Neuroscience
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Regulation of the extracellular matrix by proteases and protease inhibitors is a fundamental biological process for normal growth, development and repair in the CNS. Matrix metalloproteinases (MMPs) and the tissue inhibitors of metalloproteinases (TIMPs) are the major extracellular-degrading enzymes. Two other enzyme families, a disintegrin and metalloproteinase (ADAM), and the serine proteases, plasminogen/plasminogen activator (P/PA) system, are also involved in extracellular matrix degradation. ⋯ There are several key MMPs and ADAMs that have been implicated in neuroinflammation: gelatinases A and B (MMP-2 and -9), stromelysin-1 (MMP-3), membrane-type MMP (MT1-MMP or MMP-14), and tumor necrosis factor-alpha converting enzyme (TACE). In addition, TIMP-3, which is bound to the cell surface, promotes cell death and impedes angiogenesis. Inhibitors of metalloproteinases are available, but balancing the beneficial and detrimental effects of these agents remains a challenge.
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Activation of the complement system occurs in a variety of neuroinflammatory diseases and neurodegenerative processes of the CNS. Studies in the last decade have demonstrated that essentially all of the activation components and receptors of the complement system are produced by astrocytes, microglia, and neurons. There is also rapidly growing evidence to indicate an active role of the complement system in cerebral ischemic injury. ⋯ Intravenous immunoglobulin (IVIG) has the potential to inhibit multiple components of inflammation, including complement fragments, pro-inflammatory cytokine production and leukocyte cell adhesion. Thus, IVIG may directly protect neurons, reduce activation of intrinsic inflammatory cells (microglia) and inhibit transendothelial infiltration of leukocytes into the brain parenchyma following an ischemic stroke. The striking neuroprotective actions of IVIG in animal models of ischemic stroke suggest a potential therapeutic potential that merits consideration for clinical trials in stroke patients.
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Extensive evidence implicates inflammation in multiple phases of stroke etiology and pathology. In particular, there is growing awareness that inflammatory events outside the brain have an important impact on stroke susceptibility and outcome. ⋯ Here, we provide an overview of the impact of systemic inflammation on stroke susceptibility and outcome. We discuss potential mechanisms underlying the impact on ischemic brain injury and highlight the implications for stroke prevention, therapy and modeling.
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Review
Imaging of inflammation in the peripheral and central nervous system by magnetic resonance imaging.
Inflammation plays a central role in the pathophysiology of numerous disorders of the nervous system, but is also pivotal for repair processes like peripheral nerve regeneration. In this review we summarize recent advances in cellular magnetic resonance imaging (MRI) while nuclear imaging methods to visualize neuroinflammation are covered by Wunder et al. [Wunder A, Klohs J, Dirnagl U (2009) Non-invasive imaging of central nervous system inflammation with nuclear and optical imaging. Neuroscience, in press]. ⋯ Iron oxide-contrast-enhanced MRI allowed in vivo visualization of cellular inflammation during wallerian degeneration, experimental autoimmune neuritis and encephalomyelitis, and stroke in rodents, but also in patients with multiple sclerosis and stroke. Importantly, cellular MRI provides additional information to gadolinium-DTPA-enhanced MRI since cellular infiltration and breakdown of the blood-brain barrier are not closely linked. Coupling of antibodies to iron oxide particles opens new avenues for molecular MRI and has been successfully used to visualize cell adhesion molecules guiding inflammation.
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Following injury to the nervous system, the activation of macrophages, microglia, and T-cells profoundly affects the ability of neurons to survive and to regenerate damaged axons. The primary visual pathway provides a well-defined model system for investigating the interactions between the immune system and the nervous system after neural injury. ⋯ T cells modulate this response, whereas microglia are thought to contribute to the loss of retinal ganglion cells in this model and in certain ocular diseases. This review discusses the complex and sometimes paradoxical actions of blood-borne macrophages, resident microglia, and T-cells in determining the outcome of injury in the primary visual pathway.