Brain pathology
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Review Historical Article
Multiple sclerosis pathology: evolution of pathogenetic concepts.
This historical review describes the evolution of pathogenetic concepts of multiple sclerosis (MS) from the viewpoint of pathology. MS research is based on studies of descriptive neuropathology, performed during the 19th and early-20th century, which defined the basic nature of the inflammatory demyelinating lesions. Advances in basic immunology and neurobiology, performed during the second half of the 20th century, paved the way for the understanding of the molecular mechanims involved in inflammation and well as tissue destruction in this disease. However, recent clinical and neuroradiological studies on the evolution of the disease and its brain lesions as well as ongoing attempts to define the genetic basis of the disease indicate that our current pathogenetic concepts may be too simple and that essential aspects of MS pathology have to be redefined.
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Review
Insights into the pathogenesis of hydrocephalus from transgenic and experimental animal models.
Hydrocephalus is a progressive brain disorder characterized by abnormalities in the flow of cerebrospinal fluid (CSF) and ventricular dilatation that leads to cerebral atrophy, and if left untreated, can be fatal. Genetic mutations, congenital malformations, infectious diseases, intracerebral hemorrhages and tumors are common conditions resulting in hydrocephalus. ⋯ In this regard, recent studies in transgenic (tg) mice suggest that increased expression of cytokines such as TGF-beta1 might play an important role by disrupting the vascular extracellular matrix (ECM) remodeling, promoting hemorrhages, and altering the reabsorption of CSF. In this context, the main objective of this manuscript is to provide an overview on the cellular and molecular mechanisms of hydrocephalus based on studies derived from tg and experimental animal models.
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Physiological cell death (PCD), a process by which redundant or unsuccessful neurons are deleted by apoptosis (cell suicide) from the developing central nervous system, has been recognized as a natural phenomenon for many years. Whether environmental factors can interact with PCD mechanisms to increase the number of neurons undergoing PCD, thereby converting this natural phenomenon into a pathological process, is an interesting question for which new answers are just now becoming available. In a series of recent studies we have shown that 2 major classes of drugs (those that block NMDA glutamate receptors and those that promote GABAA receptor activation), when administered to immature rodents during the period of synaptogenesis, trigger widespread apoptotic neurodegeneration throughout the developing brain. ⋯ Thus, there is a period in pre- and postnatal human development, lasting for several years, during which immature CNS neurons are prone to commit suicide if exposed to intoxicating concentrations of drugs with NMDA antagonist or GABAmimetic properties. These findings are important, not only because of their relevance to the FAS, but because there are many agents in the human environment, other than ethanol, that have NMDA antagonist or GABAmimetic properties. Such agents include drugs that may be abused by pregnant mothers (ethanol, phencyclidine [angel dust], ketamine [Special K], nitrous oxide [laughing gas], barbiturates, benzodiazepines), and many medicinals used in obstetric and pediatric neurology (anticonvulsants), and anesthesiology (all general anesthetics are either NMDA antagonists or GABAmimetics).
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Using in vitro models, our laboratory in collaboration with those of Pierluigi Nicotera (University of Konstanz, Germany) and Stan Orrenius (Karolinska Institute) has recently shown that fulminant insults to the nervous system from excitotoxins or free radicals result in neuronal cell death from necrosis, while more subtle insults result in delayed apoptosis. Over the past dozen or so years, mounting evidence has suggested that excitotoxins, such as glutamate, result in neuronal cell death after stroke. More recent evidence has suggested that in addition to necrotic cell death in the ischemic core, a number of neurons may also undergo apoptosis. ⋯ A final common pathway for neuronal susceptibility appears to be operative, similar to that observed in stroke and several neurodegenerative diseases. This mechanism involves excessive activation of N-methyl-D-aspartate (NMDA) receptor-operated channels, with resultant excessive influx of Ca2+ and the generation of free radicals, leading to neuronal damage. With the very recent development of clinically-tolerated NMDA antagonists, as discussed here, there is hope for future pharmacological intervention.