Mechanical restriction of intracortical vessel dilation by brain tissue sculpts the hemodynamic response

Gao, Yongkang; Greene, Stephanie E.; Drew, Patrick J.

doi:10.1016/j.neuroimage.2015.04.054

Cited by 65 publications

(90 citation statements)

References 138 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Because the resistance of a blood vessel depends on its diameter, these dilations cause a sharp reduction of vascular resistance, which increases blood velocity and flux. This increase in arterial diameter and blood flow is relatively rapid, occurring within less than a second following the stimulation (Chen et al, 2011; Drew et al, 2011; Gao et al, 2015; Kim et al, 2013). Arterial dilation and increased blood flow result in an elevated influx of oxygenated hemoglobin that exceeds the oxygen demand of the surrounding neural tissue (Fox and Raichle, 1986).…”

Section: Introductionmentioning

confidence: 99%

“…A cranial window may also be implanted at this time. After allowing adequate time for surgical recovery, we begin the habituation to head-fixation, which can be done on treadmill that allows locomotion (Dombeck et al, 2010; Gao et al, 2015; Gao and Drew, 2014; Huo et al, 2014; Rosenegger et al, 2015; Tran and Gordon 2015), or body restraining cylinders or slings (Berwick et al, 2002; Drew et al, 2011) (Fig. 8).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Time to wake up: Studying neurovascular coupling and brain-wide circuit function in the un-anesthetized animal

et al. 2017

Self Cite

View full text Add to dashboard Cite

Functional magnetic resonance imaging (fMRI) has allowed the noninvasive study of task-based and resting-state brain dynamics in humans by inferring neural activity from blood-oxygenation-level dependent (BOLD) signal changes. An accurate interpretation of the hemodynamic changes that underlie fMRI signals depends on the understanding of the quantitative relationship between changes in neural activity and changes in cerebral blood flow, oxygenation and volume. While there has been extensive study of neurovascular coupling in anesthetized animal models, anesthesia causes large disruptions of brain metabolism, neural responsiveness and cardiovascular function. Here, we review work showing that neurovascular coupling and brain circuit function in the awake animal are profoundly different from those in the anesthetized state. We argue that the time is right to study neurovascular coupling and brain circuit function in the awake animal to bridge the physiological mechanisms that underlie animal and human neuroimaging signals, and to interpret them in light of underlying neural mechanisms. Lastly, we discuss recent experimental innovations that have enabled the study of neurovascular coupling and brain-wide circuit function in un-anesthetized and behaving animal models.

show abstract

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Time to wake up: Studying neurovascular coupling and brain-wide circuit function in the un-anesthetized animal

et al. 2017

Self Cite

View full text Add to dashboard Cite

show abstract

“…To study the flow of CSF in the PVS driven by functional hyperemia, we imposed arterial wall motion in our model that matched those observed in awake mice during a typical functional hyperemic event [34][35][36] (Fig 4a). The mathematical formulation of this problem is identical to the previous simulation, with the exception that the arterial wall movement was given by a typical vasodilation profile instead of a heartbeat-driven peristaltic wave (Fig 4a).…”

Section: Ignoring Brain Deformability Leads To Implausibly High Pressmentioning

confidence: 99%

“…We simultaneously imaged processes of Thy1-expressing neurons and blood vessel diameters via intravenous injection of Texas-red dextran (Fig 5b). Arterioles in the somatosensory cortex dilate during spontaneous locomotion events due to increases in local neural activity 35 , so we imaged these vessels that will be naturally subject to large vasodilation. We performed piecewise, iterative motion correction of the collected images relative to the center of the artery (see Methods) in order to robustly measure the displacement of brain tissue during arterial dilations.…”

Section: Ignoring Brain Deformability Leads To Implausibly High Pressmentioning

confidence: 99%

Functional hyperemia drives fluid exchange in the paravascular space

Kedarasetti

Turner

Echagarruga

et al. 2019

Preprint

Self Cite

View full text Add to dashboard Cite

Maintaining the ionic and chemical composition of the extracellular spaces in the brain is extremely important for its health and function. However, the brain lacks a conventional lymphatic system to remove metabolic waste. It has been proposed that the fluid movement through the paravascular space (PVS) surrounding penetrating arteries can help remove metabolites from the brain. The dynamics of fluid movement in the PVS and its interaction with arterial dilation and brain mechanics are not well understood. Here, we performed simulations to understand how arterial pulsations and dilations interact with brain deformability to drive fluid flow in the PVS. In simulations with compliant brain tissue, arterial pulsations did not drive appreciable flows in the PVS. In contrast, when the artery dilated with dynamics like those seen during functional hyperemia, there was a marked movement of fluid through the PVS. Our simulations suggest that in addition to its other purposes, functional hyperemia may serve to increase fluid exchange between the PVS and the subarachnoid space, improving the clearance of metabolic waste. We measured displacement of the blood vessels and the brain tissue simultaneously in awake, headfixed mice using two-photon microscopy. Our measurements show that brain tissue can deform in response to fluid movement in the PVS, as predicted by simulations. The results from our simulations and experiments show that the deformability of the soft brain tissue needs to be accounted for when studying fluid flow and metabolite transport in the brain.

show abstract

“…The problem with the first three models is that they only considered temporal variations in the BOLD signal across the cortical depth, disregarding any spatial effects. This cannot be used to explain hemodynamic waves in the brain (Aquino et al, 2012;Gao et al, 2015;Gravel et al, 2017;Hindriks et al, 2019). On the other hand, the work of Puckett et al (2016) was based on our cortical hemodynamic model but introduced advancements by not implementing averaging over z, allowing estimations of BOLD versus levels of the cortical depth and with each level defined by independent spatiotemporal hemodynamic processes.…”

Section: Introductionmentioning

confidence: 99%

Cortical Depth-Dependent Modeling of Visual Hemodynamic Responses

Lacy

Robinson

Aquino

et al. 2020

Preprint

View full text Add to dashboard Cite

A physiologically based three-dimensional (3D) hemodynamic model is used to predict the experimentally observed blood oxygen level dependent (BOLD) responses versus the cortical depth induced by visual stimuli. Prior 2D approximations are relaxed in order to analyze 3D blood flow dynamics as a function of cortical depth. Comparison of the predictions with experimental data for typical stimuli demonstrates that the full 3D model matches at least as well as previous approaches while requiring significantly fewer assumptions and model parameters.

show abstract

Mechanical restriction of intracortical vessel dilation by brain tissue sculpts the hemodynamic response

Cited by 65 publications

References 138 publications

Time to wake up: Studying neurovascular coupling and brain-wide circuit function in the un-anesthetized animal

Time to wake up: Studying neurovascular coupling and brain-wide circuit function in the un-anesthetized animal

Functional hyperemia drives fluid exchange in the paravascular space

Cortical Depth-Dependent Modeling of Visual Hemodynamic Responses

Contact Info

Product

Resources

About