Wang Lab
Welcome to the Wang Lab
The main focus of Dr. Wang's laboratory is to use an integrated systems approach to understand the logic of experience-dependent cortical information processing at the molecular, cellular, circuitry and behavioral levels. A variety of cutting-edge technologies in molecular and cellular biology, mouse genetics, in vivo multi-photon imaging, and electrophysiology as well as sophisticated behavioral analyses will be combined to investigate the ability of the brain to change in response to behavioral experiences during normal adaptive cognition such as perceptual discrimination and social recognition and in the context of maladaptive psychiatric disorders such as schizophrenia, depression and drug addiction.
Dr. Wang has genetically engineered a mouse line that enables direct visualization and tracking of experience-dependent and stimulus-specific molecular changes in the brain of live animals with single-cell resolution. With the aid of this line of mice, as well as new lines being developed that will provide more exquisite spatial and temporal controls of optical labeling and allow for functional manipulations of selected neurons, Dr. Wang's laboratory will identify and characterize the molecular and cellular changes in the primary sensory and higher association cortices that are regulated by the internal drives, environmental exposures, and social interactions of an animal.
Furthermore, Dr. Wang's group will examine the neurophyisological correlates of these molecular and cellular changes and investigate the mechanisms by which these changes are integrated in the cortical circuits to control behavioral decisions during perceptual discrimination and social recognition. Dr. Wang's group will also combine the optical-genetic systems that they are developing with mouse models of mental disorders to monitor the development of brain dysfunctions in real time, and test the effects of genetic risk factors as well as pharmacological and behavioral treatments.
Kuan Hong Wang, Ph.D.
Principal Investigator
Publications
View All Publications- Cholecystokinin facilitates motor skill learning by modulating neuroplasticity in the motor cortex.; eLife; Vol 13. 2024 May 03.
- Spinal projecting neurons in rostral ventromedial medulla co-regulate motor and sympathetic tone.; Cell. 2024 May 03.
- An ethologically motivated neurobiology of primate visually-guided reach-to-grasp behavior.; Current opinion in neurobiology; Vol 86, pp. 102872. 2024 Apr 01.
- Dopaminergic signaling regulates microglial surveillance and adolescent plasticity in the frontal cortex.; bioRxiv : the preprint server for biology. 2024 Mar 13.
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Wang Lab
KMRB G.9617
601 Elmwood Ave
Rochester, NY 14642