My clinical and research interests center around behavioral and psychological symptoms that present in neurodegenerative diseases, especially dementias. Though dementia is well-known to affect one’s memory and cognition, over 90% of people with dementia develop new neuropsychiatric symptoms – including apathy, dysphoria. anxiety, aggression, agitation, disinhibition, hallucinations, and delusions. Despite the ubiquity of these symptoms, very little is known about how they develop in dementia. My research interests are in understanding more about the molecular and cellular mechanisms of neuropsychiatric symptoms in dementia beyond the well-studied changes associated with cognitive deficits.
Along with my research mentor Martin Darvas PhD (Department of Laboratory Medicine and Pathology), we employ numerous approaches to better understand these neuropsychiatric symptoms, including techniques involving transcriptomic analyses of human and mouse post-mortem tissue, development and implementation of biomarkers derived from human and animal model fluids (plasma, serum, cerebrospinal fluid), virally-mediated gene manipulations, animal modeling of cognitive and neuropsychiatric phenotypes, and basic cellular and molecular biology techniques.
I am a behavioral neuroscientist who earned my PhD from Rutgers University and completed a postdoc here, in the Psychiatry and Behavioral Sciences Department at the University of Washington. My lab, located in the MIRECC at VA Puget Sound, aims to identify the neural mechanisms underlying substance use disorders and maladaptive decision making.
My primary focus is studying the neurobiological consequences and predictors of chronic fentanyl use. To accomplish this, I utilize cutting-edge in-vivo optical neuroscience tools (photometry, optogenetics, miniscopes) along with a newly developed oral-fentanyl self-administration model for rats and mice. I am also the lead developer for DeepSqueak, a popular software package for bioacoustics analysis that integrates machine-vision algorithms with an intuitive graphical interface to accelerate animal communication research.
Anna Sunshine completed her medical school, graduate school and psychiatry training at the University of Washington. Her graduate training was completed in the Department of Genome Sciences where she used high-throughput sequencing approaches to study the biological effects of complex genetic changes in the model organism Saccharomyces cerevisiae.
Connecting her background in genomics with psychiatry, Dr. Sunshine’s research now focuses on identifying genetic risk factors for schizophrenia and characterizing the biological effects of these risk alleles using induced pluripotent stem cell (iPSC) systems. Dr. Sunshine engages individuals living with schizophrenia and their families in research to further our current understanding of schizophrenia biology and help lay groundwork for future treatment development.
Dr. Michael Schrift is a Professor in the Department of Psychiatry and Behavioral Sciences at the University of Washington. He currently is an attending neuropsychiatrist at the Brain & Memory Center at Harborview Medical Center. He is he the director of the Behavioral Neurology/Neuropsychiatry Fellowship Training Program. He previously was the Division Director of Geriatric Psychiatry & Neuropsychiatry in the Department of Psychiatry and Behavioral Sciences at Northwestern University Feinberg School of Medicine in Chicago. He was also the director of the fellowship training program in Geriatric Psychiatry, co-director of the Clinical Neuroscience Fellowship program, and the director of the Neuromodulation Program and the Cancer Neuropsychiatry Program. He has many years of experience treating patients with Parkinson’s disease, Huntington’s disease, and Wilson’s, among other neuropsychiatric disorders. He also is an attending neuropsychiatrist in the Harborview Memory and Brain Wellness Clinic.
Dr. Schrift is the Book Review Editor for the Journal of Neuropsychiatry and Clinical Neurosciences.
He is board-certified in Psychiatry by the American Board of Psychiatry and Neurology as well as board certified in Behavioral Neurology and Neuropsychiatry by the United Council for Neurologic Subspecialties. He has training in Bioethics and serves on the ethics committee at Harborview Medical Center. Dr. Schrift is a fellow of the American Neuropsychiatric Association.
Personal Statement
My research interests cover two main areas:
1) development and use of novel radioligands for positron emission tomography (PET) in CNS disorders
2) cannabinoid pharmacology, and cannabis use disorder and comorbid neuropsychiatric disorders
My VA Career Development Award (VA equivalent of an NIH K-award) focuses on the translational development of imaging neuroinflammation with PET following repetitive blast mild traumatic brain injury (mTBI). In collaboration with David Cook’s lab, imaging neuroinflammation in a mouse model of repetitive mTBI provides an opportunity to compare imaging outcomes directly with histopathology in brain tissue, which is not possible in humans. In collaboration with Elaine Peskind, imaging neuroinflammation in Veterans with mTBI and persistent post-concussive symptoms provides neuroanatomical specificity to ongoing neuroinflammation, which to date has been informed using cerebrospinal fluid and serum biomarkers. To accomplish this, my laboratory evaluates and develops established and novel PET radioligands for biomarkers of neuroinflammation. Additionally, I am interested in developing novel radioligands for druggable targets for which there are no current, suitable radioligands available. I have several ongoing collaborations with other investigators at UW and VA in which I provide support with PET imaging.
As a clinician and researcher, I am interested in how patients use cannabis for perceived therapeutic effect, and the risks and adverse outcomes resulting from substantial or chronic cannabis use. These clinical patterns can now be placed into context with a better understanding of the endocannabinoid system (ECS), which provide opportunity for more selective and safer therapeutic drug development. Due in part to the recentness of discovery of the ECS, one of my goals is to educate clinical providers on the preclinical and evidenced based research conducted to date on cannabis use and the ECS so they are better informed when discussing cannabis use with patients, and better prepared for understanding mechanisms of anticipated ECS-based medications currently under development. A second goal is to conduct research on cannabis use disorder and comorbid conditions, and identification of therapies that might better address a patient’s desired outcome from cannabis use, thereby reducing the likelihood of its associated risks.
Personal Statement
I am a basic neuroscientist, a board-certified practicing psychiatrist, and an Assistant Professor of Psychiatry and Behavioral Sciences at the University of Washington Medical School. The goal of my research is to investigate the neural circuitry of cognitive, emotional and memory processing, particularly as it relates to the cerebellum, and illnesses affecting cerebellum including cognitive disorders, PTSD, TBI and dementia through the implementation of techniques in mouse behavioral genetics. In my clinical practice, I primarily see veterans with PTSD, mild cognitive impairment, and various forms of dementia in an outpatient clinic at the VAMC Puget Sound Geriatric Research, Education, and Clinical Center (GRECC) in Seattle. I have over 15 years of experience in basic science research with most of that time dedicated to the use of mouse models of neuropsychiatric disorders.
Throughout my training prior to and during graduate school, I gained background in many contemporary molecular and biochemical lab techniques, such as molecular cloning, protein biochemistry, protein crystal production, fluorometric measurement of protein kinetics, in vivo NMR spectroscopy, gene targeting, microarray genomics, immunohistochemistry, and mammalian cell culture. I have a foundation in mouse genetics, neural development, and behavior which I developed in Michael Georgieff’s lab by investigating the role of iron in developing pyramidal neurons of the mouse hippocampus. During graduate training, I also received cross-training in child psychological development. In graduate school, I developed two mouse models of nonanemic neuron specific iron deficiency: 1) a conditional knockout of the Slc11a2 gene, encoding the iron transporter DMT-1 in forebrain neurons, including hippocampal pyramidal neurons, and 2) a transgenic mouse with a reversibly inducible dominant negative (nonfunctional) form of the transferrin receptor expressed only in hippocampal pyramidal neurons. I utilized and implemented different versions of the Morris Water Maze to study learning deficits in these mouse models of perinatal brain iron deficiency, a condition that is often a consequence of diabetes during pregnancy.
During my residency training, I expanded my knowledge of neuropsychiatric disorders by directly evaluating and treating patients with neuropsychiatric disorders including PTSD, schizophrenia, Alzheimer’s disease, autism, major depression, substance abuse disorders, and personality disorders. I learned numerous pharmacological, neuromodulatory, and psychotherapeutic interventions and participated in the internally funded Neuroscience Research Track. I then received a NIMH career development award (K08) mentored by Larry Zweifel, Ph.D. In that position, I investigated interactions between catecholamines and the cerebellum in decision making, emotional and cognitive processing. In the 5 years I was in Dr. Zweifel’s lab, I learned many additional new techniques including use of viral vectors, in vivo electrophysiology, and several operant- and threat-based behaviors, and moved forward in my goal of becoming a physician scientist isolating important circuits underlying etiology of specific domains of behavioral function. This work culminated in my receiving an RO1 independent investigator award, without any gap in funding.
My current research utilizes mouse behavior, in vivo electrophysiological recordings, gene targeting, viral vectors, translational profiling, chemo- and optogenetic tools, site-specific intracranial viral vector injection, and protein chemistry. I am now forging my path as an independent investigator, and my primary goal is to understand cerebellar circuits as they relate to psychiatric and neurodegenerative illnesses and utilize this knowledge to inform and improve current and novel psychiatric illnesses, primarily in cognitive and emotional domains. As such, I am pursuing a multidisciplinary approach combining genetic, electrophysiological, pharmacological, and behavioral techniques.
