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(Stroke. 2008;39:1380.)
© 2008 American Heart Association, Inc.

Topical Review

Themes and Strategies for Studying the Biology of Stroke Recovery in the Poststroke Epoch

From the Department of Neurology, David Geffen School of Medicine at UCLA, Los Angeles, Calif.

Correspondence to S. Thomas Carmichael, MD, PhD, Associate Professor, Department of Neurology, David Geffen School of Medicine at UCLA, Neuroscience Research Building, 710 Westwood Plaza, Los Angeles, CA 90095. E-mail scarmichael{at}mednet.ucla.edu

Rajiv Ratan MD, PhD Lalit Kalra MD, PhD Section Editors:

Background and Purpose— This review will focus on the emerging principles of neural repair after stroke, and on the overlap between cellular mechanisms of neural repair in stroke and clinical principles of recovery and rehabilitation.

Summary of Review—Stroke induces axonal sprouting and neurogenesis. Axonal sprouting occurs in tissue adjacent to the stroke and its connected cortical areas, and from sites that are contralateral to the infarct. Neurogenesis produces newly born immature neurons in peri-infarct striatum and cortex. Stimulation of both axonal sprouting and neurogenesis is associated with improved recovery in animal models of stroke. A unique cellular environment in the poststroke brain supports neural repair: an association of angiogenic and remodeling blood vessels with newly born immature neurons in a neurovasclar niche. Controversies in the field of neural repair after stroke persist, and relate to the locations of axonal sprouting in animal models of stroke and how these correlate to patterns of human remapping and recovery, and to the different models of stroke used in studies of neurogenesis.

Conclusions— On a cellular level, the phenomenology of neural repair after stroke has been defined and unique regenerative environments in the poststroke brain identified. As the field moves toward specific studies of causal mechanisms in poststroke repair, it will need to maintain a perspective of the animal models suited to the study of neural repair after stroke as they relate to the patterns of recovery in humans in this disease.

Key Words: axonal sprouting • regeneration • neurogenesis • neurorehabilitation • angiogenesis

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