X-Message-Number: 23193
Date: Tue, 30 Dec 2003 09:16:14 -0500 (GMT-05:00)
From:  brent thomas <>
Subject: new research 3hrs hypoxic - no problem

Interesting new research into stroke activity at 
http://www.sciencedaily.com/releases/2003/12/031228164720.htm
showing 3hrs with lack of oxygen without signifigant cell death effects...

Seems like if this channel could be blocked in hypothermic tests we just might 
get
higher survival rates...definitly worth a look

from the article


New Understanding Of Why Brain Cells Die After Stroke Will Lead To Development 
Of New Treatments

Scientists at Toronto Western Hospital and the University of Toronto have found 
a major mechanism that causes brain cells to die from stroke. They discovered 
that when brain cells are deprived of oxygen and vital nutrients, as happens to 
parts of the brain affected by a stroke, a special channel on the surface of 
those brain cells is activated, triggering a lethal chain reaction. The channel,
called TRPM7, when activated causes brain cells to produce large quantities of 
free radicals     toxic molecules that break down the cell's DNA, proteins, and 
other components. Free radicals also cause TRPM7 to become even more active, 
causing massive overproduction of free radicals, resulting in death of the brain
cell. 


 

In a study published in the December 26 issue of Cell, an international science 
journal, the scientists also report that they have found a way to interfere with
this lethal chain reaction. While brain cells can only survive for a few 
minutes without oxygen, interfering with the activity of TRPM7 allows brain 
cells to survive for more than three hours without oxygen and vital nutrients. 


With this new understanding, there is now an opportunity to develop new 
medications that prevent activation of the TRPM7 channel. It will take 
approximately three years to develop a medication. 


"This is a quantum leap forward in understanding how stroke causes brain 
damage," says Dr. Michael Tymianski, neurosurgeon at the Krembil Neuroscience 
Centre at Toronto Western Hospital and associate professor of surgery and 
physiology at the University of Toronto. "Now we can see the bigger picture of 
why brain cells die from stroke." 


"This project is a primary example of how basic and clinical scientists can come
together as an effective research team to tackle the major health problem of 
stroke," says Dr. John MacDonald, chair of the department of physiology, Faculty
of Medicine at the University of Toronto. "We are also very excited to explore 
the many potential functions of TRPM7 channels in the brain." 


Until now, scientists thought they understood why brain cells die when deprived 
of oxygen and essential nutrients. Past research suggested that the major 
culprit was glutamate, an amino acid normally used by brain cells to communicate
by carrying signals from one brain cell to the next. Dying brain cells release 
glutamate, which attaches to a special channel called the NMDA receptor located 
on the surface of the neighbouring brain cells. This causes the NMDA channel to 
open and allows an influx of calcium ions into the brain cell. For years, it was
thought that this sequence of events caused brain cells to die from stroke. 


For this reason, many experimental medications for treating strokes were aimed 
at blocking the effects of glutamate on NMDA receptors. Although it worked in 
the lab, the medications failed to reduce brain damage in humans. Despite three 
decades of research that pointed to glutamate as the culprit in cell death, the 
failure of these medications remained a mystery. To solve this mystery, Drs. 
Tymianski and MacDonald went back to the drawing board and discovered that 
glutamate was only one part of the reason why brain cells die from stroke. 


"We have significant experience in translating such basic discoveries into drugs
that might help patients," says Dr. Tymianski. "With this new knowledge, we 
will now focus on developing medications that we can inject into stroke patients
up to several hours after a stroke. These medications will prevent the 
consequences of activating TRPM7, extend the life of brain cells after a stroke,
and help improve the outcome of patients suffering from a stroke." 


As the fourth most common cause of death in Canada, and the second leading cause
of death in the world, stroke kills about 16,000 Canadians every year. Stroke 
is a major cause of disability, as people who survive strokes suffer irreparable
damage to their brain cells. These effects can include partial paralysis, 
problems with thinking, problems with language, and difficulty with movement. 
Approximately 300,000 Canadians live with the effects of stroke. The warning 
signs of a stroke include sudden weakness, trouble speaking, vision problems, 
headache, and dizziness. 


### This research was funded by grants from the Canadian Institutes of Health 
Research, the Ontario Heart and Stroke Foundation, and the National Institutes 
of Health of the United States of America. 


Toronto Western Hospital has been serving the health care needs of its 
culturally diverse community for more than 100 years. Today, the hospital 
provides highly specialized tertiary care to people from surrounding areas and 
across Canada. Home to the Krembil Neuroscience Centre, one of the largest 
combined clinical and research neurological facilities in North America, the 
hospital also offers a community and population health program and expertise in 
musculoskeletal health and arthritis. Toronto Western Hospital is one of three 
hospitals     including Toronto General Hospital and Princess Margaret Hospital
that make up University Health Network, a teaching hospital of the 
University of Toronto. 


The University of Toronto (U of T), Canada's leading research university with 
over 60,000 students, was founded in 1872 by British royal charter. For the 
tenth consecutive year, U of T has taken the top spot among medical/doctoral 
universities in the annual Maclean's magazine university ranking. The university
now comprises 31 divisions, colleges and faculties on three campuses, including
14 professional faculties, numerous research centres and Canada's largest 
library system     one of the top research libraries in North America. U of T's 
Department of Physiology is the largest and most research-intensive university 
physiology departments in Canada and has research and training partnerships with
numerous hospital-based research institutes.

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