J. Todd Ottman scite author profile

J. Todd Ottman

2Publications

50Citation Statements Received

54Citation Statements Given

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University of Oklahoma Health Sciences Center

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Structural Changes in Alzheimers Disease Brain Microvessels

Christov

Ottman²,

Hamdheydari³

et al. 2008

CAR

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Brain microvascular alterations are thought to contribute to the development of stroke and dementia. Structural changes in capillaries of elderly patients correlate positively with advanced age and dementia. The objective of this study is to use laser-induced fluorescence spectroscopy to compare structural (collagen content) and functional (apoptosis) parameters in brain tissues and isolated vessels of AD patients to age-matched controls. Our results show significantly higher fluorescent labeling for apoptosis in AD vessels compared to controls. Also, there is significantly higher autofluorescence (reflecting levels of collagen and other proteins that autofluoresce) in AD brain and vessels compared to controls. Western blot analysis of collagen subtypes shows elevated type I and type III and reduced type IV levels in AD vessels. These data demonstrate that changes in the amount and type of collagen occur in AD brain and suggest that cerebral vessel injury is part of AD pathology.

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Vascular inflammatory, oxidative and protease-based processes: implications for neuronal cell death in Alzheimer's disease

Christov

Ottman

Grammas

2004

Neurological Research

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A substantial literature demonstrates activation of inflammatory processes in the Alzheimer's disease (AD) brain and an association between inflammation and oxidative stress. We have shown that brain microvessels from AD patients express high levels of inflammatory proteins and that these proteins evoke release of the neurotoxic protease thrombin from brain endothelial cells. The objective of this study was to determine the effects of inflammatory proteins on brain endothelial cell reactive oxygen species generation, protease release and cell apoptosis. Also, the effects of inflammatory proteins on neuronal reactive oxygen species generation, injury and apoptosis were assessed. Treatment of cultured brain endothelial cells with inflammatory proteins (LPS, IL-1beta, IL-6, IFN-gamma, TNF-alpha) resulted in a significant increase (p < 0.01) in intracellular levels of reactive oxygen species by 1 h. Inflammatory proteins also caused release of tissue plasminogen activator and increased apoptosis by 24 h in these cells. In cultured neurons, inflammatory proteins caused an increase in reactive oxygen species, membrane fluidity, and apoptosis by 24 h, as detected by fluorescent microscopy. Taken together, these data support the hypothesis that vascular inflammatory, oxidative and protease-based processes contribute to neuronal cell death, and suggest that therapies targeted at these mediators and processes could be effective in AD.

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J. Todd Ottman

Structural Changes in Alzheimers Disease Brain Microvessels

Vascular inflammatory, oxidative and protease-based processes: implications for neuronal cell death in Alzheimer's disease

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