The recent developments in the management of spinal cord injury (SCI) have led to a reduction in mortality and in the consequences, resulting from incomplete spinal cord damage in those who survive. In this respect, it is noteworthy that SCI not only results in paraplegia or tetraplegia, but also in systemic, cardiovascular and metabolic alterations secondary to autonomic dysfunction. After SCI there is a decrease in sympathetic discharge and an increase in parasympathetic drive, resulting in profound changes in arterial blood pressure and heart rate. When SCI is induced in experimental animals, an immediate hypotension occurs (acute phase) which has been attributed to an autonomic imbalance involving a predominance of parasympathetic activity. Subsequently, an episodic hypertension may develop (chronic phase) as a part of a condition denominated autonomic dysreflexia. This hypertension is caused by afferent stimulation below the level of injury and can be so severe that sometimes may lead to cerebral haemorrhage, seizures, and death. In the light of the above lines of evidence, experimental SCI may provide an ideal model to study the nature of cardiovascular mechanisms following traumatic injury. Thus, the present review will deal with an update of the possible cardiovascular complications associated to SCI (including spinal shock, autonomic dysreflexia, deep venous thrombosis, and risk for coronary heart disease). This will be discussed within the context of the development of drugs with potential therapeutic usefulness in the acute and chronic stages of SCI.
After damage to the central nervous system (CNS) the body is protected by an adaptive immune response which is directed against myelin-associated proteins. Active immunization with nonpathogenic derivatives of CNS-associated peptides (DCAP) reduces the degeneration of neurons and promotes motor recovery after spinal cord injury (SCI) in rats. In order to improve even more the neurological outcome obtained with this therapy, either a combination of DCAP immunization plus glutathione monoethyl ester (GSHE) or a double DCAP immunization were performed. GSHE is a cell-permeant derivative of glutathione, a potent antioxidant agent that significantly inhibits lipid peroxidation after SCI. After a contusive or compressive SCI, the combination of GSHE + DCAP immunization, induced better motor recovery, a higher number of myelinated axons and better rubrospinal neuron survival than immunization alone. On the other hand, double-DCAP immunization counteracted the protective effect of DCAP therapy. Motor recovery and neuronal survival of double-immunized rats were similar to those observed in control animals (PBS-treated). Further studies revealed that double immunization was not encephalitogenic but inhibited the proliferative response of T-cells specific to the DCAP-immunized peptide. This clonal dysfunction was probably secondary to anergy. GSHE improves the protective effect induced by DCAP immunization while double immunization, reverts it.
The authors postulate that MIFNES is a good alternative for the management of intraventricular and subarachnoid basal cisterns NCC because it allows removal of most of the parasites, rapid recovery of the patients, and removal and placement of shunt under direct vision when necessary. Traditional treatment is a second option where the MIFNES procedure is not available.
Spinal cord injury (SCI) is an incapacitating condition that affects motor, sensory, and autonomic functions. Since 1990, the only treatment administered in the acute phase of SCI has been methylprednisolone (MP), a synthetic corticosteroid that has anti-inflammatory effects; however, its efficacy remains controversial. Although MP has been thought to help in the resolution of edema, there are no scientific grounds to support this assertion. Aquaporin 4 (AQP4), the most abundant component of water channels in the CNS, participates in the formation and elimination of edema, but it is not clear whether the modulation of AQP4 expression by MP plays any role in the physiopathology of SCI. We studied the functional expression of AQP4 modulated by MP following SCI in an experimental model in rats along with the associated changes in the permeability of the blood-spinal cord barrier. We analyzed these effects in male and female rats and found that SCI increased AQP4 expression in the spinal cord white matter and that MP diminished such increase to baseline levels. Moreover, MP increased the extravasation of plasma components after SCI and enhanced tissue swelling and edema. Our results lend scientific support to the increasing motion to avoid MP treatment after SCI.
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