News Release

USF researchers find far-reaching, microvascular damage in uninjured side of brain after stroke

Findings suggest that blood-brain barrier integrity suffers days after ischemic stroke, leading to serious complications; repair of this protective barrier might prevent them

Peer-Reviewed Publication

University of South Florida (USF Health)

Svitlana Garbuzova-Davis, University of South Florida

image: Neuroscientist Svitlana Garbuzova-Davis, Ph.D., University of South Florida, was lead author of the study looking at brain deficits in the subacute phase of stroke. view more 

Credit: © University of South Florida

Tampa, FL (May 20, 2013) -- While the effects of acute stroke have been widely studied, brain damage during the subacute phase of stroke has been a neglected area of research. Now, a new study by the University of South Florida reports that within a week of a stroke caused by a blood clot in one side of the brain, the opposite side of the brain shows signs of microvascular injury.

Stroke is a leading cause of death and disability in the United States, and increases the risk for dementia.

"Approximately 80 percent of strokes are ischemic strokes, in which the blood supply to the brain is restricted, causing a shortage of oxygen," said study lead author Svitlana Garbuzova-Davis, PhD, associate professor in the USF Department of Neurosurgery and Brain Repair. "Minutes after ischemic stroke, there are serious effects within the brain at both the molecular and cellular levels. One understudied aspect has been the effect of ischemic stroke on the competence of the blood-brain barrier and subsequent related events in remote brain areas."

Using a rat model, researchers at USF Health investigated the subacute phase of ischemic stroke and found deficits in the microvascular integrity in the brain hemisphere opposite to where the initial stroke injury occured.

The study was published in the May 10, 2013 issue of PLOS One.

The USF team found that "diachisis," a term used to describe certain brain deficits remote from primary insult, can occur during the subacute phase of ischemic stroke. The research discovered diachisis is closely related to a breakdown of the blood-brain barrier, which separates circulating blood from brain tissue.

In the subacute phase of an ischemic stroke, when the stroke-induced disturbances in the brain occur in remote brain microvessels, several areas of the brain are affected by a variety of injuries, including neuronal swelling and diminished myelin in brain structures. The researchers suggest that recognizing the significance of microvascular damage could make the blood-brain barrier (BBB) a therapeutic "target" for future neuroprotective strategies for stroke patients.

The mechanisms of BBB permeability at different phases of stroke are poorly understood. While there have been investigations of BBB integrity and processes in ischemic stroke, the researchers said, most examinations have been limited to the phase immediately after stroke, known as acute stroke. Their interest was in determining microvascular integrity in the brain hemisphere opposite to an initial stroke injury at the subacute phase.

Accordingly, this study using rats with surgically-simulated strokes was designed to investigate the effect of ischemic stroke on the BBB in the subacute phase, and the effects of a compromised BBB upon various brain regions, some distant from the stroke site.

"The aim of this study was to characterize subacute diachisis in rats modeled with ischemic stroke," said co-author Cesar Borlongan, PhD, professor and vice chairman for research in the Department of Neurosurgery and Brain Repair and director of the USF Center for Aging and Brain Repair. "Our specific focus was on analyzing the condition of the BBB and the processes in the areas of the brain not directly affected by ischemia. BBB competence in subacute diachisis is uncertain and needed to be studied."

Their findings suggest that damage to the BBB, and subsequent vascular leakage as the BBB becomes more permeable, plays a major role in subacute diachisis.

The increasing BBB permeability hours after the simulated stroke, and finding that the BBB "remained open" seven days post-stroke, were significant findings, said Dr. Garbuzova-Davis, who is also a researcher in USF Center for Aging and Brain Repair. "Since increased BBB permeability is often associated with brain swelling, BBB leakage may be a serious and life-threatening complication of ischemic stroke."

Another significant aspect was the finding that autophagy -- a mechanism involving cell degradation of unnecessary or dysfunctional cellular components --plays a role in the subacute phase of ischemia. Study results showed that accumulation of numerous autophagosomes within endothelial cells in microvessels of both initially damaged and non-injured brain areas might be closely associated with BBB damage.

Autophagy is a complex but normal process usually aimed at "self-removing" damaged cell components to promote cell survival. It was unclear, however, whether the role of autophagy in subacute post-ischemia was promoting cell survival or cell death.

More than 30 percent of patients who survive strokes develop dementia within two years, the researchers noted.

"Although dementia is complex, vascular damage in post-stroke patients is a significant risk factor, depending on the severity, volume and site of the stroke," said study co-author Dr. Paul Sanberg, USF senior vice president for research and innovation. "Ischemic stroke might initiate neurodegenerative dementia, particularly in the aging population."

The researchers conclude that repair of the BBB following ischemic stroke could potentially prevent further degradation of surviving neurons.

"Recognizing that the BBB is a therapeutic target is important for developing neuroprotective strategies," they said.

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In addition to researchers from USF, researchers from the Ribeirao Preto School of Medicine, University of Sao Paulo, Sao Paulo, Brazil, contributed to the study.

The study was supported by the National Institutes of Health (1RO1NS071956-01A1) and the James and Esther King Biomedical Research Program (1KG01-33966).

The Department of Neurosurgery and Brain Repair has strong and ongoing commitments to neurosurgical education both at the residency and fellowship level and also to providing ongoing educational efforts for practicing physicians. Multiple avenues of research under investigation in the department include conducting clinical research in the fields of complex spinal disorders, epilepsy, brain tumor treatment, and stroke care, among others. In the departmental laboratories, studies of spinal biomechanics, neurodegenerative disorders, and microsurgical techniques are also underway. We are trying to improve the treatments available for our neurosurgical patients and neurological patients throughout the world. http://health.usf.edu/medicine/neurosurgery/index.htm

The mission of the Center of Excellence for Aging and Brain Repair is to develop new therapeutic strategies to promote repair and regeneration of aging and diseased brain. Building on a foundation of excellence in basic and clinical research, the center focuses on translating innovative ideas into industrial partnerships and educational and clinical services to address key needs of the community and those suffering from brain injury and disease. http://health.usf.edu/nocms/medicine/neurosurgery/ceabr/


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