Impairment of cerebrovascular reactivity in response to hypercapnic challenge in a mouse model of repetitive mild traumatic brain injury

Lynch, Cillian; Eisenbaum, Maxwell; Algamal, Moustafa; Balbi, Matilde; Ferguson, Scott; Mouzon, Benoit; Saltiel, Nicole; Ojo, Joseph; Mullan, Mike; Crawford, Fiona; Bachmeier, Corbin

doi:10.1177/0271678x20954015

Cited by 15 publications

(18 citation statements)

References 108 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Similarly, in human AD microvessel extracts, it was found that reduced brain mural cell levels correlated with cognitive impairment and AD diagnosis ( Bourassa et al, 2020 ). In our prior work using this r-mTBI mouse model, we observed a decline in cognitive performance at 1 month post-injury which progressively deteriorated at 3 and 6 months post-injury ( Lynch et al, 2016 ; Lynch et al, 2020 ), in line with the mural cell degeneration we observed at these time points following r-mTBI in the current studies, though further work is needed to understand the potential correlation between brain mural cell changes and cognitive function. Collectively, these studies point toward mural cell disruption as a contributing factor in TBI pathogenesis and cognitive impairment.…”

Section: Discussionsupporting

confidence: 81%

“…In our studies, we performed flow cytometry to assess the state of the mural cell population after r-mTBI and found no change in the of number of CD13+ cells between r-sham and r-mTBI cerebrovessels at 6 months post-injury. Furthermore, we recently reported no difference in mural cell vessel density between r-sham and r-mTBI animals (up to 9 months post-injury) based on CD13 vessel coverage using confocal microscopy ( Lynch et al, 2020 ). Thus, while mural cell loss may occur acutely following brain trauma ( Choi et al, 2016 ; Bhowmick et al, 2019 ), there does not appear to be an overt reduction in the number of mural cells in the chronic phase post-injury, but rather a progressive decline in key mural cell proteins (i.e., PDGFRβ and αSMC-actin), which are expressed in both pericytes and smooth muscle cells ( Alarcon-Martinez et al, 2018 ; Hellstrom et al, 1999 ; Skalli et al, 1989 ).…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Mural cell dysfunction leads to altered cerebrovascular tau uptake following repetitive head trauma

Ojo

Eisenbaum

Shackleton

et al. 2021

Neurobiology of Disease

Self Cite

View full text Add to dashboard Cite

A pathological characteristic of repetitive traumatic brain injury (TBI) is the deposition of hyperphosphorylated and aggregated tau species in the brain and increased levels of extracellular monomeric tau are believed to play a role in the pathogenesis of neurodegenerative tauopathies. The pathways by which extracellular tau is eliminated from the brain, however, remains elusive. The purpose of this study was to examine tau uptake by cerebrovascular cells and the effect of TBI on these processes. We found monomeric tau interacts with brain vascular mural cells (pericytes and smooth muscle cells) to a greater extent than other cerebrovascular cells, indicating mural cells may contribute to the elimination of extracellular tau, as previously described for other solutes such as beta-amyloid. Consistent with other neurodegenerative disorders, we observed a progressive decline in cerebrovascular mural cell markers up to 12 months post-injury in a mouse model of repetitive mild TBI (r-mTBI) and human TBI brain specimens, when compared to control. These changes appear to reflect mural cell degeneration and not cellular loss as no difference in the mural cell population was observed between r-mTBI and r-sham animals as determined through flow cytometry. Moreover, freshly isolated r-mTBI cerebrovessels showed reduced tau uptake at 6 and 12 months post-injury compared to r-sham animals, which may be the result of diminished cerebrovascular endocytosis, as caveolin-1 levels were significantly decreased in mouse r-mTBI and human TBI cerebrovessels compared to their respective controls. Further emphasizing the interaction between mural cells and tau, similar reductions in mural cell markers, tau uptake, and caveolin-1 were observed in cerebrovessels from transgenic mural cell-depleted animals. In conclusion, our studies indicate repeated injuries to the brain causes chronic mural cell degeneration, reducing the caveolar-mediated uptake of tau by these cells. Alterations in tau uptake by vascular mural cells may contribute to tau deposition in the brain following head trauma and could represent a novel therapeutic target for TBI or other neurodegenerative disorders.

show abstract

Section: Discussionsupporting

confidence: 81%

Section: Discussionmentioning

confidence: 99%

Mural cell dysfunction leads to altered cerebrovascular tau uptake following repetitive head trauma

Ojo

Eisenbaum

Shackleton

et al. 2021

Neurobiology of Disease

Self Cite

View full text Add to dashboard Cite

show abstract

“…In a chronic repetitive mTBI model in mice, involving two mTBIs per week for three months, a study demonstrated a significant reduction in CBF at three months post last injury 78 . Using the same injury paradigm, differences in compromised cerebrovascular reactivity were demonstrated at 3 and 9 months post-last injury 79 , reflecting findings in a human moderate to severe TBI patient population 80 . BBB disruption has also recently been shown after mTBI in swine, with the same appearance, albeit to a much lesser extent as found in moderate to severe TBI in humans, although the rete mirabile in swine may limit applicability to human TBI 58,73 .…”

Section: Vascular Injurysupporting

confidence: 56%

Roadmap for Advancing Pre-Clinical Science in Traumatic Brain Injury

Smith

Kochanek

Rosi

et al. 2021

Journal of Neurotrauma

Self Cite

View full text Add to dashboard Cite

Pre-clinical models of disease have long played important roles in the advancement of new treatments. However, in traumatic brain injury (TBI), despite the availability of numerous model systems, translation from bench to bedside remains elusive. Integrating clinical relevance into pre-clinical model development is a critical step toward advancing therapies for TBI patients across the spectrum of injury severity. Pre-clinical models include in vivo and ex vivo animal work—both small and large—and in vitro modeling. The wide range of pre-clinical models reflect substantial attempts to replicate multiple aspects of TBI sequelae in humans. Although these models reveal multiple putative mechanisms underlying TBI pathophysiology, failures to translate these findings into successful clinical trials call into question the clinical relevance and applicability of the models. Here, we address the promises and pitfalls of pre-clinical models with the goal of evolving frameworks that will advance translational TBI research across models, injury types, and the heterogenous etiology of pathology.

show abstract

“…Preclinical CVR studies predominantly follow similar approaches to human studies but involve additional considerations such as the effect of anaesthetic agents on resting CBF (Stringer et al, 2021). Isolated vessel preparations (Seitz et al, 2004;Joutel et al, 2010), laser speckle imaging (Lynch et al, 2020), and multiphoton microscopy (Joo et al, 2017;Kisler et al, 2017) can also assess CVR preclinically and may help improve understanding of how impaired vasoreactivity develops and further direct validation of CVR-MRI as a clinical biomarker of cerebrovascular health (Stringer et al, 2021). CVR measurements using MRI techniques showed lower repeatability between-days than within-days (Dengel et al, 2017;Merola et al, 2018).…”

Section: Validationmentioning

confidence: 99%

Cerebrovascular Reactivity Measurement Using Magnetic Resonance Imaging: A Systematic Review

et al. 2021

View full text Add to dashboard Cite

Cerebrovascular reactivity (CVR) magnetic resonance imaging (MRI) probes cerebral haemodynamic changes in response to a vasodilatory stimulus. CVR closely relates to the health of the vasculature and is therefore a key parameter for studying cerebrovascular diseases such as stroke, small vessel disease and dementias. MRI allows in vivo measurement of CVR but several different methods have been presented in the literature, differing in pulse sequence, hardware requirements, stimulus and image processing technique. We systematically reviewed publications measuring CVR using MRI up to June 2020, identifying 235 relevant papers. We summarised the acquisition methods, experimental parameters, hardware and CVR quantification approaches used, clinical populations investigated, and corresponding summary CVR measures. CVR was investigated in many pathologies such as steno-occlusive diseases, dementia and small vessel disease and is generally lower in patients than in healthy controls. Blood oxygen level dependent (BOLD) acquisitions with fixed inspired CO2 gas or end-tidal CO2 forcing stimulus are the most commonly used methods. General linear modelling of the MRI signal with end-tidal CO2 as the regressor is the most frequently used method to compute CVR. Our survey of CVR measurement approaches and applications will help researchers to identify good practice and provide objective information to inform the development of future consensus recommendations.

show abstract

Impairment of cerebrovascular reactivity in response to hypercapnic challenge in a mouse model of repetitive mild traumatic brain injury

Cited by 15 publications

References 108 publications

Mural cell dysfunction leads to altered cerebrovascular tau uptake following repetitive head trauma

Mural cell dysfunction leads to altered cerebrovascular tau uptake following repetitive head trauma

Roadmap for Advancing Pre-Clinical Science in Traumatic Brain Injury

Cerebrovascular Reactivity Measurement Using Magnetic Resonance Imaging: A Systematic Review

Contact Info

Product

Resources

About