Research may point towards more
effective surgical stents for people with diabetes. People with any
form of diabetes are at greater risk of developing cardiovascular
conditions than people without the disease. Moreover, if they
undergo an operation to open up a clogged artery by inserting a
"stent" surgical tube, the artery is much more likely to
clog up again. However, researchers at Joslin Diabetes Centers now
have uncovered an explanation for why these procedures often fail,
which may lead toward better alternatives.
An enzyme known as SHP-1, which can
suppress the growth of smooth muscle cells lining the inside of blood
vessels, plays a crucial role in stent failure, says George King,
M.D., Joslin's Chief Scientific Officer and senior author on a paper
in the journal Diabetologia describing the work.
Stents coated with a drug that
activates SHP-1, and thus slows the accelerated growth of these
vascular cells, might help in treating arterial disease in diabetes,
says King, who is also Professor of Medicine at Harvard Medical
School.
His team's research began with
experiments among mice fed a high-fat diet and rats that were
genetically modified to display insulin resistance and related
metabolic conditions related to diabetes. "We found that SHP-1
expression was decreased in the arteries from all of these animal
models," says Weier (Glorian) Qi, co-lead author on the paper.
"We also found that SHP-1 expression dropped in the arteries of
patients with type 2 diabetes."
Next, the scientists created mice that
were genetically engineered to over-express the protein in their
vascular smooth muscle cells. When the scientists fed these mice a
high-fat diet that clogged their arteries and performed a procedure
similar to stent insertion, they found that the arteries in these
animals were less clogged than in normal mice given the same
procedure.
The researchers went on to demonstrate
that SHP-1 is reduced in mouse vascular smooth muscle cells primarily
by the high levels of lipids in the blood associated with diabetes
and related conditions, rather than the high levels of glucose also
present in those conditions.
Following up on these findings may help
to address a major research puzzle in diabetic complications, says
King: Each type of tissue seems to react differently to the disease.
For example, he explains, smooth muscle
cells grow thicker in large blood vessels like arteries, but similar
type of contractile cells begin to die off in tiny blood vessels in
the eye.
"These opposite cell growth
patterns are an enigma," King comments. "They also make it
difficult to develop therapeutics, because we would want to
deactivate SHP-1 in the eye and activate it in large arteries."
Surgical stents for artery repair are
typically coated with slow-releasing drugs that aim to suppress
excessive regrowth of the surrounding smooth muscle cells. This
approach to release drugs locally might work for drugs that boost
SHP-1 expression, King speculates.
"We hope our research
encourages ideas about how to address this problem for people with
diabetes," he adds. ""The more ideas that come up, the
greater the chances that we can achieve such a needed treatment."
This is one reason that I am hesitant
to follow the high fat part of the low carb high fat diet, although I
do use the low carb medium fat and moderate protein of my own
choosing.
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