Cannabis,Cannabinoids and Cannabis-Based Medicines in Cancer Care

Introduction

At the time the inaugural issue of Integrative Cancer Therapies was published in 2002, 7 states had joined California in making medical cannabis available to patients seeking therapeutic benefit from this versatile botanical. Over the last 2 decades cannabis has been re-installed as a useful substance for medicinal and adult use throughout most of the nation, with medical cannabis available in 37 states and recreational cannabis in 18 states and the District of Columbia. Cancer is an indication for cannabis use in the majority of states that specify eligible medical conditions and oncologists generally support its use in both adults and children with malignant diagnoses.^1,2 As the main psychoactive component of the plant, delta-9-tetrahydrocannabinol (THC) was synthesized, licensed and approved for the treatment of chemotherapy-induced nausea and vomiting in 1986, oncologists theoretically may have the most experience recommending and prescribing a cannabis-based medicine.^3,4 The National Academies of Sciences, Engineering, and Medicine report on the Health Effects of Cannabis and Cannabinoids concluded that some of the strongest evidence for therapeutic benefit was for the use of cannabinoids in treatment of chemotherapy-induced nausea and vomiting.^5,6

Cannabis, however, still maintains its federal status as a Schedule I substance with high potential for abuse and no accepted medical use. The only legal source of cannabis for clinical research continues to be the National Institute on Drug Abuse despite the wide array of available products that can be obtained at sites selling cannabis in states where it is legal. ⁷ Sales of cannabis in the United States in 2020 were estimated at $17.5 billion despite still being considered illegal by the federal government. ⁸ Cancer patients are increasingly turning to the use of medical cannabis predominantly for symptom management, most commonly during the phase of active treatment.^9-15 The prevalence of recent cannabis use in patients with a variety of malignant diagnoses ranges from 18% to 40% in surveys conducted in the US, Canada and Israel. With such widespread use of cannabis in cancer patients, it behooves the oncologist to be informed about this widely used complementary botanical therapy.

Cannabis, Cannabinoids, and Cannabis-Based Medicines

The Cannabis sativa plant contains over 400 different chemical compounds.^3,5,16 Over 100 of these are 21-carbon terpenophenolic cannabinoids. ¹⁷ Delta-9-tetrahydrocannabinol (THC), the main psychoactive component, is found in highest concentration in the resin exuded from the flowers of the female plant. Cannabinol (CBN) is a degradation product of delta-9-THC which is felt to have soporific qualities although available quality evidence is limited. ¹⁸ Delta-8-THC was studied years ago in Israeli children receiving chemotherapy and was found to be an effective anti-emetic. ¹⁹ In the current era of isolating individual cannabinoids for potential therapeutic benefits, delta-8-THC is emerging as a popular favorite with questionable legal status as it is psychoactive. ²⁰ Cannabidiol (CBD) has catapulted to the top of the most favored cannabinoid list as it is felt not to be psychoactive but to have an array of other therapeutic benefits, although none have been particularly well documented in randomized controlled trials. ²¹ Purified CBD has been approved as a treatment for children with refractory epilepsy in the form of Epidiolex.^22,23 Cannabigerol (CBG) has also generated a significant amount of interest as a non-psychoactive cannabinoid that is also being touted as a bit of a panacea, absent supporting data from clinical trials. ²⁴

In addition to the cannabinoids, the plant also contains terpenoids which contribute to the diverse odors of different strains of cannabis and may also have therapeutic benefits in their own right.^17,25 Numerous flavonoids with potential health effects are also present. Many believe that, as opposed to attempting to isolate and study individual cannabinoids, it is the whole plant and the entourage effect of all of its components that is the most effective therapeutic intervention.^17,25

Dronabinol and nabilone are delta-9-THC medications that have been licensed and approved for the treatment of chemotherapy-induced nausea and vomiting since 1986.^26,27 Nabiximols is a whole plant extract with a THC:CBD ratio of 1:1 that is licensed and approved in much of the world besides the United States for treatment of spasticity associated with multiple sclerosis. ²⁸

Cannabinoid Receptors and Endocannabinoids

Two cannabinoid receptors have been identified in the human body- CB1 and CB2.^3,5,16,29 These are 7-transmembrane domain G-protein coupled receptors. They are encoded on separate genes and share less than 50% homology. The CB1 receptor is one of the most densely populated receptors in the human brain. The CB2 receptor was initially detected in macrophages and the marginal zone of the spleen with a high concentration in B lymphocytes and natural killer cells. Activation of the receptors inhibits adenylyl cyclase. The receptors have been identified in all animal species down to sea squirts. Animals have these receptors not because they were meant to use cannabis, but because, like endogenous opioids, endogenous cannabinoid also exist. The 2 endocannabinoids that have been most fully characterized are anandamide and 2-arachidonyl-glycerol (2-Ag). Endocannabinoids are produced on demand from membrane lipids and each is metabolized by a separate enzyme (anandamide by fatty acid amide hydrolase (FAAH) and 2-Ag by monoacylglycerol lipase (MAGL)). It has been suggested that the reason for the existence of the system of endocannabinoids and cannabinoid receptors is to facilitate the modulation of pain.

Therapeutic Use of Cannabis and Cannabinoids in Cancer Symptom Management

Cannabis as an Anti-Cancer Agent

There is much discussion on social media and in documentary films, mostly inaccurate, that cannabis itself has anti-cancer activity. ⁶⁵ This has led a minority of patients to shun conventional cancer treatments in favor of using highly concentrated oils of cannabis or isolated cannabinoids in hopes of curing their disease. There is increasing evidence from in vitro studies and animal models that cannabis and cannabinoids may have anti-tumoral activity that has not yet been convincingly translated into benefit in humans.^{3,16,43,66-72} One of the earliest reports published in the Journal of the National Cancer Institute was from Virginia Commonwealth University investigators who found that delta-9-THC, delta-8-THC and cannabinol all inhibited Lewis lung adenocarcinoma cells in vitro and in mice. ⁷³ CBD failed to inhibit the cell growth and appeared to enhance it. Since this early report, much of the work investigating the anti-cancer effects of cannabis and cannabinoids has been done in Europe and, increasingly, in Israel. Multiple tumor cell lines have been inhibited in vitro. Cannabinoid administration to nude mice curbs growth of a variety of tumor xenografts including gliomas, lymphoma, melanoma and lung, breast, colorectal, and pancreatic carcinomas. ⁷⁴ The National Academies of Sciences, Engineering, and Medicine report, however, concluded that there was “No or Insufficient Evidence” that cannabis has any activity against cancer as the committee’s charge was to review meta-analysis of clinical trials or high quality individual clinical trials. ⁵ At the time of the literature review, neither were available in the medical literature. The report did include a meta-analysis of 34 preclinical studies in gliomas where all but 1 study showed that cannabinoids selectively kill tumor cells without affecting normal neurons. ⁷⁵ The anti-cancer effects of cannabinoids in vitro have been elegantly described.^{3,16,43,66-75} Cannabinoids have direct tumor killing effects by complexing with the CB1 receptor. This interaction leads to autophagy and increased apoptosis. In addition, cannabinoids have been demonstrated to inhibit vascular endothelial growth factor, thereby impairing angiogenesis and decreasing tumor viability. In vitro studies also reveal that cannabinoids inhibit matrix mettaloproteinase-2 which allows cancer cells to become invasive and metastasize. Hence, pre-clinical evidence suggests that cannabinoids may inhibit tumor growth and proliferation by way of a number of mechanisms.

Despite an ever-increasing body of evidence that cannabinoids may have anti-tumor activity, some pre-clinical findings have been less encouraging. An Israeli team assessed antitumor effects of whole cannabis extracts containing significant amounts of differing phytocannabinoids on different cancer lines from various tumor origins. ⁷⁶ In the end, they chose 12 extracts to study in 12 cancer cell lines. They reported that specific extracts impaired survival and proliferation and induced apoptosis. The cannabis extracts were more effective than delta-9-THC alone. They found that cannabis extracts could differentially effect cancer cells and cancer cell lines derived from the same organ. Hence, one extract was effective against prostate cancer cell lines whereas another was not. Another investigator assayed expression of CB1 and CB2 in different human tumors. ⁷⁷ In some, overexpression of CB1 and/or CB2 was associated with worse prognosis, while in others it was associated with improved survival.

Proponents of the “cannabis cures cancer” movement often site isolated case reports in the medical literature as proof of their claims. On close review issues arise. In one instance, brain tumor patients received conventional therapies in addition to cannabidiol. ⁷⁸ Spontaneous tumor regression may explain the effect in 2 cases of partially resected pilocytic astrocytomas. ⁷⁹ Other cases put forth as illustrative do not, in fact, support cancer eradication.^80-82 A recent literature review identified 77 unique case reports describing patients with various cancers using cannabis as a treatment. ⁸³ The data supporting 81% of these cases was considered to be weak. The investigators have established an online, anonymous survey of patients using cannabis for its anticancer effect to assess the impact of the botanical against malignancies (www.catasurvey.com). Preliminary findings suggest that 4 in 10 patients believe cannabis improved control of their cancer.

Two case series have also been put forth as examples of the anti-tumor activity of CBD in particular. Data were collected from 119 patients at a London clinic over a 4-year period who were receiving pharmaceutical grade synthetic CBD oil averaging 10 mg twice a day, 3 days on, 3 days off. ⁸⁴ Clinical responses were described in 92% of the solid tumor patients, most of whom were also receiving conventional cancer treatments. Only 28 of the patients were receiving CBD alone and no data is presented on their outcomes. Despite the paucity of information presented, the authors suggest that CBD is a candidate for the treatment of breast cancer and brain tumor patients. The second case series describes 9 consecutive brain tumor patients in Vienna receiving pure phyto-CBD at a dose of 400 mg daily in addition to conventional therapy with resection followed by chemoradiation. ⁸⁵ Six of the patients had glioblastomas and 3 had lower grade tumors. The authors use a historical median survival of 14 to 16 months in glioblastoma patients compared to the observed 22.3 months mean survival in this cohort to suggest that the CBD was beneficial in this situation. It is not mentioned that the longer survival of the lower grade tumor patients may have skewed the mean value reported and not the use of the cannabinoid.

Clearly with the high concentration of CB1 receptors in the brain, treatment of central nervous system neoplasms with cannabis-based interventions seems a logical place to begin to investigate the potential anti-cancer effects. A study of 9 patients with recurrent glioblastoma was conducted in the Canary Islands. ⁸⁶ Treatment consisted of 20 to 40 μg of THC delivered via a catheter into the tumor bed for 15 days. The treatment was reportedly well-tolerated, but no difference in survival was noted compared to patients receiving chemotherapy alone. A recently reported Phase 1b trial investigated nabiximols and placebo in European patients with recurrent glioblastoma treated with dose-dense temozolomide. ⁸⁷ Nine of the 12 nabiximols and 6 of the 9 placebo recipients progressed by 6 months. Despite the similar progression rates, one-year survival was 83% for the nabiximols patients and 44% for the placebo group (P = .042), although the investigators state that the small early-phase study was not powered for a survival endpoint. Nonetheless, the trend persisted so that at 2 years 50% of the nabiximols recipients were still alive compared to 22% of the placebo group (P = .134). A larger follow-on study is being launched.

An Australian tolerability study of a single nightly dose of 2 cannabis oils in patients with high grade gliomas receiving standard therapies was recently reported. ⁸⁸ Participants received treatment with oil-based whole plant extracts of cannabis with THC:CBD ratios of either 1:1 or 4:1. Of the 88 participants enrolled, 90% had glioblastomas and 10% anaplastic astrocytomas. Sixty-one patients completed the 12-week study. Physical and functional domains of quality of life and sleep were all improved in the THC:CBD 1:1 ratio group compared to the 4:1. Although the primary objective was to assess the tolerability of the 2 ratios, MRIs were completed at baseline and 12 weeks in 53 participants as disease status was a secondary outcome. At 12 weeks, 11% had a reduction in disease, 34% had stable disease, 16% had a T2 flair and slight enhancement, and 10% had progressive disease. No difference in outcomes was seen between the groups.

Oncologists’ Concerns About Cannabis use in Cancer Patients

A random survey was sent to 400 US oncologists with a 63% response rate. ¹ Eighty percent of the respondents reported that they discuss cannabis with their patients; for 78% these discussions were patient initiated. Two-thirds of the oncologists felt that cannabis was a useful adjuvant for pain and anorexia/cachexia, but only 46% ever recommend it clinically. This may be due to the fact that only 30% responded that they felt sufficiently informed to make recommendations. It also may be a reflection of concerns that oncologists may have regarding the use of cannabis by patients with cancer. The concept of inhaling a combusted botanical is likely to raise a red flag. In fact, the review of the published literature on cancer causation summarized in the National Academies of Sciences, Engineering, and Medicine report concluded that there was moderate evidence of no statistical association between cannabis smoking and the risk of lung or head and neck cancers. ⁵ Isolated reports suggesting that cannabis smoking increased both of these tobacco-related malignancies have appeared over the years in the medical literature, but the analysis of the total body of published literature failed to support such observations. The report did note that there was limited evidence of a statistical association between current, frequent or chronic cannabis smoking and non-seminoma testicular cancer. The statistical association does not imply causation, however. It may be similar to the fact that there are increased drowning deaths in months where ice cream is over-consumed. Similar associations between the use of cannabis and risk of cancer were described in a systematic review including studies published after the National Academies of Sciences, Engineering, and Medicine’s review was concluded. ⁸⁹

Pulmonary aspergillosis is another concern that oncologists may have about cancer patients smoking cannabis. The first such case was reported in the medical literature by a young NIH fellow named Anthony Fauci. ⁹⁰ Since that time there have been numerous isolated case reports of patients with various malignancies or other immunocompromised states developing aspergillosis presumably secondary to smoking cannabis. ⁵ A case control series involving 19 HIV patients with positive aspergillus isolated from their bronchoalveolar lavage was reported. ⁹¹ The investigators concluded that the positive finding was associated with absolute neutrophil count less than 1000/mm³, CD4+ lymphocyte count less than 50/mm³, steroid use and prior Pneumocystis infection; cannabis use was not associated.

THC and CBD may both impact the metabolism of other pharmaceuticals and botanicals by way of cytochrome p450 interactions. ⁹² To date, very few pharmacokinetic interaction studies have been investigated to evaluate the effects of cannabis or isolated cannabinoids on blood levels of conventional cancer therapies. One study of a cannabis tea found no interaction with levels of irinotecan and docetaxel. ⁹³ As CBD is a potent inhibitor of many isoforms involved in the metabolism on many prescription drugs, there is a theoretical possibility that patients using highly concentrated CBD oils to treat their malignancy may inhibit the metabolism of conventional therapies conceivably leading to increased toxicity.^92,94 With the wide range of CBD doses accessed by patients from dispensaries, many patients use small amounts of the cannabinoid that are unlikely to cause a pharmacokinetic interaction. However, those using higher doses of CBD and/or THC may potentially precipitate a clinically significant interaction. Oncologists should caution patients about this possibility.

An observational study from Israel concluded that concomitant use of cannabis in association with immune checkpoint inhibitors may detract from the clinical effectiveness of the immunotherapy without impacting survival. ⁹⁵ A more recent prospective observational study from this group yielded a more concerning outcome. ⁹⁶ The study included 68 patients with metastatic disease beginning immunotherapy who were not using cannabis and 34 who were. Cannabis use was started from 9 months to 2 weeks prior to commencing immunotherapy. Non-small cell lung cancer and melanoma were the most frequent diagnoses. The investigators reported that the patients using cannabis had a median time to tumor progression of 3.4 months compared to 13.1 months in those who were not (P = .0025). In addition, the median survival was 6.4 months in those using cannabis and 28.5 months in those who were not (P = .00094). That cannabis use could have such a dramatic impact on both disease progression and survival seems astounding. A statistically significant difference between the 2 groups in this non-randomized observational analysis was that 24% of those using cannabis were receiving immunotherapy as first line therapy compared with 46% of those who were not using cannabis (P = .03). The fact that the majority of those using cannabis were receiving immunotherapy as a second or third-line intervention could explain some of the divergence in outcomes. The investigators also note that the cannabis users had less immune-related adverse events, perhaps due to an anti-inflammatory effect of the cannabis which may have also dampened the effectiveness of the immunotherapy. The investigators concluded that “cannabis consumption should be carefully considered in patients with advanced malignancies treated with immunotherapy.” As randomized placebo-controlled trials investigating this important question would be difficult to conduct, the results of this study should be shared with patients receiving immunotherapy who may be considering cannabis use.

Conclusions

Despite a dearth of published evidence related to barriers to research, botanical cannabis may be a useful adjunct to standard treatment in alleviating side effects of cancer or its treatment, but further research to produce convincing evidence is needed. Although preclinical findings are promising, there is little support in the medical literature to date for anti-tumor activity of cannabis or cannabinoids. As more tumors are assayed for actionable mutations, it may be of benefit to considering routinely assaying specimens for CB1 and CB2 expression to better understand their relationship to disease progression and response to therapy. ⁹⁷ More research should be done exploring the impact of cannabis-based therapies on malignant tumors. Oncologists’ concerns about cannabis use by patients with cancer can mostly be allayed as most controlled trials report predominantly low-grade adverse effects. More pharmacokinetic information on highly concentrated preparations of cannabis or cannabinoids on conventional cancer treatments would be useful. A caution regarding the use of cannabis in patients receiving immunotherapies is prudent. More research and education is always warranted to allow oncologists to better understand how this versatile botanical and its derivative compounds may benefit their cancer patients.