Research

A person is only as old as their arteries. We assess vascular aging with gold standard methods such as carotid-femoral pulse wave velocity (aortic stiffness), ultrasonography (carotid stiffness), and pulse contour analysis of pressure waveforms (wave reflections, augmentation index, reservoir pressure). Additionally, we are exploring use of shear wave elastography to measure viscoelastic tissue properties of the carotid artery as a novel measure of carotid artery stiffness.

Hemodynamics is the study of blood pressure and blood flow. To assess cerebral hemodynamics, we use transcranial Doppler to evaluate cerebral blood velocity. Measurement of cerebral blood velocity during cognitive tasks and acute changes in blood pressure with mental tasks (Stroop task) or physical tasks (sit to stand) is used to assess neurovascular coupling and cerebral autoregulation, respectively. We also utilize rheoencephalography to obtain intracranial impedance waveforms and are exploring novel ways of analyzing these waveforms with harmonic distortion to understand brain physiology. Finally, we are piloting ultrasound-based methods that combine speckle tracking and tissue Doppler imaging to assess brain tissue pulsations that are produced with each heartbeat.

Electroencephalography (EEG) is used to assess spontaneous neural oscillations caused by fluctuations in neuronal excitability. In addition to obtaining information across different frequency bands (delta, theta, alpha, beta, gamma), we are exploring different approaches to measuring functional connectivity (how different parts of the brain interact and exchange information). EEG can be combined with functional near-infrared spectroscopy (fNIRS) to assess regional cortical tissue oxygenation changes that occur with concomitant neural activation.

Cognitive function is assessed using a variety of methods including such platforms as NIH Toolbox along with customized continuous performance tasks to assess cognitive control. Cognitive tasks can be combined with gait tasks and balance tasks (measured on a force platform to obtain center of mass postural sway metrics) to increase cognitive load (dual tasks). Additionally, we are exploring use of virtual reality to perform novel tests of sensorimotor integration.