Spinal cord injury is a dynamic process that evolves through two main phases: Primary injury and Secondary injury.
- Occurs at the moment of trauma. - Mechanical forces directly cause:
- Mechanisms: compression, contusion, laceration, stretch, or transection.
- Initiates within minutes to hours after trauma and can continue for days to weeks. - Complex cascade involving:
- Disruption of blood-spinal cord barrier (BSCB) - Ischemia and hypoxia - Vasospasm, thrombosis
- Activation of microglia and astrocytes - Infiltration of neutrophils, macrophages, T-cells - Release of cytokines (IL-1β, TNF-α, IL-6)
- Excessive release of glutamate - Overactivation of NMDA and AMPA receptors - Calcium influx leading to neuronal death
- Accumulation of free radicals (ROS/RNS) - Lipid peroxidation - Mitochondrial dysfunction
- Programmed cell death of neurons and oligodendrocytes - Progressive demyelination
- Reactive astrocytes produce a glial scar. - Both protective (limits spread of injury) and inhibitory (blocks axonal regeneration).
- Persistent inflammation - Cystic cavity formation - Loss of neural circuits - Limited endogenous neuroplasticity - Potential for functional reorganization through rehabilitation
Spinal cord injury pathophysiology is a multistep, multiphase process where primary mechanical damage triggers complex biological cascades leading to progressive neurological deterioration. Effective therapies aim to minimize secondary injury and promote regeneration and plasticity.
Severe spinal cord injury leads to hemorrhage, edema and elevated tissue pressures that propagate ischemia. Liquefactive necrosis of damaged tissue eventually results in chronic cavities due to a wound healing process lacking adhesive contractile cells.
Spinal cord injury induces the disruption of blood-spinal cord barrier and triggers a complex array of tissue responses, including endoplasmic reticulum (ER) stress and autophagy. However, the roles of ER stress and autophagy in blood-spinal cord barrier disruption have not been discussed in acute spinal cord trauma.
The pathophysiology of spinal cord injury (SCI) related processes of axonal degeneration and demyelination are poorly understood. The present systematic review and meta-analysis were performed such to establish quantitative results of animal studies regarding the role of injury severity, SCI models and level of injury on the pathophysiology of axon and myelin sheath degeneration. 39 related articles were included in the analysis. The compiled data showed that the total number of axons, number of myelinated axons, myelin sheath thickness, axonal conduction velocity, and internode length steadily decreased as time elapsed from the injury (Pfor trend<0.0001). The rate of axonal retrograde degeneration was affected by SCI model and severity of the injury. Axonal degeneration was higher in injuries of the thoracic region. The SCI model and the site of the injury also affected axonal retrograde degeneration. The number of myelinated axons in the caudal region of the injury was significantly higher than the lesion site and the rostral region. The findings of the present meta-analysis show that the pathophysiology of axons and myelin sheath differ in various phases of SCI and are affected by multiple factors related to the injury 1).