Abstract
A mechanical trauma to the spinal cord can be followed by the development of irreversible and progressive neurodegeneration, as opposed to a temporary or partially reversible neurological damage. An increasing body of experimental and clinical evidence from humans and animal models indicates that spinal cord injury may set in motion the development of disabling and at times fatal neuromuscular disorders, whose occurrence is not normally associated with any major environmental event. This outcome appears to be dependent on the co-occurrence of a particular form of mechanical stress and of a genetically-determined vulnerability. This increased vulnerability to spinal cord injury may depend on a change of the nature and of the timing of activation of a number of neuroprotective and neurodestructive molecular signals in the injured cord. Among the main determinants, we could mention an altered homeostasis of lipids and neurofilaments, an earlier inflammatory response and the failure of the damaged tissue to rein in oxidative damage and apoptotic cell death. These changes could force injured tissue beyond a point of no return and precipitate an irreversible neurodegenerative process. A better knowledge of the molecular signals activated in a state of increased vulnerability to trauma can inform future treatment strategies and the prediction of the neurological outcome after spinal cord injury. © 2012 Yip and Malaspina; licensee BioMed Central Ltd.
Figures
![Figure 1 Differentially regulated genes that become activated or inhibited within the first few hours from injury, reported as early injury genes. Examples of molecular responses (pathways) identified in normal rodent spinal cord after mechanical injury, according to the pathway analysis of recent transcriptomic studies of SCI [28,29]. We report information regarding the functional and neuropathological effects that each reported gene may have, based on an overview of published data. The nature of the differential regulation and the location of the transcriptional change with regard to the epicenter of injury are also reported. Blue color indicates an increase in gene expression. Red color indicates a decrease in gene expression. References: 1; Aimone et al., ‘04, 2; Bareyre et al., ‘02, 3; Carmel et al., ‘01, 4; Di Giovanni et al., ‘03, 5; Malaspina et al., ‘08, 6; Nesic et al., ‘02; 7; Pan et al., ‘02; 8; Resnick et al., ‘04; 9; Schmitt et al., ‘06, 10; Song et al., ‘01.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/bb48a684-ffe0-3c93-b21a-54c4edabac91/thumbnail-4db2b44d-b13a-45e2-a65f-134f4f6e470f-0.png)
![Figure 2 Differentially regulated genes that appear to have a delayed response which become activated or inhibited more than 2 days from the trauma, reported as late injury genes. Examples of molecular responses (pathways) identified in normal rodent spinal cord after mechanical injury, according to the pathway analysis of recent transcriptomic studies of SCI [28,29]. We report information regarding the functional and neuropathological effects that each reported gene may have, based on an overview of published data. The nature of the differential regulation and the location of the transcriptional change with regard to the epicenter of injury are also reported. Blue color indicates an increase in gene expression. Red color indicates a decrease in gene expression. References: 2; Bareyre et al., ‘02, 11; Fan et al., ‘01, 12; Jokic et al., ‘10.](https://s3-eu-west-1.amazonaws.com/com.mendeley.prod.article-extracted-content/images/bb48a684-ffe0-3c93-b21a-54c4edabac91/thumbnail-bfcac06b-c16d-4df6-87d5-4395ae096c46-1.png)
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