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Adventures in the
Pathophysiology of Brain Ischemia: Penumbra, Gene Expression, Neuroprotection:
The 2002 Thomas Willis Lecture.
Ginsberg
MD.
Stroke 2003 Jan
1;34(1):214-223
Cerebral Vascular Disease Research Center,
Department of Neurology, University of Miami School of Medicine, Miami,
Fla.
BACKGROUND: The pathophysiology of cerebral ischemia is well studied
in small-animal models, which offer reproducibility and control of confounding
variables-factors essential to hypothesis-testing. This presentation first
highlights insights into the ischemic penumbra enabled by a multimodal
experimental approach; second, discusses gene expression in ischemia; and third,
confronts the challenges of neuroprotectant therapy. Summary of Review- The
ischemic penumbra: Transient (2-hour) middle cerebral artery suture-occlusion in
anesthetized rats gives rise to highly consistent neurological and
histopathological sequelae. Autoradiographic local cerebral blood flow (LCBF)
studies at 2 hours of occlusion define the penumbra as a region of intermediate
CBF depression (20% to 40% of control) surrounding the densely ischemic core (5%
to 20% of control) and constituting one half of the entire lesion. Local glucose
metabolic rate in the acute penumbra is not reduced despite the critical CBF
reduction, so that the penumbral metabolism/blood flow ratio is markedly
elevated. In contrast, following 1 hour of recirculation, glucose metabolism
throughout the previously ischemic hemisphere has become markedly depressed, and
the metabolism/flow ratio has pseudonormalized. By correlating these data with
histopathology using multimodal image analysis, the probability of infarction is
shown to be highly determined by the degree of antecedent CBF reduction. These
animal data agree strikingly with published results in patients with acute
stroke studied by positron emission tomography. This remarkable correspondence
belies the assertion that data from lower species may not be relevant to human
stroke. Gene expression: Perfusion gradients also determine differential
patterns of gene expression in ischemia. This can be demonstrated by correlating
in situ hybridization autoradiographs for gene expression with autoradiographic
LCBF data and histological infarct maps derived from replicate series. In other
studies, DNA microarray technology is used to screen for thousands of expressed
genes. In the 2-hour middle cerebral artery occlusion model with 3-hour
recirculation, we have identified 28 known ischemia-hypoxia response genes that
are upregulated and 6 that are downregulated, together with 35 upregulated and
41 downregulated genes newly connected with ischemia. These findings underscore
the enormous complexity of ischemic biology and suggest possible novel
mechanisms for future exploration. NEUROPROTECTION: A desirable neuroprotectant
would, in theory, antagonize multiple injury mechanisms. We have explored 2 such
therapies of particular promise. Mild brain hypothermia (32 degrees C target
temperature, for 5 hours) is highly neuroprotective even when initiated at the
onset of recirculation. Another highly protective agent is human albumin,
administered in doses of 1.25 to 2.5 g/kg-a therapy that reduces infarct volume
in this ischemia model by 60% to 65%, markedly diminishes brain swelling, and
has a therapeutic window extending to 4 hours. CONCLUSION: The careful study of
rodent ischemia models can yield valuable, clinically relevant insights into the
pathophysiology of ischemic stroke.
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