Toxicity/Substance Abuse

Benefits of Cannabis

The CBs hold much promise in not only improving stroke but also traumatic and anoxic brain injury outcome. There is a rise in evidence that the endocannabinoids and botanical nonpsychoactive cannabidiol derivatives from the cannabis plant have a multitude of beneficial effects, particularly with ischemic stroke. Animal models of stroke have shown cannabidiol increases cerebral blood flow (CBF) mediated by 5-hydroxytryptamine (serotonin) receptor 1A (5HT1A) receptors and induces vasorelaxation .

A major goal of acute stroke care entails salvaging the penumbra and extra-penumbral regions of brain by preventing further growth of the infarct zone. Necrosis and apoptosis within the stroke core lead to free radical formation, glutamate release, and an inflammatory cascade leading to accumulation of intracellular calcium and cell death . Endocannabinoids accumulate in ischemic tissue with CB 1 receptor (CB1 receptor) activation resulting in neuroprotective mechanisms including inhibition of glutamate release, decrease in intracellular calcium, hypothermia, decreased reactive oxygen species, and expression of brain-derived neurotrophic factor (BDNF). CB 2 receptor (CB2 receptor) activation leads to a decrease of leukocyte adhesion and cytokine release .

Synthetic CB1/CB2 receptor agonists are associated with a reduction of infarct size and hypothermia in animal models. CB1 receptor antagonists, however, have also shown a reduction of infarct size. The conflicting results prove the complexity of the ECS; others hypothesize that the CB receptor inhibitors may be targeting nonCB receptors but still producing neuroprotective effects. Studies are also investigating modulation of CB1/CB2 receptor activation with promising results on reducing infarct size with stimulation of CB2 and inhibition of CB1 . CB may also play a beneficial role in post-stroke rehabilitation with studies reporting CB1 and CB2 receptor expression in neural stem and progenitor cells .

Cons of Cannabis

Delta-9-THC is the main active ingredient in cannabis and most often implicated in depression, psychosis, and anxiety . Delta-9-THC is a psychoactive substance with vasoconstrictor effects. It has been associated with arteriopathies of small muscular arteries of the legs, coronary arteries, and cerebral circulation based on angiographic studies. A study by Ntholang and collaborators was the first study demonstrating histological evidence of hyperplastic tunica intima with associated luminal stenosis of cerebral arteries in young cannabis users .

Despite the known underreporting, the rate of cannabis-related cardiovascular complications, including peripheral, cerebral, and cardiac, has steadily risen over the past 5 years, with acute coronary syndromes and peripheral arteriopathies comprising the majority of complications . Cannabis is associated with arterial disease resulting in stroke with a high rate of occurrence in the posterior circulation, myocardial infarction (MI), and limb arteritis. An incidence of 2–39% of cannabis-associated stroke has been reported . The temporal relationship between symptom onset and resolution with starting and stopping cannabis, respectively, suggests cannabis is a trigger of these arterial disorders (Matteo).

Cannabis-related ischemic strokes are limited to case reports and population-based studies. Cannabis-related hemorrhagic stroke is also limited to few case reports. Pathogenesis of hemorrhagic stroke may be related to transient cannabis-induced hypertension with altered autoregulation. Most reported cases of cannabis-related ischemic stroke are seen in patients younger than 50 years of age without traditional vascular risk factors . Concomitant alcohol use and tobacco use have been suggested as risk factors. The pathogenesis of cannabis-related ischemic stroke is thought to be due to altered cerebral autoregulation and regional hypoperfusion, or an acute inflammatory cascade with thrombosis. It remains uncertain if platelet activation is involved in the pathogenesis of THC-triggered procoagulant properties. In vivo studies are necessary to evaluate the role on THC-platelet activation leading to a procoagulant effect .

Other mechanisms include arterial hypotension, cardioembolism, vasospasm, vasculitis, or reversible cerebral vasoconstriction syndrome (RCVS) . Chronic cannabis is associated with increased cerebrovascular resistance . Because delta-9-THC increases CBF, transcranial Doppler (TCD) was studied in marijuana users assessing blood flow velocity in the anterior and middle cerebral arteries (ACAs and MCAs, respectively) in control groups and participants using marijuana in different intensities. Blood flow velocity was also measured for 30 days of marijuana abstinence . The pulsatile index, which is a measure of cerebrovascular resistance, and systolic velocity were elevated in marijuana users compared to control groups and persisted despite abstinence. This increase in cerebrovascular resistance may account for strokes as well as cognitive deficits seen in chronic marijuana users .

Laced marijuana poses a serious danger, increasing risk of stroke in users. Marijuana can be laced with cocaine, crack (also called bazooka), PCP, heroin, and even embalming fluid . Although reports are infrequent, unregulated marijuana can easily be adulterated by dealers but most often occurs at the user level. Powdered cocaine or crack is sprinkled into a joint or blunt in order to combine the stimulant effects of cocaine with the depressant effects of marijuana. A joint can also be immersed in formaldehyde (a known carcinogen), mimicking the effects of PCP in which the user develops hallucinations, euphoria, panic, or rage. Laced marijuana undoubtedly poses cardio- and cerebrovascular complications and should be avoided .

Amphetamines and ICH/SAH

ICH is a more common adverse effect than ischemic stroke after sympathomimetic use . The association between amphetamines and ischemic or hemorrhagic stroke is based solely on case series . Most epidemiological studies assessing this association have been conducted in underserved settings or largely based on the minority population, but small case–control studies have demonstrated a strong risk factor of stroke in the insured, urban populations with amphetamine use . Most case series report that the risk of hemorrhagic stroke due to amphetamines is twice that of cocaine use . Amphetamines and other related sympathomimetic drugs can result in ICH within minutes to hours after exposure. The acute rise of blood pressure leading to ICH has been observed even after first time use of amphetamines. Transient arterial hypertension after drug exposure is thought to cause ICH in locations typical of a hypertensive hemorrhage including the basal ganglia, thalamus, pons, and subcortical white matter. Hypertension induced by amphetamine use is also thought to contribute to aneurysm formation with resulting SAH . Some studies have refuted this demonstrating that in patients presenting with amphetamine-related SAH, autopsy failed to show aneurysm or arteriovenous malformations . Although rare, methamphetamines and synthetic cannabis have also been associated with spinal SAH due to ruptured thoracic radicular artery pseudoaneurysm rupture in a single case report .

Other mechanisms of ICH include altered cerebrovascular autoregulation, coagulopathy, vasculitis, and hemorrhagic transformation of ischemic stroke . Cerebral vasoconstriction has been reported with cocaine, amphetamine, ephedrine, phenylephrine, LSD, and heroin, but it is difficult to distinguish between vasospasm and vasculitis. It is suspected that as vasospasm resolves and perfusion is restored, arterial rupture can occur .