Exploring the Use of Medical Marijuana for Supportive Care of Oncology Patients

The Endocannabinoid System

The endocannabinoid system (ECS) consists of endocannabinoids (eCBs), cannabinoid receptors, endogenous ligands, and enzymes used for their production and degradation. eCBs are also referred to as endogenous cannabinoids. Arachidonoyl-ethanolamide (AEA), also known as anandamide (named after the Sanskrit word for bliss), and 2-arachidonoylglycerol (2-AG) are eCBs produced by both humans and animals (except for insects). They are lipophilic molecules synthesized mainly in the postsynaptic membranes of the brain. They serve as primary messengers across nerve synapses and are synthesized on demand (Bridgeman & Abazia, 2017; Di Marzo et al., 1998; Nahtigal et al., 2016; Pacher et al., 2020; Sarfaraz et al., 2008; see Figure 1).

Figure 1

Cannabinoids. Anandamide and 2-AG are the two major endocannabinoids produced endogenously in the body. Reprinted with permission from www.leafly.com/news/science-tech/what-is-the-endocannabinoid-system

Two endogenous cannabinoid receptors have been identified: CB1 and CB2. The CB1 receptors are found mostly in the brain (specifically the basal ganglia and limbic system but also the hippocampus and cerebellum), peripheral nervous system, as well as in the liver, stomach, heart, and in male and female reproductive systems. Notably, they do not exist in the brain stem area controlling respiration, so lethal overdoses due to respiratory depression do not occur.

The CB2 receptors are found mostly in the immune system, particularly the spleen. Simulation of eCBs is thought to promote homeostasis of five key functions: eating, sleeping, relaxing, forgetting, and protecting (Bridgeman & Abazia, 2017; Di Marzo et al., 1998; Nahtigal et al., 2016; Pacher et al., 2020; Sarfaraz et al., 2008).

Phytocannabinoids are plant-derived cannabinoids such as THC and CBD and are found in the marijuana plant Cannabis sativa L. More than 140 cannabinoids have been isolated, and there are thousands of medical marijuana strains referred to as “chemovars.” Each chemovar has varying concentrations of cannabinoids and other components. THC is the primary cannabinoid responsible for the psychotropic and intoxicating effects of medical marijuana. THC-dominant sativa strains produce uplifting, energizing cerebral effects; THC-dominant indica strains have sedating, relaxing cerebral effects; and hybrid chemovars fall in between. CBD has mild mood-altering psychotropic activity but does not cause intoxication. CBD binds to receptors adjacent to THC, thus modulating its effects. To take advantage of this, medicinal preparation with specific CBD to THC ratios are produced by licensed companies and medical marijuana growers. Other phytocannabinoids, including cannabinol (CBN), cannabigerol (CBG), and cannabichromene (CBC), also appear to have biological effects and are being investigated for therapeutic use. Additionally, more than 200 terpenoids or terpenes have been found in specialized structures called trichomes, which are epidermal projections on the medical marijuana plant. Terpenes are the main component of the essential oils of plants and flowers. They work synergistically with cannabinoids, creating what is referred to as the “entourage effect.” This refers to the idea that plants as a whole can be better drugs than individual compounds derived from them. Some terpenes found in many medical marijuana plants are (The NCSBN Medical Marijuana Guidelines Committee, 2018; Pacher et al., 2020; Sarfaraz et al., 2008):

• • Limonene, which has anxiolytic and antidepressant effects.

• • Myrcene, which has anti-inflammatory, analgesic, and sedative effects.

• • α-pinene, which has anti-inflammatory, antibacterial and bronchodilator effects, as well as the ability to counteract short-term memory defects induced by too much THC.

• • Linalool, which has anxiolytic effects.

• • β-caryophyllene, which has gastroprotective and anti-inflammatory effects.

• • Ocimene, which has possibilities as an antibiotic.

• • Terpinolene which, in preclinical studies, has potential as an antibiotic and may have antitumor activity.

Patients who want medical marijuana to treat a particular condition can utilize the terpene profile in the CoA to aid in finding the right product.

Synthetic cannabinoids are those developed in the laboratory. Dronabinol (used to treat chemotherapy-induced nausea and vomiting [CINV] and decreased appetite) and nabilone (used to treat severe CINV) are synthetic preparations of THC.

The cannabidiol oral solution, Epidiolex, is a purified plant-derived preparation of CBD used to treat seizures associated with Lennox-Gastaut syndrome, Dravet syndrome, or tuberous sclerosis complex in patients who are 1 year old or older. THC and cannabidiol (Sativex), also a plant-derived preparation, is a CBD to THC 1:1 ratio oral mucosal spray used for muscle spasms associated with multiple sclerosis. It is not approved in the United States (Kleckner et al., 2019).

Pharmacokinetics

The pharmacokinetics (PK) of medical marijuana vary with the method of administration (see Table 4 for a quick guide to PK). The PK of THC in humans has been evaluated after inhalation (smoking or vaporization) and ingestion. The onset, rate of absorption, and bioavailability are increased after inhalation. THC has been detected in the plasma after the first inhalation, and peak plasma concentrations are achieved after 5 to 10 minutes. Bioavailability of inhaled THC ranges from 2% to 56%. It is thought that up to 50% of the inhaled dose is lost due to pyrolysis and side stream smoke. Factors affecting PK of inhaled THC are the volume of each puff, the duration of time that the puff is held, and the temperature of the vaporizer. Recommended temperatures for vaporizers range from 350°F to 400°F. Temperatures above 400°F may cause the release of the carcinogenic agent benzene and other toxins. Duration of action of inhaled THC is 2 to 4 hours. The rapid action of inhaled medical marijuana makes it ideal for acute or episodic symptoms. Chronic use is associated with respiratory symptoms such as cough, phlegm, and bronchitis, but not lung cancer or chronic obstructive pulmonary disease (COPD) unless patients also use tobacco (Tashkin, 2013). It is felt that vaporization produces less harmful byproducts than smoking and produces decreased pulmonary symptoms (Bridgeman & Abazia, 2017; MacCallum & Russo, 2018; Nahtigal et al., 2016; National Academy of Sciences, 2017). Patients should wait 10 to 15 minutes between puffs to avoid overconsumption and unwanted effects.

Oral consumption and metabolism of medical marijuana “edibles” is much slower and less predictable. The onset of action may be 30 to 90 minutes, with peak levels between 1 to 6 hours and a duration of 4 to 10 hours. Bioavailability after ingestion is 4% to 20%. Oral medical marijuana undergoes significant first-pass hepatic metabolism by the CYP450 gene where delta-9-THC is converted to 11-hydroxy-THC, which is a longer-lasting and more potent cannabinoid. Cannabinoids are lipophilic so are best absorbed in the presence of fats, oils, or polar solvents. Therefore, recent meals may affect absorption. Oral routes are popular due to convenience, more accurate dosing, and are good for chronic symptoms; however, they are more difficult to titrate (Bridgeman & Abazia, 2017; Dolce & Chin, 2018; MacCallum & Russo, 2018; Nahtigal et al., 2016).

Oral mucosal preparations have on onset of 15 to 45 minutes if held sublingually and last 3 to 4 hours; the onset is 90 minutes if swallowed and lasts 6 to 8 hours. Topical preparations such as salves are used for local pain such as that from dermatologic or arthritic conditions and have a variable onset of action and duration. Newer transdermals using nanoparticles or ionized particles may have enhanced and time-released absorption. Their onset is usually within 15 minutes and may last up to 48 hours depending on dose.

A less popular form of medical marijuana is suppositories. THC-hemisuccinate is the form of THC that has the best rectal absorption. Suppositories could be helpful for palliative care, patients who cannot swallow, gastrointestinal illnesses, and for healing skin damaged by rectal radiation. Onset of action is about 15 minutes and the effect may last up to 12 hours (Backes, 2017; Dolce & Chin, 2018; MacCallum & Russo, 2018; see Table 2 for dosing strategies and Table 4 for a guide to PK).

Adverse Effects of Medical Marijuana

In general, medical marijuana is considered safe and well tolerated (Bar-Lev Schleider et al., 2018; Kleckner et al., 2019; MacCallum & Russo, 2018; Ware al., 2015). An Israeli study of 2,970 cancer patients found that 30% of patients reported at least one side effect from medical marijuana at 6 months, but that the side effects were relatively minor: dizziness, dry mouth, increased appetite, sleepiness, and psychoactive effects. Most patients reported fewer side effects as well as less severe side effects than with their prescription medications (Bar-Lev Schleider et al., 2018). Ware and colleagues (2015) prospectively studied safety issues using a standardized medical marijuana product (12.5% THC) in patients who did not have cancer but were being managed in chronic pain clinics. Patients could choose the route of administration. The patients were compared with patients in the same clinics who did not use medical marijuana and were followed for 1 year. They found no significant difference in the occurrence of serious adverse effects.

Adverse effects are related primarily to THC and are dose dependent. THC administered with CBD reduces psychoactive side effects. Side effects of THC such as fatigue, tachycardia, and dizziness are often avoidable when the starting dose is low and titration is slow. Slow titration also decreases the incidence of psychoactive side effects. There have been no reported deaths due to overdose due to the lack of CB1 receptors in the cardiorespiratory centers of the brainstem (MacCallum & Russo, 2018).

The most common adverse effects reported are drowsiness and fatigue, dizziness, dry mouth, anxiety, nausea, cognitive effects (alteration in perception, time distortion, memory and attention), and cough or bronchitis if smoked. Euphoria, blurred vision, and headache are also common. Rare side effects are orthostatic hypotension, paranoia, toxic psychosis, depression, ataxia, tachycardia, diarrhea, and medical marijuana hyperemesis syndrome (Kleckner et al., 2019; MacCallum & Russo, 2018). Medical marijuana hyperemesis syndrome is most often seen in patients under 50 years old with a long history of marijuana use. These patients present with severe, cyclic nausea and vomiting. Cessation of marijuana, long, hot showers or baths, and capsaicin applied to the abdomen are recommended to relieve the symptoms (Lapoint, 2014; The NCSBN Medical Marijuana Guidelines Committee, 2018). Allergies to cannabis have also been reported. They are immunoglobulin E (IgE) mediated and vary depending on the route of administration (Kleckner et al., 2019).

Cannabis use disorder (CUD) is a term used when medical marijuana use leads to significant impairment or distress. Long-term medical marijuana use can lead to addiction; 9% of users are at risk (The NCSBN Medical Marijuana Guidelines Committee, 2018). Adolescents are at greater risk, as are persons with persistent negative emotions and psychological distress (The NCSBN Medical Marijuana Guidelines Committee, 2018). Medical marijuana withdrawal syndrome is usually seen in patients with heavy, prolonged use. Symptoms may include insomnia, lack of appetite, restlessness, anxiety, irritability, anger, depression, physical discomfort, and unpleasant dreams (The NCSBN Medical Marijuana Guidelines Committee, 2018).

Chronic Pain

Pain is one of the most common symptoms in patients with cancer and has a negative impact on patients’ activities of daily living and quality of life. Pain is reported in up to 60% of patients being actively treated for cancer and up to 90% of those with advanced disease (Boland et al., 2020). There is evidence that cannabis affects both sensation and perception of pain. CB1 receptors are located on nociceptors, allowing medical marijuana to have a direct effect on nociceptors in the periphery. CB1 and CB2 receptors in the nervous and immune systems allow for additional modulation of pain sensation (Kleckner et al., 2019). Additionally, medical marijuana is known to have a euphoric effect, so it may increase a subjective sense of well-being that may decrease the perception of pain.

Various systematic reviews arrive at conflicting opinions on the helpfulness of medical marijuana in reducing pain. The National Academy of Sciences concluded that there is substantial evidence that medical marijuana is an effective treatment for chronic pain in adults (National Academy of Sciences, 2017). Another systematic review and meta-analysis of 28 studies using various formulations of medical marijuana demonstrated a nonsignificant improvement in pain control (Whiting et al., 2015). Davis (2016) looked at multiple studies of low to moderate quality and reported a modest reduction in cancer pain. Ware and colleagues (2015) compared outcomes for over a year in a study of 215 patients with chronic noncancer pain who used a standardized preparation of medical marijuana administered by whatever route the patient chose. There was a comparison group of 216 patients with chronic noncancer pain who did not use medical marijuana. They found a significant reduction in pain intensity reported on the 0 to 10 numerical rating scale, as well as an improvement in physical function in the medical marijuana group but not in the control group. However, Boland and colleagues (2020) reported in their systematic review and meta-analysis that the addition of medical marijuana to opiates in patients with advanced cancer did not decrease pain.

Two recent studies showed significant relief in pain. Bar-Lev Schleider and colleagues (2018) assessed pain intensity and quality of life in more than 1,000 patients and demonstrated a significant reduction in pain in those using medical marijuana. Prior to use, 52.9% of the patients reported their pain to be between 8 to 10 on a 0 to 10 pain scale where 0 is no pain and 10 is intense pain; after 6 months, only 4.6% of patients reported pain at this intensity. Patients also said their quality of life improved; 18.7% reported a good quality of life before starting medical marijuana, while 69.5% reported a good quality of life 6 months later (Bar-Lev Schleider et al., 2018). Another retrospective study of 244 patients reported a decrease in opioid use of 64%, less drug-related side effects, and an improved quality of life (Kleckner et al., 2019).

The exact pathway in which medical marijuana acts to relieve the symptoms of chemotherapy-induced peripheral neuropathy (CIPN) is not known. However, preclinical studies in rats have presented evidence that CBD plays a role in reducing neuropathic pain. Studies in rats have shown that a CB1/CB2 receptor agonist both reduced paclitaxel-induced thermal hyperalgesia and tactile allodynia by activating CB1 and CB2 receptors. The same agonist also prevented vincristine- induced neuropathy (Kleckner et al., 2019).

Placebo-controlled trials in patients with chronic neuropathic pain from various etiologies other than cancer have been conducted. Patients reported that smoking medical marijuana significantly decreased neuropathic pain when compared with placebo (Kleckner et al., 2019).

Nausea and Vomiting

Chemotherapy-induced nausea and vomiting is highly prevalent. Although modern regimens are effective at preventing vomiting, 40% to 75% of patients still report nausea when highly or moderately emetogenic chemotherapies are administered (Bar-Lev Schleider et al., 2018; Kleckner et al., 2019). Dronabinol and nabilone are FDA- approved for the treatment of CINV in patients who have not responded adequately to conventional antiemetic therapy, and the National Comprehensive Cancer Network (NCCN) Guidelines on antiemesis (2020) list dronabinol and nabilone as agents that can be added for breakthrough treatment of CINV.

It is hypothesized that cannabinoids, specifically CBD, exert their antiemetic effect through modulation of the 5-HT₃ and 5-HT_1A receptors. Additionally, cannabinoids modulated the release of substance P in preclinical studies (Kleckner et al., 2019). The National Academy of Sciences (2017) decided that there is conclusive evidence that oral cannabinoids are effective antiemetics for the treatment of CINV (National Academy of Sciences, 2017). In his systematic review, Davis (2016) concluded that nabilone was a better antiemetic than the older drugs domperidone, chlorperazine, and alizapride, but noted there were no comparisons between medical marijuana and the serotonin receptor antagonists. He also pointed out that there have been no direct comparisons to olanzapine and aprepitant, which are both effective drugs for breakthrough nausea and vomiting. Whiting and colleagues (2015) assessed 28 studies comparing medical marijuana with a variety of antiemetics including ondansetron. They found that the average number of patients showing a complete nausea and vomiting response was greater with medical marijuana than with placebo and that there was a nonsignificant greater benefit of medical marijuana compared with the other active comparators. There is also evidence that nabilone is somewhat effective in managing nausea and vomiting related to radiation therapy and anesthesia after abdominal surgery (Abrams & Guzman, 2014).

More recent clinical evidence supports patient claims that cannabis relieves CINV. Bar-Lev Schleider and colleagues (2018) reported that 1,662 patients in their study used medical marijuana (as an oil or flower, capsules, or cigarettes) for CINV. At 6 months, 36.3% of patients reported no more nausea or vomiting, 54.7% claimed symptom improvement, and 9% reported no change (Bar-Lev Schleider et al., 2018). A study by Reblin and colleagues (2019) looked at medical marijuana use in patients with gliomas treated at a comprehensive cancer center in Florida. Thirteen patients used medical marijuana (smoked or ingested THC, CBD only, or THC and CBD oil) for the treatment of nausea; 12 reported symptom relief and 1 reported no effect (Reblin et al, 2019). A study of patients enrolled in Minnesota’s medical marijuana program (which allows vapes, capsules, oral solutions, and topical agents) revealed that 40.5% of patients complaining of nausea achieved 30% or greater improvement in symptoms within 4 months and that 49.8% of patients complaining of vomiting achieved a 30% or greater improvement of symptoms in 4 months (Anderson et al., 2019).

The route of delivery must be considered when using medical marijuana for treating nausea and vomiting. A nonoral route is preferred so that the drug has more opportunity to be retained (not expelled) and to reach the target site.

Anorexia and Decreased Appetite

Anorexia and weight loss in cancer patients lead to a poorer quality of life and decreased survival. Dysgeusia is also a common complaint among patients undergoing chemotherapy as well as those with advanced cancer. It is possible that CB1 receptors in the hypothalamus, hindbrain, limbic system, intestinal system, and adipose tissue modulate peptides involved in appetite regulation (Kleckner et al., 2019). Thus, it is possible that medical cannabis may stimulate the orosensory reward pathway and increase the enjoyment of food.

The National Academy of Sciences (2017) did not find enough evidence to support or refute the use of cannabis as a treatment for decreased appetite or anorexia-cachexia syndrome in cancer patients. However, they did conclude that there is limited evidence supporting its use in increasing appetite and decreasing weight loss in patients with human immunodeficiency virus/acquired immunodeficiency syndrome (HIV/AIDS; National Academy of Sciences, 2017). Davis (2016) reports two small trials and a small case series with medical marijuana where appetite was improved and weight loss was slowed in patients with cancer. However, a large, randomized trial revealed megestrol as superior to dronabinol in increasing appetite (Davis, 2016). There are also animal studies that show that THC and other cannabinoids stimulate appetite and increase food intake. For example, anandamide enhanced appetite in mice and rats.

However, there is some clinical evidence showing that medical marijuana can help increase appetite and improve dysgeusia in adult cancer patients. In 2011, Brisbois and colleagues reported on a randomized trial comparing oral tetrahydrocannabinol to oral placebo. They found the tetrahydrocannabinol significantly heightened chemosensory perception of food resulting in the perception that food “tasted better.” Also, premeal appetite and the number of calories eaten as protein increased. Bar-Lev Schleider and colleagues (2018) reported that 1,453 patients in their study utilized medical marijuana for lack of appetite. 25.8% said the symptom disappeared at 6 months, 62.1% reported improvement, and 12.1% reported no change (Bar-Lev Schleider et al., 2018). Reblin and colleagues (2017) reported on 12 patients who used medical marijuana as an appetite stimulant, and all reported symptom relief. In the Minnesota study by Anderson and colleagues (2019), 1,000 patients reported a lack of appetite, and 38.8% achieved a 30% or greater improvement in appetite within 4 months of initiating the use of medical marijuana. In addition, a randomized study of 47 patients from the National Cancer Institute of Canada found that, after 8 weeks, patients who were given nabilone had a significantly increased caloric intake compared with those given placebo (Turcot et al., 2018).

Medical marijuana may be a good option for cancer patients to try, because the recommended drugs (megestrol acetate, metoclopramide, and steroids) are only recommended for short-term use due to side effects. Dronabinol use is not limited. It is important to note that although medical marijuana may increase appetite and caloric intake, it may not necessarily reverse the cancer cachexia related to energy wasting (Abrams & Guzman., 2014; Kleckner et al., 2019).

Sleep Disorders and Fatigue

Sleep disorders (insomnia, difficultly falling and staying asleep, or unrestful sleep) are complaints of approximately 80% of patients with cancer. Additionally, patients with cancer-related fatigue have a high incidence of sleep disorders. Animal studies have shown that endogenous cannabinoids regulate the circadian rhythm; for example, there is evidence in rats that 2-AG level is highest during the light phase of the dark-light cycle, while AEA is higher during the dark phase (Kleckner et al., 2019).

There is moderate evidence that medical marijuana helps sleep disorders due to chronic illness (National Academy of Sciences, 2017). The evidence that assesses medical marijuana’s effect on sleep and fatigue derives from studies of patients with other chronic disorders: irritable bowel disease, fibromyalgia, Crohn disease, Parkinson disease, multiple sclerosis, and post-traumatic stress syndrome. These patients reported less fatigue and sleep disturbances than patients not using medical marijuana (Kleckner et al., 2019).

Studies in patients with cancer have evaluated the effect on sleep and fatigue as secondary outcomes. Turcott and colleagues (2018) studied the effect of nabilone on appetite in a randomized controlled trial and found that patients using nabilone reported a significant decrease in insomnia. In the Bar-Lev Schleider and colleagues study (2018), 2,329 patients used medical marijuana for sleep problems: The sleep problem went away in only 16.7% of patients, but 70.8% reported improvement, while 12.3% reported no relief. In the same study, 2,160 patients used medical marijuana for weakness and fatigue. Only 10.9% reported the symptoms went away, while 55.9% reported improvement and 33.2% reported no improvement (Bar-Lev Schleider et al., 2018). In a study by Anderson and colleagues (2019) in Minnesota, it was reported that of 1,073 patients with disturbed sleep, 41.8% claimed a 30% or more improvement within the first 4 months. In this same study, of the 1,113 patients reporting fatigue, only 27% had an improvement of 30% or more after 4 months. Reblin and colleagues (2019) had only 2 patients using cannabis as a sleep aid, but both found relief from medical marijuana.

Gastrointestinal Distress

Gastrointestinal (GI) distress (abdominal pain, bloating, cramps, constipation, diarrhea, or flatulence) are common in patients with cancer, particularly in those undergoing chemotherapy and with advanced cancer. However, there is not a lot known about how medical marijuana may modulate GI symptoms or its efficacy in treating them. It is hypothesized that medical marijuana moderates the inflammatory cytokines produced by cancer and chemotherapy or via a direct effect on the endocannabinoid systems that helps regulate gut motility and peristalsis (Kleckner et al., 2019). A study by Bar-Lev Schleider and colleagues (2018) evaluated the 1,918 patients who complained of digestive problems. After 6 months of medical marijuana use, the problems disappeared in 26.7% of the patients, improved in 50.3% of the patients, and did not help 23% of the patients.

Cognitive Impairment

Cognitive impairment is a common complaint in patients with cancer. Kleckner and colleagues (2019) reported that up to 30% of patients report cognitive impairment before treatment even starts, and that number increases to 75% during treatment. Unfortunately, research is lacking on the effect of medical marijuana and cognitive impairment. Patients have reported that moderate to large doses of medical marijuana cause acute impairment in memory and attention, but it appears these effects are temporary. In fact, the study by Ware and colleagues (2015) on the safety of using medical marijuana as a treatment for pain found that neurocognitive tests showed significant improvement after 6 and 12 months both in the group using medical marijuana and the group that did not. There is also some preclinical evidence that CBD can reverse age-related cognitive impairment in rats; and, in older mice, low dose THC restored learning and improved spatial learning and memory (Kleckner et al., 2019).