Microstructural and metabolic changes in the brains of concussed athletes

Henry, Luke

07 1900

Les commotions cérébrales ont longtemps été considérées comme une blessure ne comportant que peu ou pas de conséquences. Cependant, la mise à la retraite forcée de plusieurs athlètes de haut niveau, liée au fait d'avoir subi des commotions cérébrales multiples, a porté cette question au premier plan de la culture scientifique et sportive. Malgré la sensibilisation croissante du public et la compréhension scientifique accrue des commotions cérébrales, il reste encore beaucoup d’inconnus au sujet de ces blessures. En effet, il est difficile de comprendre comment cette atteinte peut avoir des effets si profonds malgré le fait qu’elle n’entraîne apparemment pas de conséquences physiques apparentes lorsque les techniques traditionnelles d’imagerie cérébrale sont utilisées. Les techniques de neuroimagerie fonctionnelle ont cependant contribué à répondre aux nombreuses questions entourant les conséquences des commotions cérébrales ainsi qu'à accroître la compréhension générale de la physiopathologie de commotions cérébrales. Bien que les techniques de base telles que l'imagerie structurelle comme les scans TC et IRM soient incapables de détecter des changements structurels dans la grande majorité des cas (Ellemberg, Henry, Macciocchi, Guskiewicz, & Broglio, 2009; Johnston, Ptito, Chankowsky, & Chen, 2001), d'autres techniques plus précises et plus sensibles ont été en mesure de détecter avec succès des changements dans le cerveau commotionné. Des études d’IRM fonctionelle ont entre autres établi une solide relation entre les altérations fonctionnelles et les symptômes post-commotionels (Chen, Johnston, Collie, McCrory, & Ptito, 2007; Chen et al., 2004; Chen, Johnston, Petrides, & Ptito, 2008; Fazio, Lovell, Pardini, & Collins, 2007). Les mesures électrophysiologiques telles que les potentiels évoqués cognitifs (ERP) (Gaetz, Goodman, & Weinberg, 2000; Gaetz & Weinberg, 2000; Theriault, De Beaumont, Gosselin, Filipinni, & Lassonde, 2009; Theriault, De Beaumont, Tremblay, Lassonde, & Jolicoeur, 2010) et la stimulation magnétique transcrânienne ou SMT (De Beaumont, Brisson, Lassonde, & Jolicoeur, 2007; De Beaumont, Lassonde, Leclerc, & Theoret, 2007; De Beaumont et al., 2009) ont systématiquement démontré des altérations fonctionnelles chez les athlètes commotionnés. Cependant, très peu de recherches ont tenté d'explorer davantage certaines conséquences spécifiques des commotions cérébrales, entre autres sur les plans structural et métabolique. La première étude de cette thèse a évalué les changements structurels chez les athlètes commotionnés à l’aide de l'imagerie en tenseur de diffusion (DTI) qui mesure la diffusion de l'eau dans la matière blanche, permettant ainsi de visualiser des altérations des fibres nerveuses. Nous avons comparé les athlètes commotionnés à des athlètes de contrôle non-commotionnés quelques jours après la commotion et de nouveau six mois plus tard. Nos résultats indiquent un patron constant de diffusion accrue le long des voies cortico-spinales et dans la partie du corps calleux reliant les régions motrices. De plus, ces changements étaient encore présents six mois après la commotion, ce qui suggère que les effets de la commotion cérébrale persistent bien après la phase aiguë. Les deuxième et troisième études ont employé la spectroscopie par résonance magnétique afin d'étudier les changements neurométaboliques qui se produisent dans le cerveau commotionné. La première de ces études a évalué les changements neurométaboliques, les aspects neuropsychologiques, et la symptomatologie dans la phase aiguë post-commotion. Bien que les tests neuropsychologiques aient été incapables de démontrer des différences entre les athlètes commotionnés et non-commotionnés, des altérations neurométaboliques ont été notées dans le cortex préfrontal dorsolatéral ainsi que dans le cortex moteur primaire, lesquelles se sont avérées corréler avec les symptômes rapportés. La deuxième de ces études a comparé les changements neurométaboliques immédiatement après une commotion cérébrale et de nouveau six mois après l’atteinte. Les résultats ont démontré des altérations dans le cortex préfrontal dorsolatéral et moteur primaire dans la phase aiguë post-traumatique, mais seules les altérations du cortex moteur primaire ont persisté six mois après la commotion. Ces résultats indiquent que les commotions cérébrales peuvent affecter les propriétés physiques du cerveau, spécialement au niveau moteur. Il importe donc de mener davantage de recherches afin de mieux caractériser les effets moteurs des commotions cérébrales sur le plan fonctionnel. / Concussions had long been considered an injury of little to no consequence. However, the forced retirement of several high profile athletes due to the impact of having suffered multiple concussions has pushed the issue to the forefront of scientific and sports culture alike. Despite the growing public awareness and the ever-expanding scientific understanding of concussions there is still much that remains unknown about these injuries. Indeed, understanding how an injury can have such profound effects, though mostly transient, without any apparent physical consequence continues to confound how concussions are conceptualized in research. Neuroimaging techniques have helped answer many of the questions surrounding the physical consequences of concussions on the brain as well as increasing the general understanding of the pathophysiology of concussions. While basic structural imaging techniques such as CT scans and MRI are unable to detect any structural changes in the vast majority of cases (Ellemberg, et al., 2009; Johnston, et al., 2001), other more precise and sensitive techniques have been able to successfully detect changes in the concussed brain. Functional MRI studies have further established a strong relationship between functional alterations and post-concussion symptoms (Chen, et al., 2007; Chen, et al., 2004; Chen, et al., 2008; Fazio, et al., 2007). Electrophysiological measures such as ERP (Gaetz, et al., 2000; Gaetz & Weinberg, 2000; Theriault, et al., 2009; Theriault, et al., 2010) and TMS (De Beaumont, Brisson, et al., 2007; De Beaumont, Lassonde, et al., 2007; De Beaumont, et al., 2009) have consistently demonstrated alterations in concussed athletes. However, there has been very little research that has attempted to further explore the specific structural and metabolic aspects of concussion. The first study assessed structural changes in concussed athletes using diffusion tensor imaging which measures water diffusion in white matter. We compared concussed athletes with non-concussed control athletes in the days immediately after injury and again six months later. Our results indicated a consistent pattern of increased diffusion along neural tracts of the cortical spinal tract and in the corpus callosum underlying motor cortex. Furthermore, these changes were still present six months after injury suggesting that the effects of concussion are persistent past the acute phase. The second and third studies employed magnetic resonance spectroscopy as a means of investigating the neurometabolic changes that occur in the concussed brain. The first of these studies investigated the neurometabolic changes, neuropsychological aspects, and symptomatology in the acute post-injury phase. While neuropsychological testing was unable to show differences between concussed and non-concussed athletes, neurometabolic alterations were noted in the dorsal lateral prefrontal cortex as well as in primary motor cortex which correlated with reported symptoms. The second study investigated neurometabolic changes immediately after concussion and again six months after injury. Results indicated alterations in the dorsolateral prefrontal and primary motor cortices in the acute post-injury phase, but only those in primary motor cortex persisted to the six month time point.

Commotion cérébrale

Neuro-imagerie

Traumatisme axonal

Neurometabolism

Concussion

Neuroimaging

Traumatic axonal Injury

Neurometabolism

Microstructural and metabolic changes in the brains of concussed athletes

Henry, Luke

07 1900

Les commotions cérébrales ont longtemps été considérées comme une blessure ne comportant que peu ou pas de conséquences. Cependant, la mise à la retraite forcée de plusieurs athlètes de haut niveau, liée au fait d'avoir subi des commotions cérébrales multiples, a porté cette question au premier plan de la culture scientifique et sportive. Malgré la sensibilisation croissante du public et la compréhension scientifique accrue des commotions cérébrales, il reste encore beaucoup d’inconnus au sujet de ces blessures. En effet, il est difficile de comprendre comment cette atteinte peut avoir des effets si profonds malgré le fait qu’elle n’entraîne apparemment pas de conséquences physiques apparentes lorsque les techniques traditionnelles d’imagerie cérébrale sont utilisées. Les techniques de neuroimagerie fonctionnelle ont cependant contribué à répondre aux nombreuses questions entourant les conséquences des commotions cérébrales ainsi qu'à accroître la compréhension générale de la physiopathologie de commotions cérébrales. Bien que les techniques de base telles que l'imagerie structurelle comme les scans TC et IRM soient incapables de détecter des changements structurels dans la grande majorité des cas (Ellemberg, Henry, Macciocchi, Guskiewicz, & Broglio, 2009; Johnston, Ptito, Chankowsky, & Chen, 2001), d'autres techniques plus précises et plus sensibles ont été en mesure de détecter avec succès des changements dans le cerveau commotionné. Des études d’IRM fonctionelle ont entre autres établi une solide relation entre les altérations fonctionnelles et les symptômes post-commotionels (Chen, Johnston, Collie, McCrory, & Ptito, 2007; Chen et al., 2004; Chen, Johnston, Petrides, & Ptito, 2008; Fazio, Lovell, Pardini, & Collins, 2007). Les mesures électrophysiologiques telles que les potentiels évoqués cognitifs (ERP) (Gaetz, Goodman, & Weinberg, 2000; Gaetz & Weinberg, 2000; Theriault, De Beaumont, Gosselin, Filipinni, & Lassonde, 2009; Theriault, De Beaumont, Tremblay, Lassonde, & Jolicoeur, 2010) et la stimulation magnétique transcrânienne ou SMT (De Beaumont, Brisson, Lassonde, & Jolicoeur, 2007; De Beaumont, Lassonde, Leclerc, & Theoret, 2007; De Beaumont et al., 2009) ont systématiquement démontré des altérations fonctionnelles chez les athlètes commotionnés. Cependant, très peu de recherches ont tenté d'explorer davantage certaines conséquences spécifiques des commotions cérébrales, entre autres sur les plans structural et métabolique. La première étude de cette thèse a évalué les changements structurels chez les athlètes commotionnés à l’aide de l'imagerie en tenseur de diffusion (DTI) qui mesure la diffusion de l'eau dans la matière blanche, permettant ainsi de visualiser des altérations des fibres nerveuses. Nous avons comparé les athlètes commotionnés à des athlètes de contrôle non-commotionnés quelques jours après la commotion et de nouveau six mois plus tard. Nos résultats indiquent un patron constant de diffusion accrue le long des voies cortico-spinales et dans la partie du corps calleux reliant les régions motrices. De plus, ces changements étaient encore présents six mois après la commotion, ce qui suggère que les effets de la commotion cérébrale persistent bien après la phase aiguë. Les deuxième et troisième études ont employé la spectroscopie par résonance magnétique afin d'étudier les changements neurométaboliques qui se produisent dans le cerveau commotionné. La première de ces études a évalué les changements neurométaboliques, les aspects neuropsychologiques, et la symptomatologie dans la phase aiguë post-commotion. Bien que les tests neuropsychologiques aient été incapables de démontrer des différences entre les athlètes commotionnés et non-commotionnés, des altérations neurométaboliques ont été notées dans le cortex préfrontal dorsolatéral ainsi que dans le cortex moteur primaire, lesquelles se sont avérées corréler avec les symptômes rapportés. La deuxième de ces études a comparé les changements neurométaboliques immédiatement après une commotion cérébrale et de nouveau six mois après l’atteinte. Les résultats ont démontré des altérations dans le cortex préfrontal dorsolatéral et moteur primaire dans la phase aiguë post-traumatique, mais seules les altérations du cortex moteur primaire ont persisté six mois après la commotion. Ces résultats indiquent que les commotions cérébrales peuvent affecter les propriétés physiques du cerveau, spécialement au niveau moteur. Il importe donc de mener davantage de recherches afin de mieux caractériser les effets moteurs des commotions cérébrales sur le plan fonctionnel. / Concussions had long been considered an injury of little to no consequence. However, the forced retirement of several high profile athletes due to the impact of having suffered multiple concussions has pushed the issue to the forefront of scientific and sports culture alike. Despite the growing public awareness and the ever-expanding scientific understanding of concussions there is still much that remains unknown about these injuries. Indeed, understanding how an injury can have such profound effects, though mostly transient, without any apparent physical consequence continues to confound how concussions are conceptualized in research. Neuroimaging techniques have helped answer many of the questions surrounding the physical consequences of concussions on the brain as well as increasing the general understanding of the pathophysiology of concussions. While basic structural imaging techniques such as CT scans and MRI are unable to detect any structural changes in the vast majority of cases (Ellemberg, et al., 2009; Johnston, et al., 2001), other more precise and sensitive techniques have been able to successfully detect changes in the concussed brain. Functional MRI studies have further established a strong relationship between functional alterations and post-concussion symptoms (Chen, et al., 2007; Chen, et al., 2004; Chen, et al., 2008; Fazio, et al., 2007). Electrophysiological measures such as ERP (Gaetz, et al., 2000; Gaetz & Weinberg, 2000; Theriault, et al., 2009; Theriault, et al., 2010) and TMS (De Beaumont, Brisson, et al., 2007; De Beaumont, Lassonde, et al., 2007; De Beaumont, et al., 2009) have consistently demonstrated alterations in concussed athletes. However, there has been very little research that has attempted to further explore the specific structural and metabolic aspects of concussion. The first study assessed structural changes in concussed athletes using diffusion tensor imaging which measures water diffusion in white matter. We compared concussed athletes with non-concussed control athletes in the days immediately after injury and again six months later. Our results indicated a consistent pattern of increased diffusion along neural tracts of the cortical spinal tract and in the corpus callosum underlying motor cortex. Furthermore, these changes were still present six months after injury suggesting that the effects of concussion are persistent past the acute phase. The second and third studies employed magnetic resonance spectroscopy as a means of investigating the neurometabolic changes that occur in the concussed brain. The first of these studies investigated the neurometabolic changes, neuropsychological aspects, and symptomatology in the acute post-injury phase. While neuropsychological testing was unable to show differences between concussed and non-concussed athletes, neurometabolic alterations were noted in the dorsal lateral prefrontal cortex as well as in primary motor cortex which correlated with reported symptoms. The second study investigated neurometabolic changes immediately after concussion and again six months after injury. Results indicated alterations in the dorsolateral prefrontal and primary motor cortices in the acute post-injury phase, but only those in primary motor cortex persisted to the six month time point.

Commotion cérébrale

Neuro-imagerie

Traumatisme axonal

Neurometabolism

Concussion

Neuroimaging

Traumatic axonal Injury

Neurometabolism

Age-dependent rAAV Mediated Reconstitution of hASPA Reveals N-acetylaspartate Regulates Fuel Selection in the Central Nervous System

Gessler, Dominic J.

08 October 2020

N-acetylaspartate (NAA) is one of the most abundant molecules in the mammalian central nervous system (CNS). The current paradigm suggests that NAA is synthesized in neurons by the enzyme N-acetyltransferase 8-like (NAT8L) and hydrolyzed into aspartate and acetate by the enzyme aspartoacylase (ASPA) in oligodendrocytes. Although the function of NAA is not well understood, several hypotheses have been proposed since its discovery several decades ago. Among the most cited theory is the concept of acetate delivery to oligodendrocytes via NAA for the synthesis of fatty acids for myelin lipids and myelination. Another concept suggests that NAA functions as a molecular water pump to remove molecular water from oxidative phosphorylation. In contrast, disruption of NAA metabolism has been associated with oxidative stress contributing to neurodegeneration, as seen in Canavan disease, a monogenic disorder associated with loss-of-function mutations in ASPA. Accumulation of NAA in the CNS and peripheral organs is pathognomonic for Canavan disease (CD) and is used clinically to diagnose this rare disease. Symptoms typically occur within months after birth and primarily manifest in the CNS with spongy degeneration of the white matter. Initially, affected patients present with poor feeding, lack of head control, hydrocephalus; later, they miss developmental milestones and develop seizures. Only supportive treatment is available possibly helping patients to survive past the first couple of years. Gene therapy has been considered early on for the treatment of CD. The first trial in humans demonstrated safety but did not result in symptomatic improvement. In addition to gene therapy for the treatment of CD, NAA has gained increasing interest in neurodegenerative and psychiatric disorders, but also in adipose tissue. Here, we are investigating the function of NAA in the context of ASPA deficiency, aka Canavan disease. We found that impaired NAA metabolism caused by ASPA mutations is characterized by a neurometabolic profile that suggests cellular shift from glucose towards fatty acid metabolism for energy production. Although, we found a similar metabolic signature in asymptomatic mice within days after birth, longitudinal comparison suggest that disease progression leads to fatty acid depletion, which is not present in asymptomatic mice, potentially challenging the concept that NAA-derived acetate is essential for lipid synthesis in the myelinating brain. Using rAAV to determine the reversibility of this metabolic phenotype, we found that early treatment prevents loss of myelin, normalizes the neurometabolic phenotype and keeps Canavan mice asymptomatic; in contrast, later treatment only allows for partial normalization of the neurometabolome, despite adequate ASPA gene delivery by rAAV, independent of ubiquitous or astrocyte-restricted hASPA expression. Furthermore, we found that non-enzymatically active hASPA might play a ubiquitous role in glucose uptake regulation in vivo. Importantly, we identified brain regions with metabolic changes that also correspond to the areas with significant histopathologic alterations. Finally, we confirmed the glycolytic changes in a Canavan disease patient cell line using Seahorse metabolic analyzer, demonstrating the decreased rate of glycolysis for energy production. Overall, our findings reveal a novel metabolic phenomenon in Canavan disease and NAA metabolism that allows to assign a novel function of N-acetylaspartate.

Canavan disease

rAAV

N-acetylaspartate

energy metabolism

central nervous system

gene therapy

neurometabolism

Nervous System Diseases

The Influence of Biomechanics on Acute Spatial and Temporal Pathophysiology Following Blast-Induced Traumatic Brain Injury

Norris, Caroline Nicole

21 June 2023

Blast-induced traumatic brain injury (bTBI) remains a significant problem among military populations. When an explosion occurs, a high magnitude positive pressure rapidly propagates away from the detonation source. Upon contact, biological tissues throughout the body undergo deformation at high strain rates and then return to equilibrium following a brief negative pressure phase. This mechanical disruption of the tissue is known to cause oxidative stress and neuroinflammation in the brain, which can lead to neurodegeneration and consequently poor cognitive and behavioral outcomes. Further, these clinical outcomes, which can include chronic headaches, problems with balance, light and noise sensitivity, anxiety, and depression, may be sustained years following blast exposure and there are currently no effective treatments. Thus, there is a need to investigate the acute molecular responses following bTBI in order to motivate the development of effective therapeutic strategies and ultimately improve or prevent long-term patient outcomes. It is important to not only understand the acute molecular response, but how the brain tissue mechanics drive these metabolic changes. The objective of this work was to identify the interplay between the tissue-level biomechanics and the acute bTBI pathophysiology. In a rodent bTBI model, using adult rats, intracranial pressure was mapped throughout the brain during blast exposure where frequency contributions from skull flexure and wave dynamics were significantly altered between brain regions and were largely dependent on blast magnitude. These findings informed the subsequent spatial and temporal changes in neurometabolism. Amino acid molecular precursor concentrations decreased at four hours post-blast in the cortex and hippocampus regions. This motivates further investigation of amino acids as therapeutic targets aimed to reduce oxidative stress and prevent prolonged injury cascades. However, neurochemical changes were not consistent across blast magnitudes, which may be explained by the disparities in biomechanics at lower blast pressures. Lastly, we investigated the acute changes in metabolic regulators influencing excitotoxicity where it was found that astrocytes maintained normal clearance of excitatory and inhibitory neurotransmitters prior to astrocyte reactivity. Outcomes of this work provide improved understanding of blast mechanics and associated acute pathophysiology and inform future therapeutic and diagnostic approaches following bTBI. / Doctor of Philosophy / Blast-induced traumatic brain injury (bTBI) remains a significant problem among military populations. When an explosion occurs, a high magnitude positive pressure wave rapidly propagates away from the detonation source. Upon contact, biological tissues throughout the body undergo deformation that can cause injury. This mechanical disruption of the tissue is known to trigger negative biological processes that lead to persistent cognitive and behavioral deficits. Further, these clinical outcomes, which can include chronic headaches, problems with balance, light and noise sensitivity, anxiety, and depression, may be sustained years following blast exposure. There are currently no effective treatments that can help those afflicted, and biomarkers for injury diagnostics are limited. Thus, there is a great need to investigate the early biological responses following bTBI in order to motivate the development of effective therapeutic strategies and ultimately improve or prevent long-term patient outcomes. It is important to not only understand the immediate responses, but also how the brain tissue mechanics drive these metabolic changes. The objective of this work was to identify the interplay between the brain biomechanics and the acute bTBI pathophysiology. Using a translational animal model, pressure inside the brain was measured with pressure sensors during blast exposure. Subsequent spatial and temporal changes in neurochemical concentrations were quantified. The results showed (1) significant disparities in the pressure dynamics inside the brain and it varied across brain regions, (2) neurochemical precursors may have therapeutic potential post-injury, and (3) biomechanical and neurochemical responses were dependent on blast severity. Outcomes of this work provide improved understanding of blast mechanics and associated pathophysiology and inform future therapeutic and diagnostic approaches to prevent prolonged injury cascades.

Traumatic Brain Injury

Blast-Induced Neurotrauma

Intracranial Pressure

Neurometabolism

Glutamine-Glutamate/GABA Cycle