Reduced brain glutamine in female varsity rugby athletes after concussion and in non‐concussed athletes after a season of play

Schranz, Amy L.; Manning, Kathryn Y.; Dekaban, Gregory A.; Fischer, Lisa; Jevremovic, Tatiana; Blackney, Kevin; Barreira, Christy; Doherty, Timothy J.; Fraser, Douglas D.; Brown, Arthur; Holmes, Jeffrey D.; Menon, Ravi S.; Bartha, Robert

doi:10.1002/hbm.23919

Cited by 28 publications

(40 citation statements)

References 52 publications

(91 reference statements)

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“…Changes in MR spectroscopy have previously been reported in a subset of these rugby players; glutamine concentrations were reduced after concussion and during the off-season and may relate to an evolving shift in oxidative metabolism or microglial priming. 13 All diffusion measures within the brainstem changed significantly between the in-and off-season in contact athletes only. The FA within the brainstem was significantly related to SCAT immediate memory scores, suggesting that these pair-wise changes in brain microstructural measures are related to exposure to repetitive impacts and altered immediate memory capacity.…”

Section: Discussionmentioning

confidence: 92%

“…These data were compared to longitudinal data from concussed contact athletes in a previous publication in which details of their season are described. 13,14 A total of 31 noncontact age-matched (p > 0.3) athletes were assessed during the in-season and 23 during the off-season. Noncontact athletes (i.e., rowers and swimmers) began regular training and practices while in-season data were collected (September).…”

Section: Methodsmentioning

confidence: 99%

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Longitudinal changes of brain microstructure and function in nonconcussed female rugby players

et al. 2020

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ObjectiveTo longitudinally assess brain microstructure and function in female varsity athletes participating in contact and noncontact sports.MethodsConcussion-free female rugby players (n = 73) were compared to age-matched (ages 18–23) female swimmers and rowers (n = 31) during the in- and off-season. Diffusion and resting-state fMRI (rs-fMRI) measures were the primary outcomes. The Sports Concussion Assessment Tool and head impact accelerometers were used to monitor symptoms and impacts, respectively.ResultsWe found cross-sectional (contact vs noncontact) and longitudinal (in- vs off-season) changes in white matter diffusion measures and rs-fMRI network connectivity in concussion-free contact athletes relative to noncontact athletes. In particular, mean, axial, and radial diffusivities were increased with decreased fractional anisotropy in multiple white matter tracts of contact athletes accompanied with default mode and visual network hyperconnectivity (p < 0.001). Longitudinal diffusion changes in the brainstem between the in- and off-season were observed for concussion-free contact athletes only, with progressive changes observed in a subset of athletes over multiple seasons. Axial diffusivity was significantly lower in the genu and splenium of the corpus callosum in those contact athletes with a history of concussion.ConclusionsTogether, these findings demonstrate longitudinal changes in the microstructure and function of the brain in otherwise healthy, asymptomatic athletes participating in contact sport. Further research to understand the long-term brain health and biological implications of these changes is required, in particular to what extent these changes reflect compensatory, reparative, or degenerative processes.

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Section: Discussionmentioning

confidence: 92%

Section: Methodsmentioning

confidence: 99%

Longitudinal changes of brain microstructure and function in nonconcussed female rugby players

et al. 2020

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“…Relation to previous investigations. A variety of previous investigations into the effects of sports participation, repetitive head impacts and white matter tissue properties of athletes have used the diffusion tensor (DTI) model (Bahrami et al, 2016;Basser et al, 1994;Bazarian et al, 2014;Burzynska et al, 2016;Chang et al, 2015;Chun et al, 2015;Churchill et al, 2017aChurchill et al, , 2017bDavenport et al, 2016aDavenport et al, , 2016bDavenport et al, , 2014Deng et al, 2018;Duru and Balcioglu, 2018;Gajawelli et al, 2013;Hänggi et al, 2015Hänggi et al, , 2010Jäncke et al, 2009;Koerte et al, 2012;Kuzminski et al, 2018;Lao et al, 2015;Marchi et al, 2013;Mayinger et al, 2018;McAllister et al, 2014;Merchant-Borna et al, 2016;Myer et al, 2018Myer et al, , 2016aMyer et al, , 2016bPark et al, 2015;Saghafi et al, 2018;Schlaffke et al, 2014;Schranz et al, 2018;Sollmann et al, 2018;Stamm et al, 2015;Yuan et al, 2018) . The studies investigating the effects of elite sports participation commonly report lower fractional anisotropy (FA) and higher mean diffusivity (MD) between athletes and non-athletes.…”

Section: Discussionmentioning

confidence: 99%

Advanced mapping of the human white matter microstructure better separates elite sports participation

Caron¹,

Bullock²,

Kitchell³

et al. 2020

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Collision-sport athletes, especially football players, are exposed to a higher number of repetitive head impacts. Little is known, however, regarding the effects of long-term exposure to repetitive head impacts on brain tissue structure and the locations (i.e. superficial or deep tissue structures) affected. On top of this, little is known about the effects of highly competitive athletics on brain tissue structure. We investigated this relationship, including the baseline effect of collegiate athletic participation, by mapping measures of microstructure to cortical and subcortical white matter parcels and major white matter tracts of varsity IU football players, cross-country runners, and non-athlete students using advanced microstructural mapping techniques and machine-learning. We tested a series of hypotheses on the differences between the subject groups. To do so, we implemented an innovative approach to statistical hypothesis testing combining advanced white matter tissue properties and machine-learning classifiers. We used cross-validation to select the best subject group model and best machine-learning classifier. Wide-spread differences in brain tissue microstructure across cortical, subcortical, and major white matter structures were documented. The tissue properties of the major white matter tracts were found to best predict collision-sport participation and sports participation in general, however, cortical and subcortical white matter parcels were also found to predict collision-sports participation. The biggest differences in brain tissue microstructure is between the athletes (football and cross country combined) and the non-athletes students. The rewards and risks of playing competitive sports at the highest collegiate level may account for the differences in brain microstructure. This was the first investigation into the effects of repetitive head impacts to use an open-source data processing platform brainlife.io. The data and code for these analyses are available via brainlife.io.

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“…The most common SVS voxel placement reflects the fact that preclinical and postmortem studies have identified white matter diffuse axonal injury as the hallmark site of TBI injury (Su & Bell, 2015). Most often, the targeted regions have been frontal/prefrontal white matter (Maugans et al, 2012;Schranz et al, 2018;Sivák et al, 2014;Vagnozzi et al, 2010Vagnozzi et al, , 2008Walz et al, 2008); Dhandapani et al, 2014), splenium (Cecil et al, 1998;Gasparovic et al, 2009; and genu of the corpus callosum. SVS voxel placement in gray matter is also common, with most studies focusing on the cingulate gyrus (Koerte et al, 2015;Lin et al, 2012;Louis et al, 2017), dorsolateral prefrontal cortex (Dean et al, 2015;Henry et al, 2010;Poole et al, 2014;Bari et al, 2019) and primary motor cortex (Tremblay et al, 2014).…”

Section: Considerations For Study Design Multisite Studies and Recomentioning

confidence: 99%

The Clinical Utility of Magnetic Resonance Spectroscopy in Traumatic Brain Injury: Recommendations from the ENIGMA MRS Working Group

Bartnik‐Olson¹,

Tate²,

Babikian³

et al. 2019

Preprint

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Proton magnetic resonance spectroscopy provides a non-invasive and quantitative measure of brain metabolites. Traumatic brain injury impacts cerebral metabolism and a number of research groups have successfully used this technique as a biomarker of injury and/or outcome in both pediatric and adult TBI populations. However, this technique is underutilized, with studies being performed primarily at centers with access to MR research support. In this paper we present a technical introduction to the acquisition and analysis of in vivo magnetic resonance spectroscopy and review magnetic resonance spectroscopy findings in different injury populations. In addition, we propose a basic data acquisition scheme that can be added to any imaging protocol, regardless of clinical magnetic resonance platform. We outline a number of considerations for study design as a way of encouraging the use of magnetic resonance spectroscopy in the study of traumatic brain injury, as well as recommendations to improve data harmonization across groups already using this technique.

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Reduced brain glutamine in female varsity rugby athletes after concussion and in non‐concussed athletes after a season of play

Cited by 28 publications

References 52 publications

Longitudinal changes of brain microstructure and function in nonconcussed female rugby players

Longitudinal changes of brain microstructure and function in nonconcussed female rugby players

Advanced mapping of the human white matter microstructure better separates elite sports participation

The Clinical Utility of Magnetic Resonance Spectroscopy in Traumatic Brain Injury: Recommendations from the ENIGMA MRS Working Group

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