroimaging and neuropsychology researcher in the study of aging and age-related neurodegenerative disease. He is a Fellow of the Association for Psychological Science and the American Psychological Association (Division 40) Society for Clinical Neuropsychology. His research has been supported by grants from the National Institutes of Health, the Evelyn F. McKnight Brain Research Foundation, the State of Arizona, and the Alzheimer’s Association. He uses structural and functional magnetic resonance imaging (MRI) and positron emission tomography (PET) combined with measures of cognition and behavior to investigate the effects of multiple health and lifestyle factors on the brain changes associated with aging and the risk for Alzheimer’s disease. Keywords: "Aging/Age-Related Disease", "Brain Imaging", "Cognitive Neurosicence", "Alzheimer's Disease"