Partial interruption of axonal transport due to microtubule breakage accounts for the formation of periodic varicosities after traumatic axonal injury

Tang-Schomer, Min D.; Johnson, Victoria E.; Baas, Peter W.; Stewart, William Α.; Smith, Douglas H.

doi:10.1016/j.expneurol.2011.10.030

Cited by 284 publications

(301 citation statements)

References 34 publications

(60 reference statements)

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“…3,8,21,[27][28][29][30] In contrast, a series of swellings along otherwise intact axons represent ''axonal varicosities.'' 31 This common pathological profile found in acute TBI may reflect a process whereby transport is only partially interrupted at multiple sites along the axon's length, producing the string-of-beads appearance, in contrast with presumed complete interruption at one site forming singular axonal bulbs. 3,11,24,31 Typically in humans, reactive axonal swellings can be recognized within the first hours post-injury as large focal axonal swellings 10-20 lm in diameter that expand in size over 24-48 h reaching up to approximately 50 lm.…”

Section: Histopathological Identification Of Daimentioning

confidence: 99%

“…31 This common pathological profile found in acute TBI may reflect a process whereby transport is only partially interrupted at multiple sites along the axon's length, producing the string-of-beads appearance, in contrast with presumed complete interruption at one site forming singular axonal bulbs. 3,11,24,31 Typically in humans, reactive axonal swellings can be recognized within the first hours post-injury as large focal axonal swellings 10-20 lm in diameter that expand in size over 24-48 h reaching up to approximately 50 lm. 1,3,8,15,18,25,32 During this time, both axonal bulbs and varicosities are often observed together in various ratios, presumably reflecting the different rates of swelling and progression toward disconnection in individual injured axons.…”

Section: Histopathological Identification Of Daimentioning

confidence: 99%

“…During normal daily activities, axons are supple and can accommodate substantial mechanical deformation, such as stretching. 8,31,58,61 Indeed, under quasistatic loading conditions, axons can easily be stretched for over 100% of their original length and spring back without any evidence of structural or functional failure. 61 Constituents of axons, however, are thought to become brittle under very rapid mechanical loading conditions, predisposing vulnerable structures in the axolemma and/or axoplasm to mechanical damage, typically occurring at discrete points along the axon's length.…”

Section: Biomechanics Of Daimentioning

confidence: 99%

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Therapy Development for Diffuse Axonal Injury

Smith

Hicks

Povlishock

2013

Journal of Neurotrauma

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169

146

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Diffuse axonal injury (DAI) remains a prominent feature of human traumatic brain injury (TBI) and a major player in its subsequent morbidity. The importance of this widespread axonal damage has been confirmed by multiple approaches including routine postmortem neuropathology as well as advanced imaging, which is now capable of detecting the signatures of traumatically induced axonal injury across a spectrum of traumatically brain-injured persons. Despite the increased interest in DAI and its overall implications for brain-injured patients, many questions remain about this component of TBI and its potential therapeutic targeting. To address these deficiencies and to identify future directions needed to fill critical gaps in our understanding of this component of TBI, the National Institute of Neurological Disorders and Stroke hosted a workshop in May 2011. This workshop sought to determine what is known regarding the pathogenesis of DAI in animal models of injury as well as in the human clinical setting. The workshop also addressed new tools to aid in the identification of this axonal injury while also identifying more rational therapeutic targets linked to DAI for continued preclinical investigation and, ultimately, clinical translation. This report encapsulates the oral and written components of this workshop addressing key features regarding the pathobiology of DAI, the biomechanics implicated in its initiating pathology, and those experimental animal modeling considerations that bear relevance to the biomechanical features of human TBI. Parallel considerations of alternate forms of DAI detection including, but not limited to, advanced neuroimaging, electrophysiological, biomarker, and neurobehavioral evaluations are included, together with recommendations for how these technologies can be better used and integrated for a more comprehensive appreciation of the pathobiology of DAI and its overall structural and functional implications. Lastly, the document closes with a thorough review of the targets linked to the pathogenesis of DAI, while also presenting a detailed report of those target-based therapies that have been used, to date, with a consideration of their overall implications for future preclinical discovery and subsequent translation to the clinic. Although all participants realize that various research gaps remained in our understanding and treatment of this complex component of TBI, this workshop refines these issues providing, for the first time, a comprehensive appreciation of what has been done and what critical needs remain unfulfilled.

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Section: Histopathological Identification Of Daimentioning

confidence: 99%

Section: Histopathological Identification Of Daimentioning

confidence: 99%

Section: Biomechanics Of Daimentioning

confidence: 99%

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Therapy Development for Diffuse Axonal Injury

Smith

Hicks

Povlishock

2013

Journal of Neurotrauma

Self Cite

169

146

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“…FAS can lead to a remarkable 30-fold increase in axon diameter [29,30]. Additionally, recent works demonstrate that critical changes in axonal morphology can impair the underlying spike train propagation responsible for encoding information in neural activity.…”

Section: Modeling Injurious Effects Of Fasmentioning

confidence: 99%

“…But even in mild TBI, injured axons undergo changes culminating in FAS [6,7,[25][26][27][28]. FAS can lead to dramatic changes in axon diameters, potentially interrupting axonal transport [29,30] and/or significantly impairing the underlying spike train propagation responsible for encoding information in neural activity [8][9][10]31].…”

Section: Introductionmentioning

confidence: 99%

Cognitive and behavioral deficits arising from neurodegeneration and traumatic brain injury: a model for the underlying role of focal axonal swellings in neuronal networks with plasticity

Rudy¹,

Maia²,

Kutz³

2016

J Integr Syst Neurosci

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Neurodegenerative diseases and traumatic brain injury, whose hallmark features are the presence of focal axonal swellings (FAS), are leading causes of cognitive dysfunction. By leveraging biophysical observations of FAS statistics, we develop a theoretical model of functional neural network activity driven by adaptive changes from plasticity. Based upon the FORCE model of Sussillo and Abbott [1], our innovations highlight the role of plasticity in overcoming injuries and degeneration of neurons in a network architecture. We provide a quantitative measure, on a network level, of cognitive deficits arising from injury. We demonstrate that plasticity is capable of overcoming mild injuries while failing to compensate for more severe injuries. Such injuries are characterized by their underlying effect on spike trains propagating through the neurons in a network architecture. Specifically, spike trains can be filtered in firing rate, or blocked under more severe FAS. The level of injury dictates the FORCE model's ability to produce a desired output functionality (and associated behavior) and allows for quantitative metrics for accessing cognitive and behavioral deficits. Thus a direct link between FAS in neural networks and compromised functional response can be established. The theoretical framework developed is a promising computational framework for providing a deeper understanding of the cognitive deficits arising in, for instance, Alzheimer's, Parkinson's, Multiple-Sclerosis, and TBI.

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The cytoskeleton as a modulator of tension driven axon elongation

Sousa

2020

Developmental Neurobiology

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Throughout development, neurons are capable of integrating external and internal signals leading to the morphological changes required for neuronal polarization and axon growth. The first phase of axon elongation occurs during neuronal polarization.At this stage, membrane remodeling and cytoskeleton dynamics are crucial for the growth cone to advance and guide axon elongation. When a target is recognized, the growth cone collapses to form the presynaptic terminal. Once a synapse is established, the growth of the organism results in an increased distance between the neuronal cell bodies and their targets. In this second phase of axon elongation, growth cone-independent molecular mechanisms and cytoskeleton changes must occur to enable axon growth to accompany the increase in body size. While the field has mainly focused on growth-cone mediated axon elongation during development, tension driven axon growth remains largely unexplored. In this review, we will discuss in a critical perspective the current knowledge on the mechanisms guiding axon growth following synaptogenesis, with a particular focus on the putative role played by the axonal cytoskeleton.

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Partial interruption of axonal transport due to microtubule breakage accounts for the formation of periodic varicosities after traumatic axonal injury

Cited by 284 publications

References 34 publications

Therapy Development for Diffuse Axonal Injury

Therapy Development for Diffuse Axonal Injury

Cognitive and behavioral deficits arising from neurodegeneration and traumatic brain injury: a model for the underlying role of focal axonal swellings in neuronal networks with plasticity

The cytoskeleton as a modulator of tension driven axon elongation

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