how much cbd oil for cancer treatment

Lung Cancer Tumor Shrinks After CBD Use

One of medical marijuana’s most promising uses is for the treatment of cancer. Cancer forms when the body’s cells begin to rapidly divide and multiply, eventually resulting in the growth of tumors. Current cancer treatments are both invasive and physically taxing. Marijuana has proven to be effective for dealing with symptoms of cancer treatment such as nausea and vomiting, but it may also have significant effects on cancer itself by slowing, stopping and even reversing the growth of cancerous tumors.

CBD and Lung Cancer Tumors

Lung cancer is a particularly difficult cancer to treat, as many patients fail to respond fully to treatment, which results in an eventual relapse. However, a recent study of an 81-year-old man with lung cancer suggests that cannabidiol (CBD), a naturally produced marijuana chemical compound, may help reverse the growth of tumors.

This particular patient had chosen not to receive chemotherapy or other cancer treatments because he was concerned that they would take a toll on him that would decrease his quality of life. Instead, he chose to use CBD oil twice a day. Within only two months, the tumor in the patient’s lung underwent a “significant reduction in size” to what doctors described as a “near total resolution.”

Initial scans of the man, who was diagnosed with lung adenocarcinoma in October 2016, showed a 2.5 by 2.5cm cancerous tumor in his left lung. A second scan conducted in December 2016 revealed the lung mass had increased in size to 2.7 by 2.8cm. However, in November 2017, something interesting happened:

Medical scans revealed the tumor had shrunk to just 1.3 by 0.6cm.

Curious, doctors asked the patient about any recent lifestyle changes. The man revealed he had started taking CBD oil (200mg of CBD/every 10ml) in September, just two months before his tumor decreased in size.

The man started with two drops twice a day for a week, before increasing his dose to nine drops twice a day until the end of September. No other changes in diet, medication or lifestyle were noted.

Ian Hamilton, a drug researcher at the University of York, who did not treat the patient, calls the report “important,” adding:

I think there is real potential with CBD but there is also a lot of false hope being given. This kind of case study is important but is unlikely to change medical practice. It will need a larger randomized control trial, which would help distinguish how much is down to the placebo effect.

The researchers who documented the case agree, concluding:

In summary, the data presented here indicate that CBD may have had a role in the striking response in a patient with histologically proven adenocarcinoma of the lung as a result of self-administration of CBD oil for a month and in the absence of any other identifiable lifestyle, drug or dietary changes.

Further work is needed both in vitro and in vivo to better evaluate the various mechanisms of action of CBD on malignant cells, and its potential application in the treatment of not only lung cancer but also other malignancies.

How Does Marijuana Fight Cancer?

Marijuana includes many natural cannabinoids, such as CBD and tetrahydrocannabinol (THC), which are able to interact with the body’s endocannabinoid system to stimulate appetite, relieve pain and produce many of the other medicinal benefits of marijuana. In addition to cannabinoids, the endocannabinoid system is also comprised of two main cannabinoid receptors, referred to as CB1 and CB2. These receptors are responsible for triggering many of the effects of cannabis.

Marijuana was first identified as a potential cancer treatment by a study performed on mice in 1975. The study found that the growth of tumors in mice either slowed or stopped with the administration of THC.

A later study found that suppressing CB1 receptor activity led to the acceleration of tumor growth, suggesting a link between the endocannabinoid system and cancer.

Marijuana can also serve as an effective cancer treatment by preventing the rapid multiplication of cancer cells or by encouraging the death of cancer cells, which typically ignore the body’s signals for programmed death. A 2012 study found that CBD reduced the proliferation, or increase, of cancer cells through multiple processes. A study published in Molecular Cancer Therapeutics complemented these findings, concluding that CBD induced the death of cancerous cells.

While treatments such as chemotherapy are able to destroy cancer cells, they may also damage other healthy cells; however, as the National Cancer Institute points out:

Cannabinoids appear to kill tumor cells but do not affect their non-transformed counterparts and may even protect them from cell death.

This means that the cannabinoids found in marijuana may be able to eliminate cancer cells, stop their growth and protect the body’s healthy cells throughout the process.

Hemp CBD vs. Marijuana CBD

CBD has become somewhat of a cultural phenomenon since it offers many therapeutic benefits and can be accessed nearly anywhere – even where marijuana is illegal. The reason for this is that CBD can also be found in hemp, a plant that shares the Cannabis sativa family with marijuana. Hemp contains a much lower level of THC than marijuana, which is the psychoactive compound responsible for perceived feelings of being “high.” There is less than 0.3% THC in hemp-derived CBD oil, which allows it to be legally sold and purchased even in states where marijuana is illegal.

While hemp-derived CBD may offer some of the pain relief and therapeutic benefits that patients are looking for, it is generally less effective than marijuana-derived CBD because of a lack of THC and other cannabinoids. Additionally, hemp has a lower CBD concentration than marijuana. To create hemp-derived CBD oil, the process requires many more plants, which can result in contamination by toxins and pesticides.

For these reasons, doctors and researchers recommend that patients use marijuana-derived CBD oil for medical purposes.

How to Qualify for Medical Marijuana

Under current legislation in Florida, cancer is a medical condition that can qualify a patient for treatment with CBD and other medical marijuana products. To determine if you qualify for treatment, call CannaMD at 1 (855) 420-9170 or consider filling out our free online application.

Our team of certified medical marijuana physicians can help you navigate medical marijuana treatment and provide you with the state-required recommendation you need to get started!

Cannabinoids in glioblastoma multiforme—hype or hope?

Cannabis and its derivatives are being used increasingly by patients with cancer, including patients with glioblastoma multiforme (GBM), the most common and aggressive primary brain malignancy. Despite promising preclinical data suggesting potential anti-cancer effects for cannabinoids in GBM, clinical and safety data are lacking. This editorial will discuss a recent Phase 1b trial of nabiximols oromucosal spray in combination with dose-intense temozolomide in patients with recurrent GBM in the context of other relevant findings in this field.

Cannabinoids are diverse compounds that are ligands for endogenous cannabinoid and other G-protein coupled receptors. 1,2,3 Some of these are being investigated increasingly in preclinical models and clinical studies in a variety of cancers, assessing their potential in ameliorating symptoms or for anti-cancer effects. The group comprises plant-derived phytocannabinoids (including cannabidiol (CBD) and the psychoactive Δ 9 -tetrahydrocannabinol (THC)), synthetic substances (including nabilone and dronabinol which are FDA-approved for chemotherapy-induced nausea and vomiting), and a variety of (physiological) endocannabinoids.

While the use of cannabis grown specifically for ‘medical purposes’, and its extracts (e.g. CBD oil), by cancer patients has increased significantly in recent years, high-quality evidence supporting their safety and utility is sparse, and products comprise inconsistent ingredients with inconsistent dosage. Although reports suggest dysregulation of cannabinoid receptors and their endogenous ligands in cancer, results to date have generally been inconclusive and suggest both pro-tumorigenic and anti-cancer effects. 1,2,3 It is unclear whether these inconsistencies reflect an incomplete understanding of this complex biological system, heterogeneity in the function of ligated receptors in distinct tissues or disease states, or bystander effects (where changes in this system are not central to cancer progression or maintenance). Nevertheless, multiple preclinical models do support a role for modulation of cannabinoid and other receptors (through genetic or pharmacological manipulation) in affecting tumour cell proliferation, survival and invasion, and the tumour microenvironment, including immune and endothelial cells.

Glioblastoma multiforme (GBM) is the most common, and most aggressive, malignant primary brain tumour of adults. Tumour recurrence is all but inevitable after optimal primary treatment with maximal safe surgical resection followed by radiation ± temozolomide (alkylating) chemotherapy. 4 Options for recurrent GBM are limited, and include lomustine chemotherapy, temozolomide, re-irradiation and surgical re-resection. While the optimal therapeutic paradigm for recurrent GBM is unclear, outcomes are dismal regardless of the approach and novel treatment strategies are required urgently. The cannabinoid receptors CB1 and CB2 are expressed in gliomas, and although the study of their expression has been limited, CB2 expression may positively correlate with tumour grade, 5 although expression levels by immunohistochemistry are heterogeneous, including in grade IV (GBM) tumours. 5,6 Specific cannabinoids have been investigated in numerous preclinical glioma models, where they can have anti-cancer effects, reducing tumour cell proliferation, inducing tumour cell death, and modulating angiogenesis. 1,2,3 While temozolomide or THC have no or very minor effects on GBM cell line viability in vitro, either results in a significant reduction in tumour growth of subcutaneous xenografts of the U87MG GBM cell line in a murine model, when injected peritumourally. 7 Temozolomide and THC in combination resulted in complete abrogation of xenograft growth, which appears to be mediated through autophagic stimulation (which may also have unwanted effects 8 ) and apoptotic cell death. CBD and THC in combination resulted in significantly reduced viability of GBM cell lines and a primary human GBM culture in vitro and U87MG xenografts in vivo, with results suggesting synergy between these agents in effecting tumour cell death at submaximal concentrations, with distinct mechanisms induced by each agent, but both promoting apoptosis. Nabiximols oromucosal spray (Sativex®) is approved in multiple countries to reduce (otherwise refractory) moderate to severe spasticity associated with multiple sclerosis, and principally comprises Cannabis sativa leaf- and flower-derived THC and CBD in an

1:1 ratio with an ethanol excipient. Similar preclinical anti-tumour effects were also seen in GBM cells with a ‘Sativex-like’ formulation, including significant xenograft growth inhibition in combination with temozolomide. 7 This was also seen using the relatively temozolomide-resistant GBM cell line T98G, where a combination of temozolomide and THC or a ‘Sativex-like’ formulation led to significant tumour growth inhibition (unobserved with any of these alone). Consistent findings were later observed from similar experiments using oral cannabinoid administration, while such synergy was not observed between these compounds and lomustine chemotherapy (which is commonly used in recurrent GBM). 9 These data, and other supporting findings, led to the hypotheses that THC or THC/CBD combinations (including Sativex®) in combination with temozolomide may have potential clinical utility in patients with GBM. A pilot study of intracranial THC administration directly into the surgical cavity of nine patients with recurrent, resected GBM showed a reduction in tumour cell proliferation in the two patients who had further biopsies on the study. 6 While this approach appeared tolerable, outcomes in this study remained poor. Anecdotal reports and case series suggesting anti-cancer efficacy of cannabinoid preparations in patients with GBM 10 are limited by possible selection bias, other concomitant or recent treatments with proven efficacy, and potential issues with pseudo-progression after such treatments.

In this issue of the British Journal of Cancer, Twelves et al. 11 present the findings of their well-executed, Phase 1b study of the tolerability and safety (primary objective) and pharmacokinetics and preliminary efficacy (secondary objectives) of nabiximols oromucosal spray (nabiximols) and dose-intense temozolomide (DIT) in 27 patients with a first recurrence of GBM following radiotherapy and temozolomide as first-line treatment. Part 1 of the study was open-label (n = 6) and Part 2 was randomised (1:1 to either nabiximols (n = 12) or placebo (n = 9)), and double-blind. Temozolomide was given at 85 mg/m 2 daily (days 1–21 of each 28-days cycle with a maximum of 13 cycles), starting one week before the addition of nabiximols/placebo which was administered in an individualised manner (starting with one spray per day and building up to 3–12 sprays/day depending on tolerability, a dosing strategy based on a prior study in chronic pain 12 ).

Three patients (50%) in Part 1, and three patients (17.6%) in Part 2, came off study owing to treatment-emergent adverse events (TRAEs). Four patients completed study treatment, all in Part 2 (with three in the placebo arm). The mean dose of nabiximols was 6 sprays/day (Part 1) and 7.5 sprays/day (Part 2) and the mean duration of exposure to nabiximols was 16 weeks (Part 1) and 24.9 weeks (Part 2; cf. 10 sprays/day and 23.6 weeks for placebo). The most frequent TRAEs in patients treated with nabiximols and DIT were vomiting, dizziness, nausea, fatigue and headache. These were predominantly low grade, with most being more frequent in the nabiximols arm of Part 2 (e.g. nausea in 75% versus 11.1% in patients receiving placebo). Grade 3 or greater TRAEs in patients receiving nabiximols included non-cardiac chest pain, headache, pulmonary embolism, constipation, peripheral oedema, anaemia, and urinary tract infection. There were no grade 3 or greater TRAEs in patients receiving placebo. Nabiximols had no discernible effect on temozolomide exposure.

The pre-defined efficacy endpoints were progression-free survival at 6 months (PFS6) and overall survival (OS) at 1 year for both parts of the study. PFS6 for patients in Part 1 was 16.7% (with one PFS status being unknown). PFS6 for patients in Part 2 was 33.3% for both arms of the study (with one PFS status being unknown for each arm). OS at 1 year for patients in Part 1 was 50%, and in Part 2 was 83.3% for the nabiximols group and 44.4% for those receiving placebo. A log-rank test suggested a significant survival advantage in favour of nabiximols (p = 0.042). However, the trial was not powered to detect survival differences between groups in Part 2 (and see important caveats below). The OS at 1 year in Part 1 where all patients were receiving nabiximols was 50% (similar to the placebo group in Part 2 but these are all small numbers). In a post hoc analysis of survival (collected outside the study protocol), 2-year OS was 50% versus 22% in favour of patients treated with nabiximols (p = 0.134). Similar limitations apply to the interpretation of these findings.

This is the first study to assess the safety of nabiximols in combination with DIT, and does so in a challenging patient population. The authors have shown that dosing with nabiximols using an individualised schedule is feasible, although the incidence of TRAEs was higher than those observed previously—this could be owing to uncertainty regarding disease-related and treatment-related AEs, treatment duration, the concomitant temozolomide, or indeed a true emergent nabiximols toxicity profile for GBM patients (or a combination of these). The population enrolled was younger and had better performance status compared with most patients with recurrent GBM, and the generalisability of toxicity findings to other patients remains unclear from this small study. A significant number of patients discontinued treatment, suggesting that this is not an easily tolerated treatment combination even in this highly selected group, although this must be tempered with the caveats above and any potential therapeutic benefit in this population.

The efficacy findings in this study are intriguing but must be interpreted with significant caution, particularly given the small number of patients included in the study. This population had excellent prognosticating features: compared with the general population of patients with recurrent GBM, they were younger (mean age 50.2 years for Part 1 and 57.8 years for Part 2), fitter (with a median KPS of 90% for all groups with more patients with KPS > / = 90% in the nabiximols arm of Part 2), and with a significantly longer median time to recurrence after primary treatment—this was 20.2, 22.9 and 19.6 months from initial diagnosis for those in Part 1, Part 2 (nabiximols) and Part 2 (placebo), respectively. Importantly, the absence of (now standard) prognostic and biomarker information available within the study (e.g. IDH1/2 mutational [prognostic biomarker] and MGMT methylation status [predictive of temozolomide efficacy]) means that assessment for potential Part 2 arm enrichments/imbalances is not possible, and treatment information was not collected after study drug discontinuation/completion. Two early deaths (within 40 days) in the placebo arm of Part 2, which may simply be related to specific patient/disease factors, appear to count for much of the observed survival differences in Part 2. Additionally, there is no standard dose and schedule for DIT, the reasons for the dose and schedule in this study are unclear, and there is no evidence that DIT delivers a better outcome compared with standard temozolomide dosing schedules. 13

Regardless of any potential differences between arms in Part 2, the overall survival in this trial population remains impressive, although it is difficult to conceive how this may be modulated by either nabiximols or DIT given the absence of a signal for improvement in PFS. Nevertheless, these interesting findings, backed up by a strong preclinical rationale, still warrant urgent exploration of the combination of temozolomide and nabiximols in a sufficiently powered larger study. A Phase 1b study (GEINOCANN; NCT03529448) will study TN-TC11G in combination with radiotherapy and temozolomide in first-line treatment of GBM (with a recruitment target of 30 patients). It is crucial that clinical research efforts are combined with solid translational research to attempt to identify any potential predictive biomarkers for cannabinoid efficacy.

We argue against imprudent use of off-label nabiximols or other cannabinoid products in patients with GBM (which appears to be increasingly widespread and often patient-led 14 ), particularly given the significant TRAE profile observed, until such time as high-quality evidence supporting or refuting the use of a specific product, in a specific population, becomes available.

Change history


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