Blood-brain barrier disruption, traumatic encephalopathy, and cognitive decline in retired athletes
Cerebrovascular disruption has been implicated in the pathophysiology of head trauma and chronic traumatic encephalopathy (CTE). However, the long-term consequences of repetitive head trauma on blood-brain barrier (BBB) integrity and its link to cognitive function remain unknown.
Here, using dynamic contrast–enhanced magnetic resonance imaging (DCE-MRI), we show that BBB disruption can be detected years after the retirement of combat and collision sports athletes (n = 47) from their respective sports. A subgroup of individuals (n = 17) with extensive BBB disruption displayed worse cognitive decline compared with those with less extensive BBB disruption. Commonly used systemic markers of central nervous system injury and neurodegeneration were of limited utility; however, a greater systemic inflammatory burden with a higher proportion of circulating monocytes was associated with cognitive decline in the retired athletes.
Transcriptomic analysis of these peripheral immune cells revealed dysregulation of the complement system and vascular developmental pathways. Altered expression of complement receptors, including C5AR1, ITGAM, ITGB2, and CD59, a potent inhibitor of the membrane attack complex (MAC), was associated with BBB disruption and cognitive decline.
Postmortem brain tissues from those with confirmed cases of CTE showed MAC deposition around cerebral blood vessels. Bioinformatic analysis of single-nucleus RNA sequencing data from postmortem individuals with CTE revealed microglia-endothelial cross-talk, which may mediate complement dysregulation.
Together, our data suggest that sustained systemic inflammation and persistent BBB disruption are associated with the long-term outcome of repetitive head trauma.
EDITORS SUMMARY
Athletes who play collision and combat sports with exposure to repetitive head trauma are at increased risk for cognitive decline. Greene et al. now show in 47 retired athletes using dynamic contrast–enhanced MRI (DCE-MRI) imaging that blood-brain barrier (BBB) disruption was present years after exposure to repetitive head impacts. They report greater leakage via the BBB that was associated with poorer cognition in the retired athletes compared with a control group. However, symptom history and self-reported concussions did not reliably predict this BBB abnormality. A distinct subgroup of retired athletes with extensive BBB leakage showed worse cognitive performance and lower brain volumes as well as an increase in monocytes and complement dysregulation. These findings suggest that persistent BBB disruption and systemic inflammation after sport-related head trauma remain in athletes long after they have retired.
Web | DOI | Science Translational Medicine | Paywall
Chris Greene; Declan Brennan; Sheida Mirloo; Ruairi Connolly; Jeffrey O’Callaghan; Avril Reddy; Jeff Henderson; Gergő Porkoláb; Adam McGlinchey; Nicole Hanley; Siobhan Hutchinson; James F M Meaney; Michael Farrell; Sarah L Doyle; Alon Friedman; Colin P Doherty; Matthew Campbell
Cerebrovascular disruption has been implicated in the pathophysiology of head trauma and chronic traumatic encephalopathy (CTE). However, the long-term consequences of repetitive head trauma on blood-brain barrier (BBB) integrity and its link to cognitive function remain unknown.
Here, using dynamic contrast–enhanced magnetic resonance imaging (DCE-MRI), we show that BBB disruption can be detected years after the retirement of combat and collision sports athletes (n = 47) from their respective sports. A subgroup of individuals (n = 17) with extensive BBB disruption displayed worse cognitive decline compared with those with less extensive BBB disruption. Commonly used systemic markers of central nervous system injury and neurodegeneration were of limited utility; however, a greater systemic inflammatory burden with a higher proportion of circulating monocytes was associated with cognitive decline in the retired athletes.
Transcriptomic analysis of these peripheral immune cells revealed dysregulation of the complement system and vascular developmental pathways. Altered expression of complement receptors, including C5AR1, ITGAM, ITGB2, and CD59, a potent inhibitor of the membrane attack complex (MAC), was associated with BBB disruption and cognitive decline.
Postmortem brain tissues from those with confirmed cases of CTE showed MAC deposition around cerebral blood vessels. Bioinformatic analysis of single-nucleus RNA sequencing data from postmortem individuals with CTE revealed microglia-endothelial cross-talk, which may mediate complement dysregulation.
Together, our data suggest that sustained systemic inflammation and persistent BBB disruption are associated with the long-term outcome of repetitive head trauma.
EDITORS SUMMARY
Athletes who play collision and combat sports with exposure to repetitive head trauma are at increased risk for cognitive decline. Greene et al. now show in 47 retired athletes using dynamic contrast–enhanced MRI (DCE-MRI) imaging that blood-brain barrier (BBB) disruption was present years after exposure to repetitive head impacts. They report greater leakage via the BBB that was associated with poorer cognition in the retired athletes compared with a control group. However, symptom history and self-reported concussions did not reliably predict this BBB abnormality. A distinct subgroup of retired athletes with extensive BBB leakage showed worse cognitive performance and lower brain volumes as well as an increase in monocytes and complement dysregulation. These findings suggest that persistent BBB disruption and systemic inflammation after sport-related head trauma remain in athletes long after they have retired.
Web | DOI | Science Translational Medicine | Paywall