The immunophilin ligand, cyclosporin A (CsA), is effective in reducing the axonal damage associated with traumatic brain injury (TBI). Based upon extensive ultrastructural and immunohistochemical studies, the neuroprotection afforded by CsA appeared to be mediated via mitochondrial protection, specifically, the prevention of mitochondrial swelling and inhibition of mitochondrial permeability transition (MPT). However, the potential that CsA could also be neuroprotective via the immunophilin-mediated inhibition of the protein phosphatase, calcineurin (CN) has not been directly assessed. To address this issue, the current study assessed the ability of FK506, another immunophilin ligand that inhibits CN with no effect on MPT, to attenuate axonal damage in a rat impact-acceleration model of TBI. Traumatic axonal injury (TAI), detected via an antibody against beta-amyloid precursor protein (APP), a specific marker of axonal injury, was significantly reduced at 24 hr postinjury in Sprague-Dawley rats receiving intravenous FK506 (2 mg/kg; n = 5) 30 min prior to injury compared to vehicle controls (n = 3). While not rejecting the established efficacy of CsA in providing neuroprotection via its targeting of MPT, this study does underscore the potential importance of CN in the progressive pathobiology of TAI, suggesting that CN may constitute another important therapeutic target.
Cyclosporin A has emerged as a promising therapeutic agent in traumatic brain injury (TBI), although its precise neuroprotective mechanism is unclear. Cyclosporin A, given as a single-dose intrathecal bolus, has previously been shown to attenuate mitochondrial damage and reduce axonal injury in experimental TBI. We assessed the effect of a range of intravenous cyclosporin A doses upon axonal injury attenuation to determine the ideal dose. Rats were subjected to experimental TBI and given one of five intravenous doses of cyclosporin A. At 3 h post-injury, brains were processed for brain tissue cyclosporin A concentration. In a second set of animals, at 24 h postinjury, brains were processed for amyloid precursor protein immunoreactivity, a widely used marker of axonal injury. Intravenous administration produced therapeutic levels of cyclosporin A in brain parenchyma. Higher concentrations were achieved with equivalent doses given intrathecally; this is consistent with the reported poor blood-brain barrier permeability of cyclosporin A. Cyclosporin A 10 mg/kg i.v. produced the greatest degree of neuroprotection against diffuse axonal injury; cyclosporin A 50 mg/kg i.v. was toxic. Intravenous cyclosporin A administration achieves therapeutic levels in brain parenchyma and 10 mg/kg is the most effective dose in attenuating axonal damage after traumatic brain injury.
This article provides a review of immunology to enhance understanding of vaccine efficacy and use, and elaborates on the immune response to vaccination. The use of vaccines to prevent infectious diseases represents a tremendous accomplishment of biomedical science, especially considering the complex interplay of the immune system with innumerable pathogens. Vaccines have allowed for total eradication of one disease and have significantly reduced the incidence of other diseases. In order to have a successful vaccine-based eradication program, the infection must be limited to humans without an animal reservoir and only one or a few strains may exist in viral infection. These strains must have constant antigenic properties. A number of vaccine types exist, both traditional and innovative, and are described herein.
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