Cardiovascular Effects of Cannabis
1.1 One of the most consistent effects of cannabis intoxication is an increased heart rate [i] . For this reason alone it would not be normally recommended for patients with cardiovascular problems. However, THC also acts as a smooth-muscle relaxant, relaxing the walls of the arteries, which can result in lower blood pressure and increased blood flow to the tissues [ii] [iii] . The effect taken together is analogous to a car changing down a gear.
1.2 Cannabis intoxication has been found to reduce the level of exercise which can be tolerated before the onset of angina [iv] .to a greater extent than a high-nicotine tobacco cigarette [v] . Cardiovascular symptoms have been attributed to cannabis use, either alone (stroke) [vi] , or in combination with alcohol and cocaine [vii] .
1.3 The presence and action of CB1 cannabinoid receptors in arterial tissue was described by Bilginger et al [viii] , who reported: “the data demonstrate that cannabinoid signalling is involved with the regulation of the microvascular environment” Cannabinoids such as CBD and the synthetic HU-211 [ix] have been shown to reduce ischaemic cell damage following cardiac arrest or stroke. CBD also counteracts the increase in heart-rate associated with THC [x] – THC and CBN both appear to increase heart rate, while CBD tends to decrease heart rate. There is conflicting evidence as to whether changes in cardiovascular function are related to myocardial contractility [xi] [xii] . Animal studies are conflicting, the effect in dogs appears opposite to that in humans [xiii] [xiv] . Part of the increase in heart rate can be counteracted by use of beta-blocker drugs [xv] , but not by opiate antagonists such as Naloxone [xvi] . From a clinical study of long-term marijuana smokers, Tashkin et al [xvii] concluded ” in long-term heavy users of cannabis, marihuana has no significant effect on myocardial contractility independent of its effect on heart rate .”
2 Blood Pressure:
2.1 Early studies on rats bred for high blood pressure [xviii] found that THC reduced levels of blood pressure [xix] [xx] , and that tolerance developed to this effect [xxi] . Mechoulam [xxii] predicted in 1978 ” Numerous synthetic cannabinoids are currently being investigated as analgetics and as sedative-relaxants .” Zaugg & Kyncl [xxiii] reported ” hydroxyacetyl and gamma-hydroxybutyryl (cannabinol) derivatives were potent antihypertensive agents (minimum effective dose, 3-5 mg/kg, orally) of the same order of activity as the highly CNS-active N-propargyl derivatives “
2.2 Hanus et al [xxiv] reported that the specific CB2 receptor agonist HU-308 ” reduces blood pressure. The hypotension. produced by HU-308 (is) blocked (or partially blocked) by the CB(2) antagonist SR-144528, but not by the CB(1) antagonist SR-141716A. These results demonstrate the feasibility of discovering novel nonpsychotropic cannabinoids that may lead to new therapies for hypertension. ” Garcia et al [xxv] reported ” Anandamide produced a dose-dependent decrease in mean arterial pressure due to a drop in systemic vascular resistance (SVR) that was accompanied by a compensatory rise in cardiac output . Anandamide also elicited an increase in both portal venous flow and pressure, along with a decline in mesenteric vascular resistance (MVR). Pretreatment with 3 mg/kg SR-141716A, a CB(1) antagonist, prevented the decline of SVR and MVR from the lower dose of anandamide .”
2.3 Gardiner et al [xxvi] , rats studying the effects of the cannabinoid receptor agonist WIN 55212-2 in normal (HSD) and hypertensive (TG), concluded ” Collectively, the results indicate that the predominant cardiovascular effects of WIN 55212-2 in conscious HSD and TG rats (i.e., pressor and vasoconstrictor actions) can be attributed largely to indirect, pentolinium-sensitive mechanisms, which appear to differ little in the normotensive and hypertensive state, at least in conscious animals. Under the conditions of our experiments, signs of cannabinoid-induced vasodilatation were modest .” Studying anandamide in anaesthetised and conscious rats, Gardiner et al [xxvii] reported ” At all doses of anandamide, there was a significant, short-lived increase in mean arterial blood pressure associated with vasoconstriction in renal, mesenteric and hindquarters vascular beds. The higher doses (2.5 and 3 mg kg(-1)), caused an initial, marked bradycardia accompanied, in some animals, by a fall in arterial blood pressure which preceded the hypertension. In addition, after the higher doses of anandamide, the hindquarters vasoconstriction was followed by vasodilatation. None of the cardiovascular actions of anandamide were influenced by the CB(1)-receptor antagonist, AM 251 “
2.4 Jarai & Kunos [xxviii] noted ” cannabinoids were found to be potent CB1-receptor dependent vasodilators in the coronary and cerebrovascular beds ” concluding ” the endogenous cannabinoid system plays an important role in cardiovascular regulation, and pharmacological manipulation of this system may offer novel therapeutic approaches in a variety of pathological conditions .” Wagner et al [xxix] report ” Activation of peripheral cannabinoid CB(1) receptors elicits hypotension ” and noted ” We conclude that cannabinoids elicit profound coronary and cerebral vasodilation in vivo by direct activation of vascular cannabinoid CB(1) receptors, rather than via autoregulation, a decrease in sympathetic tone or, in the case of anandamide, the action of a non-cannabinoid metabolite .” However, in a review article for the Bulletin on Narcotics, Husan & Khan [xxx] warned ” The use of cannabis causes prominent and predictable effects on the heart, including increased work-load, increased plasma volume and postural hypotension, which could impose threats to the cannabis users with hypertension, cerebrovascular disease or coronary arteriosclerosis .” Lake et al [xxxi] noted ” in anesthetized rats anandamide elicits bradycardia and a triphasic blood pressure response: transient hypotension secondary to a vagally mediated bradycardia, followed by a brief pressor and prolonged depressor response, the latter two effects being similar to those of delta 9-tetrahydrocannabinol (THC) ” Krowicki et al [xxxii] found that, in anaesthetised rats ” Intravenously administered delta9-THC evoked . bradycardia, and hypotension “
2.5 The picture is slowly becoming clearer, indicating that endo-cannabinoids modify aspects of blood flow at a subtle local level. In a 2001 review, Schiffrin [xxxiii] noted ” The endothelium produces a variety of substances that play important roles in regulation of the circulation and vascular wall homeostasis. The control of blood vessel wall homeostasis is achieved via production of vasorelaxants and vasoconstrictors. Among the vasorelaxants are . metabolites of arachidonic acid like epoxyeicosatrienoic acids, and endocannabinoids) “
3 Cerebrovascular Effects:
3.1 Matthew & Wilson [xxxiv] found ” In experienced marijuana smokers, marijuana smoking was accompanied by a significant bilateral increase in cerebral blood flow (CBF) especially in the frontal regions and cerebral blood velocity .” Tunving et al [xxxv] , studying long-term cannabis users found decreases in cerebral blood flow during the early stages of detoxification, reverting to normal after 9-60 day follow-up. Similar results were found by Lundqvist et al [xxxvi] – ” Cerebral blood flow (CBF) was measured in 12 long-term cannabis users shortly after cessation of cannabis use (mean 1.6 days). The findings showed significantly lower mean hemispheric blood flow values and significantly lower frontal values in the cannabis subjects compared to normal controls ” Ellis et al [xxxvii] found ” Anandamide (AN) and delta 9-THC similarly induced a dose-dependent dilation (of cerebral arterioles) starting at concentrations as low as 10(-12) M. Maximum dilation for AN was 25% and that for delta 9-THC 22%. Topical coapplication of indomethacin, a cyclooxygenase inhibitor, completely blocked dilation “
3.2 Bloom et al [xxxviii] found different areas of the brain to have different blood-flow responses to THC · ” Changes in regional cerebral blood flow were observed in 16 of the 37 areas measured .” Stein et al [xxxix] in the rat, an O”Leary et al [xl] in human recreational users, also found wide variations in cerebrovascular response in different brain regions.
4 Strokes and Neuroprotectivity:
4.1 There are a number of case studies describing patients who have suffered strokes following or during cannabis use, some, but not all,of these cases can be explained by use of other drugs (alcohol or stimulants). Cooles & Michaud [xli] report a case history of a patient suffering a stroke following a heavy bout of cannabis smoking. Alvaro et al [xlii] reported another case history ” of a young man and heavy cannabis smoker who suffered posterior cerebral artery infarction during his first episode of coital headache “In a further case history, Lawson & Rees [xliii] reported ” A 22-year-old man with a five-year history of drug and alcohol abuse presented with a left hemiparesis preceded by three transient ischaemic attacks, two of which occurred whilst smoking cannabis ” although in response, McCarrom & Thomas [xliv] stressed the likely role of alcohol or other drugs in the etiology of such strokes. Mouzak et al [xlv] described ” Three male patients (mean age 24.6 years) who were heavy cannabis smokers presented with transient ischemic attacks (TIA) shortly after cannabis abuse. The urine analysis was positive for cannabis metabolites. There were no other abnormal findings in the rest of the meticulous and thorough study of all 3 patients, which leads to the conclusion that cannabis was the only risk factor responsible for the observed TIA, contradictory to other studies, which support that cannabis is a ‘safe’ drug .”
4.2 However, it is clear that cannabinoids have a variety of cerebrovascular effects, increasing the blood supply to the brain [xlvi] , and can protect against potentially fatal brain cell death following a stroke by reducing tumour necrosis factor, which causes self-destruction in exposed cells. The use of cannabinoids for treatment of brain damage arising from strokes is reaching an advanced stage of the licensing process, Job [xlvii] reported in 2000 “Dexanabinol is a non-psychotropic cannabinoid NMDA receptor antagonist under development by Pharmos Corp for the potential treatment of cerebral ischemia. cardiac failure, head injury and multiple sclerosis (MS). it is in phase III trials for traumatic brain injury. Pharmos estimates that the worldwide market for dexanabinol in the treatment of severe head trauma may reach $1 billion per year” Leker et al [xlviii] investigated the effect of dexanabinol, a synthetic cannabinoid which is a NMDA antagonist, with antioxidant and anti-tumour necrosis factor alpha properties, on the levels of brain damage (infarct) following experimentally induced ischaemic strokes in rats, finding ” Dexanabinol significantly decreased infarct volumes. It also significantly lowered TNFalpha levels in the ipsilateral hemisphere although not to the level of sham operated rats. In conclusion, dexanabinol may be a pluripotent cerebroprotective agent .”
4.3 Panikashvili et al [xlix] reported ” Traumatic brain injury triggers the accumulation of harmful mediators that may lead to secondary damage. Protective mechanisms to attenuate damage are also set in motion. 2-Arachidonoyl glycerol (2-AG) is an endogenous cannabinoid. after injury to the mouse brain, 2-AG may have a neuroprotective role in which the cannabinoid system is involved. After closed head injury (CHI) in mice, the level of endogenous 2-AG was significantly elevated. We administered synthetic 2-AG to mice after CHI and found significant reduction of brain oedema, better clinical recovery, reduced infarct volume and reduced hippocampal cell death compared with controls. When 2-AG was administered together with additional inactive 2-acyl-glycerols that are normally present in the brain, functional recovery was significantly enhanced. The beneficial effect of 2-AG was dose-dependently attenuated by SR-141761A, an antagonist of the CB1 cannabinoid receptor .”
4.4 Belayev et al [l] found the synthetic cannabinoid HU-211 to be ” an effective drug in protecting against the effects of focal ischemia-induced (blood-brain barrier) disruption in the rat and suggest that the drug may be an effective treatment against the ischemic cell death and BBB disruption that can occur clinically following a stroke or cardiac arrest .” Nagayama et al [li] noted ” R(+)-WIN 55212-2, a synthetic cannabinoid agonist, decreased hippocampal neuronal loss after transient global cerebral ischemia and reduced infarct volume after permanent focal cerebral ischemia induced by middle cerebral artery occlusion in rats. The less active enantiomer S(-)-WIN 55212-3 was ineffective, and the protective effect . was blocked by (a) specific central cannabinoid (CB1) cannabinoid receptor antagonist . R(+)-WIN 55212-2 also protected cultured cerebral cortical neurons from in vitro hypoxia and glucose deprivation, but in contrast to the receptor-mediated neuroprotection observed in vivo, this in vitro effect was not stereoselective and was insensitive to CB1 and CB2 receptor antagonists ” concluding ” Cannabinoids may have therapeutic potential in disorders resulting from cerebral ischemia, including stroke, and may protect neurons from injury through a variety of mechanisms .”
4.5 In a 1999 review of advances in cannabinoid research, Mechoulam [lii] noted ” A synthetic cannabinoid, HU-211, is in advanced clinical tests against brain damage caused by closed head injury. It may prove to be valuable against stroke and other neurological diseases ” Guzman et al [liii] observed ” One of the most exciting and promising areas of current cannabinoid research is the ability of these compounds to control the cell survival/death decision. Thus cannabinoids may induce proliferation, growth arrest, or apoptosis in a number of cells, including neurons, lymphocytes, and various transformed neural and nonneural cells .” Jin et al [liv] concluded ” These findings are consistent with a neuroprotective role for endogenous cannabinoid signaling pathways and with a potential therapeutic role in stroke for drugs that activate CB1 receptors “
5 Summary · Cardiovascular effects of Cannabis:
5.1 Cannabis increases heart rate in nave users although tolerance develops to this effect.
5.2 Cannabinoids can also reduce blood pressure via arteriollar dilatation in a variety of tissues, although the effect on blood flow varies at a local level, with some organs or brain regions experiencing vasoconstriction, others vasodilation.
5.3 In the withdrawal phase following cessation of chronic use, cerebral blood flow may be significantly reduced.
5.4 Cannabis use has been implicated as a causative factor in a small number of patients suffering strokes or transient ischaemic attacks, and may represent a risk factor to susceptible individuals.
5.5 However cannabinoids, in particular CB1-receptor agonists, have been shown to protect against nerve cell death following stroke, and dexanabinol at an advanced stage of the licensing process as a drug to be administered to victims of stroke or closed-head injuries to minimise the long-term brain damage caused by such events, and to improve survival and recovery prospects.
[i] Nahas G, Trouve R (1985) Effects and interactions of natural cannabinoids on the isolated heart. Proc Soc Exp Biol Med 180(2):312-6
[ii] Malit LA, Johnstone RE, Bourke DI, Kulp RA, Klein V, Smith TC (1975) Intravenous delta9-Tetrahydrocannabinol: Effects of ventilatory control and cardiovascular dynamics. Anesthesiology 42(6):666-73
[iii] Johnstone RE, Lief PL, Kulp RA, Smith TC (1975) Combination of delta9-tetrahydrocannabinol with oxymorphone or pentobarbital: Effects on ventilatory control and cardiovascular dynamics. Anesthesiology 42(6):674-84
[iv] Editorial (1978) Cannabis, 1977. Ann Intern Med 89(4):539-49
[v] Aronow WS, Cassidy J (1975) Effect of smoking marihuana and of a high-nicotine cigarette on angina pectoris. Clin Pharmacol Ther 17(5):549-54
[vi] Lawson TM, Rees A (1996) Stroke and transient ischaemic attacks in association with substance abuse in a young man. Postgrad Med J 72(853):692-3
[vii] Daisley H, Jones-Le Cointe A, Hutchinson G, Simmons V (1998) Fatal cardiac toxicity temporally related to poly-drug abuse. Vet Hum Toxicol 40(1):21-2
[viii] Bilfinger TV, Salzet M, Fimiani C, Deutsch DG, Tramu G, Stefano GB (1998) Pharmacological evidence for anandamide amidase in human cardiac and vascular tissues. Int J Cardiol 64 Suppl 1:S15-22
[ix] Belayev L, Busto R, Watson BD, Ginsberg MD (1995) Post-ischemic administration of HU-211, a novel non-competitive NMDA antagonist, protects against blood-brain barrier disruption in photochemical cortical infarction in rats: a quantitative study. Brain Res 702(1-2):266-70
[x] Nahas G, Trouve R (1985) op cit
[xi] Tashkin DP, Levisman JA, Abbasi AS, Shapiro BJ, Ellis NM (1977) Short-term effects of smoked marihuana on left ventricular function in man. Chest 72(1):20-6
[xii] Smiley KA, Karler R, Turkanis SA (1976) Effects of cannabinoids on the perfused rat heart. Res Commun Chem Pathol Pharmacol 14(4):659-75
[xiii] Jandhyala BS, Malloy KP, Buckley JP (1976) Effects of acute administration of delta9-tetrahydrocannabinol on pulmonary hemodynamics of anesthetized dogs. Eur J Pharmacol 38(1):183-7
[xiv] Daskalopoulos N, Schmitt H, Laubie M (1975) [Action of delta 9 tetrahydrocannabinol on the central cardiovascular regulation : mechanism and localization].[Article in French] Encephale 1(2):121-32
[xv] Kanakis C Jr, Pouget JM, Rosen KM (1976) The effects of delta-9-tetrahydrocannabinol (cannabis) on cardiac performance with and without beta blockade. Circulation 53(4):703-7
[xvi] Daskalopoulos N, Schmitt H, Laubie M (1975) op cit
[xvii] Tashkin DP, Levisman JA, Abbasi AS, Shapiro BJ, Ellis NM.  Short-term effects of smoked marihuana on left ventricular function in man. Chest 72(1):20-6
[xviii] Birmingham MK.  Reduction by 9-tetrahydrocannabinol in the blood pressure of hypertensive rats bearing regenerated adrenal glands. Br J Pharmacol 148(1):169-71
[xix] Williams RB, Ng LK, Lamprecht F, Roth K, Kopin IJ  9 -Tetrahydrocannabinol: a hypotensive effect in rats. Psychopharmacologia 28(3):269-74
[xx] Varma DR, Goldbaum D.  Effect of delta9-tetrahydrocannabinol on experimental hypertension in rats. J Pharm Pharmacol 27(10):790-1
[xxi] Nahas GG, Schwartz IW, Adamec J, Manger WM.  Tolerance of delta-9-tetrahydrocannabinol in the spontaneously hypertensive rat Proc Soc Exp Biol Med 142(1):58-60
[xxii] Mechoulam R, Carlini EA.  Toward drugs derived from cannabis Naturwissenschaften 65(4):174-9
[xxiii] Zaugg HE, Kyncl J.  New antihypertensive cannabinoids. J Med Chem 26(2):214-7
[xxiv] Hanus L, Breuer A, Tchilibon S, Shiloah S, Goldenberg D, Horowitz M, Pertwee RG, Ross RA, Mechoulam R, Fride E.  HU-308: a specific agonist for CB(2), a peripheral cannabinoid receptor. Proc Natl Acad Sci U S A 96(25):14228-33
[xxv] Garcia N Jr, Jarai Z, Mirshahi F, Kunos G, Sanyal AJ.  Systemic and portal hemodynamic effects of anandamide. Am J Physiol Gastrointest Liver Physiol 280(1):G14-20
[xxvi] Gardiner SM, March JE, Kemp PA, Bennett T.  Regional haemodynamic responses to the cannabinoid agonist, WIN 55212-2, in conscious, normotensive rats, and in hypertensive, transgenic rats. Br J Pharmacol 133(3):445-53
[xxvii] Gardiner SM, March JE, Kemp PA, Bennett T  Complex regional haemodynamic effects of anandamide in conscious rats. Br J Pharmacol 135(8):1889-96
[xxviii] Jarai Z, Kunos G.  [Cardiovascular effects of cannabinoids] [Article in Hungarian] Orv Hetil 143(26):1563-8
[xxix] Wagner JA, Jarai Z, Batkai S, Kunos G.  Hemodynamic effects of cannabinoids: coronary and cerebral vasodilation mediated by cannabinoid CB(1) receptors. Eur J Pharmacol 423(2-3):203-10
[xxx] Husain S, Khan I.  An update on cannabis research. Bull Narc 1985 Oct-Dec;37(4):3-13
[xxxi] Lake KD, Martin BR, Kunos G, Varga K.  Cardiovascular effects of anandamide in anesthetized and conscious normotensive and hypertensive rats. Hypertension 29(5):1204-10
[xxxii] Krowicki ZK, Moerschbaecher JM, Winsauer PJ, Digavalli SV, Hornby PJ.  Delta9-tetrahydrocannabinol inhibits gastric motility in the rat through cannabinoid CB1 receptors. Eur J Pharmacol 371(2-3):187-96
[xxxiii] Schiffrin EL.  A critical review of the role of endothelial factors in the pathogenesis of hypertension. J Cardiovasc Pharmacol 38 Suppl 2:S3-6
[xxxiv] Mathew RJ, Wilson WH.  Acute changes in cerebral blood flow after smoking marijuana. Life Sci 52(8):757-67
[xxxv] Tunving K, Thulin SO, Risberg J, Warkentin S.  Regional cerebral blood flow in long-term heavy cannabis use. Psychiatry Res 17(1):15-21
[xxxvi] Lundqvist T, Jonsson S, Warkentin S.  Frontal lobe dysfunction in long-term cannabis users. Neurotoxicol Teratol 23(5):437-43
[xxxvii] Ellis EF, Moore SF, Willoughby KA.  Anandamide and delta 9-THC dilation of cerebral arterioles is blocked by indomethacin Am J Physiol 269(6 Pt 2):H1859-64
[xxxviii] Bloom AS, Tershner S, Fuller SA, Stein EA.  Cannabinoid-induced alterations in regional cerebral blood flow in the rat. Pharmacol Biochem Behav 57(4):625-31
[xxxix] Stein EA, Fuller SA, Edgemond WS, Campbell WB.  Selective effects of the endogenous cannabinoid arachidonylethanolamide (anandamide) on regional cerebral blood flow in the rat. Neuropsychopharmacology 19(6):481-91
[xl] O’Leary DS, Block RI, Koeppel JA, Flaum M, Schultz SK, Andreasen NC, Ponto LB, Watkins GL, Hurtig RR, Hichwa RD.  Effects of smoking marijuana on brain perfusion and cognition. Neuropsychopharmacology 26(6):802-16
[xli] Cooles P, Michaud R.  Stroke after heavy cannabis smoking. Postgrad Med J 63(740):511
[xlii] Alvaro LC, Iriondo I, Villaverde FJ.  Sexual headache and stroke in a heavy cannabis smoker. Headache 42(3):224-6
[xliii] Lawson TM, Rees A.  Stroke and transient ischaemic attacks in association with substance abuse in a young man. Postgrad Med J 72(853):692-3
[xliv] McCarron MO, Thomas AM  Cannabis and alcohol in stroke. Postgrad Med J 73(861):448
[xlv] Mouzak A, Agathos P, Kerezoudi E, Mantas A, Vourdeli-Yiannakoura E  Transient ischemic attack in heavy cannabis smokers–how ‘safe’ is it? Eur Neurol 2000;44(1):42-4
[xlvi] Goldman H, Dagirmanjian R, Drew WG, Murphy S  delta9-tetrahydrocannabinol alters flow of blood to subcortical areas of the conscious rat brain. Life Sci 17(3):477-82
[xlvii] Pop E.  Dexanabinol Pharmos Curr Opin Investig Drugs 1(4):494-503
[xlviii] Leker RR, Shohami E, Abramsky O, Ovadia H.  Dexanabinol; a novel neuroprotective drug in experimental focal cerebral ischemia. J Neurol Sci 162(2):114-9
[xlix] Panikashvili D, Simeonidou C, Ben-Shabat S, Hanus L, Breuer A, Mechoulam R, Shohami E.  An endogenous cannabinoid (2-AG) is neuroprotective after brain injury. 413(6855):527-31
[l] Belayev L, Busto R, Watson BD, Ginsberg MD  Post-ischemic administration of HU-211, a novel non-competitive NMDA antagonist, protects against blood-brain barrier disruption in photochemical cortical infarction in rats: a quantitative study. Brain Res 702(1-2):266-70
[li] Nagayama T, Sinor AD, Simon RP, Chen J, Graham SH, Jin K, Greenberg DA.  Cannabinoids and neuroprotection in global and focal cerebral ischemia and in neuronal cultures. J Neurosci 19(8):2987-95
[lii] Mechoulam R.  Recent advantages in cannabinoid research. Forsch Komplementarmed 6 Suppl 3:16-20
[liii] Guzman M, Sanchez C, Galve-Roperh I.  Control of the cell survival/death decision by cannabinoids. J Mol Med 78(11):613-25
[liv] Jin KL, Mao XO, Goldsmith PC, Greenberg DA.  CB1 cannabinoid receptor induction in experimental stroke. Ann Neurol 48(2):257-61One of the most consistent effects of cannabis intoxication is an increased heart rate. However, THC also acts as a smooth-muscle relaxant, relaxing the walls of the arteries, which can result in…
How Medical Marijuana Acts as a Vasodilator
Home / Resources / Ailment Resources / How Medical Marijuana Acts as a Vasodilator
Updated on January 5, 2020. Medical content reviewed by Dr. Joseph Rosado, MD, M.B.A, Chief Medical Officer
While many patients and caregivers are familiar with the most common side effects of medical weed, such as giddiness and hunger, most are unaware of the beneficial effect of tetrahydrocannabinol (THC) as a vasodilator, which influences the treatment of several conditions, including glaucoma.
What Is a Vasodilator
A vasodilator is any substance that causes vasodilation, which is the widening of your blood vessels to improve blood flow to other parts of your body, such as your heart. While vasodilation also occurs naturally within the body, such as when you’re feeling faint, vasodilators are a part of modern medicine.
For example, you can treat high blood pressure with vasodilators — by expanding your blood vessels, your blood pressure decreases. Unlike prescription medications, however, medical cannabis is a natural vasodilator that interacts with your body’s receptors to initiate vasodilation.
Why Medical Cannabis Acts as a Vasodilator
Due to federal and state laws, it’s difficult for researchers to provide a specific answer as to why medical cannabis acts as a vasodilator. Like many of its effects, however, scientists believe it’s tied to the endocannabinoid system (ECS), which features cell receptors that bind with cannabinoids, like THC, to create a reaction.
As an example, consider this interaction of the ECS and cannabinoids in pain management. You consume medical marijuana, such as through smoking, and your body begins to process the medical weed. During that process, cannabinoids activate ECS receptors throughout your body to regulate reactions, such as chronic pain.
How Medical Marijuana-Induced Vasodilation Treats Conditions
Because of limited research opportunities, scientists are aware of only some of the instances where medical marijuana-induced vasodilation treats conditions and helps patients resume their daily lives or regain a sense of normalcy in their day-to-day activities.
Conditions that respond well to vasodilation include:
- Glaucoma: A primary side effect of glaucoma is pressure. Due to the ineffective drainage of fluid, eye pressure builds up, which can lead to blindness from optic nerve damage. With the natural vasodilation of medical weed and supportive lifestyle changes, intraocular pressure can decrease to a manageable level — and without the severe side effects of prescription treatments.
- High Blood Pressure: As the name reveals, high blood pressure or hypertension involves the increased demand placed on your heart and arteries to pump blood throughout your body. Like glaucoma, many patients use medical pot as a vasodilator and complement to their treatment plan, which will likely include diet and exercise.
- Nail-Patella Syndrome: One symptom of nail-patella syndrome is glaucoma. By incorporating medical marijuana into your treatment plan, you can lower your blood pressure by natural means, which will then offset and manage your intraocular pressure. As medical pot treats several other side effects of nail-patella syndrome, like chronic pain, it delivers a multi-faceted treatment plan.
With more research, scientists expect to discover additional beneficial uses of medical weed as a vasodilator.
Benefits of Medical Weed-Induced Vasodilation
Incorporating medical weed into your treatment plan for its role as a vasodilator offers several benefits, including:
- A more natural and effective approach
- Fast- or long-acting medicating options
- Strains that ease multiple symptoms
- Fewer and less severe side effects than prescription drugs
If you’re considering using medical pot because it’s a vasodilator, talk to your medical marijuana doctor first.
Learn More About Medical Cannabis and Vasodilation
At MarijuanaDoctors.com, we give families and patients valuable, up-to-date information on medical marijuana. From research studies and legislation changes to qualifying conditions and side effects, we compile and deliver it in a compact, easy-to-understand form for you and your family.
To learn more about medical cannabis and vasodilation, explore our resource library and blog!Many are familiar with the most common side effects of medical weed, like giddiness & hunger; most are unaware of its beneficial effect of vasodilation. ]]>