Journal of neurotrauma
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Journal of neurotrauma · Nov 2011
Rate of neurodegeneration in the mouse controlled cortical impact model is influenced by impactor tip shape: implications for mechanistic and therapeutic studies.
Controlled cortical impact (CCI), one of the most common models of traumatic brain injury, is being increasingly used with mice for exploration of cell injury mechanisms and pre-clinical evaluation of therapeutic strategies. Although CCI brain injury was originally effected using an impactor with a rounded tip, the majority of studies with mouse CCI use a flat or beveled tip. Recent finite element modeling analyses demonstrate that tip geometry is a significant determinant of predicted cortical tissue strains in rat CCI, and that cell death is proportional to predicted tissue strains. ⋯ The flat-tip impactor was associated in general with more regional hippocampal neurodegeneration, especially at early time points such as 4?h. Impactor tip geometry did not have a notable effect on blood?brain barrier breakdown, traumatic axonal injury, or motor and cognitive dysfunction. Execution of CCI injury with a rounded-tip impactor is posited to provide a substantially enhanced temporal window for the study of cellular injury mechanisms and therapeutic intervention while maintaining critical aspects of the pathophysiological response to contusion brain injury.
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Journal of neurotrauma · Nov 2011
Case Reports Comparative StudyComparison of acute and chronic traumatic brain injury using semi-automatic multimodal segmentation of MR volumes.
Although neuroimaging is essential for prompt and proper management of traumatic brain injury (TBI), there is a regrettable and acute lack of robust methods for the visualization and assessment of TBI pathophysiology, especially for of the purpose of improving clinical outcome metrics. Until now, the application of automatic segmentation algorithms to TBI in a clinical setting has remained an elusive goal because existing methods have, for the most part, been insufficiently robust to faithfully capture TBI-related changes in brain anatomy. This article introduces and illustrates the combined use of multimodal TBI segmentation and time point comparison using 3D Slicer, a widely-used software environment whose TBI data processing solutions are openly available. ⋯ The proposed tools allow cross-correlation of multimodal metrics from structural imaging (e.g., structural volume, atrophy measurements) with clinical outcome variables and other potential factors predictive of recovery. In addition, the workflows described are suitable for TBI clinical practice and patient monitoring, particularly for assessing damage extent and for the measurement of neuroanatomical change over time. With knowledge of general location, extent, and degree of change, such metrics can be associated with clinical measures and subsequently used to suggest viable treatment options.
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Journal of neurotrauma · Nov 2011
Microfluidic generation of haptotactic gradients through 3D collagen gels for enhanced neurite growth.
We adapted a microfluidic system used previously to generate durotactic gradients of stiffness in a 3D collagen gel, to produce haptotactic gradients of adhesive ligands through the collagen gel. Oligopeptide sequences that included bioactive peptide sequences from laminin, YIGSR, or IKVAV, were grafted separately onto type I collagen using 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC). Solutions of peptide-grafted collagen and untreated collagen were then used as source and sink input solutions, respectively, in an H-shaped microfluidic network fabricated using traditional soft lithography. ⋯ When these two gradients were presented in combination, the bias in growth acceleration was the largest and most consistent. No differences were observed in the number of neurites choosing to grow up or down the gradients in any condition. These results suggest that the incorporation of distinct gradients of multiple bioactive ligands can improve directional acceleration of regenerating axons.
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Journal of neurotrauma · Nov 2011
Comparative StudyEngineered in vitro/in silico models to examine neurite target preference.
Research on spinal cord injury (SCI) repair focuses on developing mechanisms to allow neurites to grow past an injury site. In this article, we observe that numerous divergent paths (i.e., spinal roots) are present along the spinal column, and hence guidance strategies must be devised to ensure that regrowing neurites reach viable targets. ⋯ We find in both in silico and in vitro models that the probability of a neurite entering a given root decreases exponentially with respect to the number of roots away from the DRG; consequently, the likelihood of neurites reaching a distant root can be vanishingly small. This result represents a starting point for future strategies to optimize the likelihood that neurites will reach appropriate targets in the regenerating nervous system, and provides a new computational tool to evaluate the feasibility and expected success of neurite guidance in complex geometries.