Diabetes Mellitus Clinical Trial
Official title:
Does Reduction of Hyperglycemia With Insulin Impact Restenosis and Improve Clinical Outcomes Following PCI?
Coronary artery disease is a process that results in “hardening of the arteries”. When the
arteries that supply blood and oxygen to your heart muscle become clogged or narrowed, a
heart attack may result, or you may feel chest discomfort (angina) – sometimes even while
resting. One approach to treating this condition is a balloon procedure known as coronary
angioplasty.
The major limitation of coronary angioplasty is renarrowing of the artery (restenosis) in
the first six months following the procedure requiring either repeat angioplasty or referral
for bypass surgery. Patients with diabetes have always been identified as having higher
rates of restenosis and poor outcomes following angioplasty, despite some important
scientific advances. We think that the level of blood sugar control at the time of
angioplasty and in the following months may be related to the extent of restenosis.
We expect that a reduction in blood sugar with insulin may, in turn, reduce the restenosis
process and improve your long-term outcome.
Studies consistently show that diabetes (DM) is an independent predictor of angiographic
restenosis as well as clinical outcomes after PCI. A common criticism of the early PCI
trials is that stents were not routinely used. However, even when stents are used, the
presence of DM is associated with a higher restenosis rate and lower event rate survival. In
a series of 3,554 consecutive patients (715 DM patients) undergoing stenting procedures at a
single centre the incidence of restenosis and total vessel occlusion by angiographic
assessment was significantly higher in diabetes. Increased restenosis rates were
consistently demonstrated across a broad range of lesion types.
The pathophysiology of restenosis is viewed as a complex temporal sequence of interactions
involving several cellular and mechanical factors including elastic recoil, thrombosis,
intimal hyperplasia, extra cellular matrix elaboration, apoptosis, oxidative stress and
unfavorable arterial remodeling (“arterial shrinkage”). The exposure of subendothelial
elements initiates platelet adhesion and activation. Activated platelets at the site of
injury secrete growth factors that release smooth muscle cells from growth inhibition and
induce their proliferation and subsequent migration from the media to the intima. Smooth
muscle cell proliferation continues beyond the phase of platelet deposition. Extracellular
matrix is produced and secreted by smooth muscle cells that have migrated into the injured
intimal zone. This hypocellular matrix material forms the bulk of the intimal tissue.
Although mechanical factors such as early vessel elastic recoil may play a major role
following balloon angioplasty, this mechanism should not significantly affect the stented
segments as the stent provides a rigid endovascular scaffold. Similarly, late arterial
remodelling which has been postulated to be a significant factor for the development of
restenosis after PCI should not have a major effect in the context of stents. Therefore, the
major mechanism contributing to in-stent restenosis is aggressive intimal hyperplasia.
Recent studies demonstrate that DM is characterized by diffuse intimal hyperplasia within
the stented segment. DM is an independent predictor of the volume of intimal hyperplasia
within the stent. The pattern of stent restenosis in patients with DM tends to be more
diffuse and proliferative and therefore more likely to lead to total vessel occlusion. This
is significant because diffuse restenosis is difficult to manage with repeat percutaneous
procedures.
Hyperglycemia has been postulated to promote the restenotic process in diabetes by the
following mechanisms: i. endothelial cell dysfunction; ii. increased platelet aggregation
and thrombus formation; iii. dysregulation of growth factor expression; iv. abnormal
extracellular matrix deposition; v. advanced isolation and products.
Approaches to preventing stent restenosis have had limited effect. Pharmacologic trials have
universally failed to show a reduction in restenosis rates in human subjects. Recent reports
suggested radiation therapy (brachytherapy) especially applied locally either via catheters
or through radioactive stents has a potential to reduce the proliferative response. Although
this approach holds great promise there are unresolved logistic issues, safety issues, and
cost issues limiting wide-spread application.
Preliminary studies of drug-eluting stents show initial promise in reducing restenosis
rates. However, stent coatings can counteract the restenotic process only at points where
the stent strut opposes the arterial wall and have little effect on neointimal tissue that
can protrude between the struts and into the lumen. Furthermore, both brachytherapy and
stent coatings only apply to the stented segments and the vessel whereas the arterial
responses to balloon injury may also depend on flow characteristics (i.e. rheology) of the
vessel. Therefore, alternative strategies that impact both local processes of the dilatation
site and systematic processes on vessel remodelling and rheology are needed.
Clinical trial data suggests that glycemic control may prevent restenosis. A recent study of
patients with type 2 diabetes undergoing PCI with stent demonstrated a significant reduction
in both neointimal area and neointimal index among participants randomized to the
glucose-lowering agent troglitazone. Observational data from two registry studies indicate
that diabetic patients with well-controlled hemoglobin A1c had lower rates of restenosis.
Several lines of evidence suggest that insulin is safe and effective in controlling diabetes
as well as reducing cardiovascular events. The recently published DIGAMI Study in which
patients with myocardial infarction were randomized to an insulin infusion followed by at
least three months of intensified insulin therapy showed a 31% reduction mortality in
patients receiving intensified therapy. Subcutaneous insulin has been safely used to treat
diabetes for almost 80 years. Patients can easily learn to both inject and titrate insulin
response to home capillary glucose measurements. Greater than 85% of patients with type II
diabetes who were started on insulin can achieve safe and effective metabolic control with
one injection per day.
Intravascular ultrasound is the most direct and sensitive technology available for
measurement of intravascular hyperplasia volume within the stent. It is the technology that
is most likely to uncover a benefit of insulin in reducing restenosis if one exists. This
methodology will allow the research question to be answered with the smallest possible
sample size. Recent studies demonstrate that detailed cross-sectional analysis of
intracoronary stents during motorized IVUS catheter pullback is feasible with excellent
reproducibility, safety and can be stored for off-line analysis. Establishing a mechanistic
link between glycemic control and restenosis will support the design of larger clinical
studies evaluating clinical outcomes.
Primary Study Question
- Does intensive control of glucose levels with insulin in patients with DM reduce volume
of intimal hyperplasia within the stented segment as evaluated by intravascular
ultrasound (IVUS) at 6 months? Secondary Study Question
- Does intensive glycemic control with insulin reduce restenosis as evaluated by
quantitative coronary angiography (QCA) at 6 months
- Does intensive glycemic control with insulin prevent clinical events such as hospital
admission for unstable angina and for congestive heart failure, myocardial infarction,
stroke, revascularization (PCI, CABG) and death at 12 months.
Primary Hypothesis:
·Intensive glycemic control with insulin in diabetic (DM) patients reduces intimal
hyperplasia within the stented segment after percutaneous coronary revascularization
Secondary Hypothesis:
- The reduction in intimal hyperplasia is related to the degree of glycemic control (i.e.
HbA1c values); and
- Event-free survival is improved in patients treated with insulin
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Open Label, Primary Purpose: Treatment
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