Capillary networks and have traditionally been viewed as passive sites for gas and nutrient exchange and waste removal. However, considering the vast area of the brain capillaries, which constitute ~90% of all vessels in the entire vascular landscape, the potential of these microvessels to serve sensory and signaling functions comes into sharp focus. Notably, their high density and close proximity to neurons ideally position capillaries to act as sensors of local signals from surrounding neurons and glia. Critically, a wide range of neurological disorders, including ischemic and hemorrhagic small vessel diseases, dementia, migraine, and age-related cognitive decline, exhibit deficits in cerebral blood flow. The enormity of the coverage area of brain capillaries, comprising pericytes and endothelial cells, can be more fully appreciated by direct visualization (see images below). 

The brain vasculature can respond to neuronal and glial signals and regulate blood flow through the activation of various receptors and ion channels. However, our understanding of the repertoire of ion channels in pericytes and capillary endothelial cells and the properties governing the propagation and amplification of signals between these cells remains incomplete. This gap in our knowledge obscures our overall understanding of blood flow regulation in the brain and how diseases may affect blood flow and brain health, thus representing a fruitful research area for many years to come.

The lab utilizes patch clamp electrophysiology, high resolution/speed confocal and fluorescent imaging, intracellular voltage recordings, functional ultrasound, and two-photon imaging in cortical and retinal tissue. Pictures and descriptions of the equipment are coming soon (still building most of them)!