Subarachnoid Hemorrhage Clinical Trial
Official title:
A Randomized, Double-Blind, Placebo-Controlled Trial of Simvastatin on Subarachnoid Hemorrhage-Induced Vasospasm
To determine whether HMG-CoA reductase inhibitor simvastatin prevents or ameliorates subarachnoid hemorrhage-induced delayed vasospasm and its ischemic consequences.
The mortality rate of aneurysmal subarachnoid hemorrhage (SAH) approaches 50% within the 1st
24 hours of ictus. Patients who survive can subsequently develop a progressive vasospasm of
large cerebral arteries, which is a major cause of morbidity and mortality. Vasospasm can be
of varying severity, and only a small portion of patients with vasospasm develop clinical
signs or symptoms. Patients with severe vasospasm are prone to develop ischemic deficits,
which, if untreated, will progress into ischemic infarcts.
The mechanisms of vasospasm have been subject to intense investigation. Nitric oxide
(NO)-cGMP system has attracted particular attention. Under normal physiological conditions,
NO synthesized by endothelia NO synthase (eNOS) stimulates vascular smooth muscle cGMP
production, which in turn causes smooth muscle relaxation. Vasospasm impairs
endothelium-dependent dilations, suggesting that SAH induces a state of NO deficiency within
cerebral arteries.
There are several potential mechanisms of such an NO deficiency. Hemoglobin is a potent
scavenger of NO, and when applied extraluminal it binds NO and inhibits its action. Presence
of perivascular hemoglobin may contribute to development of vasospasm by reducing the
availability of NO. It has been shown that adventitial applied hemoglobin can inhibit basal
NO activity and that in vivo adventitial exposure to whole blood leads to a reduction in
basal cGMP levels in association with vasospasm of cerebral arteries. Similarly, superoxide
also reacts with NO and acts as an NO scavenger. Superoxide production is increased after
SAH, which may in part be responsible for inhibition of NO-dependent vasodilation. Free
radical scavengers and manipulations to reduce free radical formation reduce vasospasm after
SAH.
NOS is constitutively expressed in endothelium and adventitial perivascular nerve fibers.
SAH-induced vasospasm in monkeys has been associated with diminished constitutive NOS
immunoreactivity in the perivascular nerves around the spastic arteries. Endothelial NOS
mRNA has also been decreased in monkey cerebral arteries 7d after SAH. Therefore, data
suggest that there is a relative reduction in NO synthesis after SAH, in addition to
increased breakdown.
In summary, the reduction in NO tonus around the cerebral arteries induced by decreased
expression of endothelial NOS as well as increased NO scavenger substances in the
subarachnoid space, and a relative resistance to NO-induced vasodilation in SAH appears to
be one of the key events in the development of vasospasm. Therefore, therapeutic
interventions that enhance endothelial NO production may compensate for these changes and
reverse or reduce vasospasm.
Statins are FDA approved mainly as antihyperlipidemics, and they effectively reduce the risk
of stroke and myocardial infarction. Simvastatin is also FDA-approved for stroke prevention.
The risk reduction, however, is not correlated with the degree of lipid reduction, and is
seen even in individuals with normal lipid levels. Statins are also cerebroprotective in
stroke. They enhance endothelium-dependent relaxations, augment cerebral blood flow, reduce
cerebral infarct size, and improve neurological outcome of stroke in normocholesterolemic
animals. Their protective effects are independent of lipid reduction. Most importantly,
statins upregulate endothelial NOS expression. This in turn improves cerebral blood flow and
reduces infarct size in experimental models. In addition, statin treatment enhances
endothelial fibrinolytic action, and inhibits platelet aggregation. Therefore, statins are
excellent candidates to test on SAH-induced vasospasm.
This study has a randomized, double blind, placebo-controlled design. The anticipated
enrollment is 104 patients, 52 in simvastatin, and 52 in placebo group, all recruited and
studied at MGH. Assuming a difference of 27% or more, the power of this study is 88%, and
alpha=0.05.
Inclusion and exclusion criteria are summarized below. Once enrolled, patients are
randomized by Research Pharmacy staff to receive either placebo, or simvastatin 80 mg once
every day, the highest clinically used dose of simvastatin. We chose this dose to maximize
the effect on endothelium, which has been dose dependent in experimental studies. The study
investigators are blinded to the treatment group. Patients are followed prospectively and
receive standard aneurysmal subarachnoid hemorrhage care. The data collected pertains to
development of vasospasm, and hence involves daily vital signs, neurologic examination, and
routine neuroimaging. The development of vasospasm is determined based on daily transcranial
Doppler studies, conventional angiography (routinely done within 7 days after subarachnoid
hemorrhage as standard of care), and neurologic examination. Liver function tests along with
total CPK are checked on admission and once a week for as long as the drug is continued, to
screen for potential toxicity from the medication. Medication is discontinued if CPK or
liver enzymes are elevated by more than 3 times the upper limit of normal range. CPK
elevations due to surgical or percutaneous/endovascular interventions, or from cardiac
sources (i.e. accompanied by troponin elevation with or without ECG changes), are not
considered as indications for drug discontinuation.
;
Allocation: Randomized, Endpoint Classification: Safety/Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double-Blind, Primary Purpose: Treatment
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