Smoked cannabis for chronic neuropathic pain: a randomized controlled trial
From the Department of Anesthesia (Ware), the Department of Family Medicine (Ware), the Department of Epidemiology, Biostatistics and Occupational Health (Wang, Shapiro), the Department of Medicine (Huynh) and the Alan Edwards Centre for Research on Pain (Gamsa, Bennett), McGill University, Montréal, Que.; Boreal Primum (Robinson, Ducruet), Montréal, Que.; and the Centre for Applied Health Research and Evaluation (Collet), University of British Columbia, Vancouver, BC
Correspondence to: Dr. Mark A. Ware, E19.145, Montréal General Hospital, 1650 Cedar Ave., Montréal QC H3G 1A4; [email protected]
Chronic neuropathic pain affects 1%–2% of the adult population and is often refractory to standard pharmacologic treatment. Patients with chronic pain have reported using smoked cannabis to relieve pain, improve sleep and improve mood.
Adults with post-traumatic or postsurgical neuropathic pain were randomly assigned to receive cannabis at four potencies (0%, 2.5%, 6% and 9.4% tetrahydrocannabinol) over four 14-day periods in a crossover trial. Participants inhaled a single 25-mg dose through a pipe three times daily for the first five days in each cycle, followed by a nine-day washout period. Daily average pain intensity was measured using an 11-point numeric rating scale. We recorded effects on mood, sleep and quality of life, as well as adverse events.
We recruited 23 participants (mean age 45.4 [standard deviation 12.3] years, 12 women [52%]), of whom 21 completed the trial. The average daily pain intensity, measured on the 11-point numeric rating scale, was lower on the prespecified primary contrast of 9.4% v. 0% tetrahydrocannabinol (5.4 v. 6.1, respectively; difference = 0.7, 95% confidence interval [CI] 0.02–1.4). Preparations with intermediate potency yielded intermediate but nonsignificant degrees of relief. Participants receiving 9.4% tetrahydrocannabinol reported improved ability to fall asleep (easier, p = 0.001; faster, p < 0.001; more drowsy, p = 0.003) and improved quality of sleep (less wakefulness, p = 0.01) relative to 0% tetrahydrocannabinol. We found no differences in mood or quality of life. The most common drug-related adverse events during the period when participants received 9.4% tetrahydrocannabinol were headache, dry eyes, burning sensation in areas of neuropathic pain, dizziness, numbness and cough.
A single inhalation of 25 mg of 9.4% tetrahydrocannabinol herbal cannabis three times daily for five days reduced the intensity of pain, improved sleep and was well tolerated. Further long-term safety and efficacy studies are indicated. (International Standard Randomised Controlled Trial Register no. ISRCTN68314063)
Chronic neuropathic pain has a prevalence of 1%–2%, 1 and treatment options are limited. 2 Pharmacotherapy includes anticonvulsants, antidepressants, opioids and local anesthetics, 3 , 4 but responses vary and side effects limit compliance.
Cannabis sativa has been used to treat pain since the third millennium BC. 5 An endogenous pain-processing system has been identified, mediated by endogenous cannabinoid ligands acting on specific cannabinoid receptors. 6 These findings, coupled with anecdotal evidence of the analgesic effects of smoked cannabis, 7 support a reconsideration of cannabinoid agents as analgesics.
Oral cannabinoids such as tetrahydrocannabinol, cannabidiol and nabilone have, alone and in combination, shown efficacy in central 8 , 9 and peripheral 10 neuropathic pain, rheumatoid arthritis 11 and fibromyalgia. 12
The analgesic effects of smoked cannabis remain controversial, although it is used by 10%–15% of patients with chronic noncancer pain 13 and multiple sclerosis. 14 Clinical trials are needed to evaluate these effects, given that the risks and benefits of inhaled cannabinoids may differ from oral agents. To date, three small clinical trials of the analgesic efficacy of smoked cannabis have been reported. 15 – 17 All studies were conducted in residential laboratories, and participants smoked multiple doses of the drug at each time point. No study adequately reported data related to adverse events.
We conducted a clinical trial using a standardized single-dose delivery system to explore further the safety and efficacy of smoked cannabis in outpatients with chronic neuropathic pain.
The study was approved by the McGill University Health Centre Research Ethics Committee, and all participants gave written informed consent. Participants were recruited at the McGill University Health Centre.
Those eligible were men and women aged 18 years or older with neuropathic pain of at least three months in duration caused by trauma or surgery, with allodynia or hyperalgesia, and with an average weekly pain intensity score greater than 4 on a 10-cm visual analogue scale. Participants had a stable analgesic regimen and reported not having used cannabis during the year before the study (Appendix 1, available at www.cmaj.ca/cgi/content/full/cmaj.091414/DC1). Potential participants had to have normal liver function (defined as aspartate aminogransferase less than three times normal), normal renal function (defined as a serum creatinine level < 133 μmol/L), normal hematocrit (>38%) and a negative result on β human chorionic gonadotropin pregnancy test (if applicable). Women of child-bearing potential consented to use adequate contraception during the study and for three months afterward.
Exclusion criteria were pain due to cancer or nociceptive causes, presence of significant cardiac or pulmonary disease, current substance abuse or dependence (including abuse of or dependence on cannabis), history of psychotic disorder, current suicidal ideation, pregnancy or breastfeeding, participation in another clinical trial within 30 days of enrolment in our trial, and ongoing insurance claims.
We used a randomized, double-blind, placebo-controlled, four-period crossover design. Each period was 14 days in duration, beginning with five days on the study drug followed by a nine-day washout period. Eligible participants were randomized to a sequence of treatment periods based on a Latin square design.
Cannabis was obtained from Prairie Plant Systems Inc. (Saskatoon, Sask.) and the United States National Institute of Drug Abuse. Prairie Plant Systems Inc. blended cannabis flowers and leaves to prepare three different potencies of active drug (2.5%, 6.0% and 9.4% tetrahydrocannabinol). The US National Institute of Drug Abuse used ethanolic extraction of cannabinoids to prepare the 0% tetrahydrocannabinol product. Intermediate doses (2.5% and 6.0% tetrahydrocannabinol) were used to increase the likelihood of successful blinding. Doses of 25 mg (± 1 mg) were prepared in opaque gelatin capsules by the study pharmacist. A panel of nine independent personnel examined the appearance of the four cannabis preparations and found no association between estimated and true potency (data not shown).
Cannabis doses were delivered as single smoked inhalations using a titanium pipe (RayDiaTor, Mori Designs, Auburn, WA, USA). The first dose of each period was self-administered under observation in a ventilated room. For dose delivery, one capsule of the assigned potency was opened and the cannabis tipped into the bowl of the pipe. Participants were instructed to inhale for five seconds while the cannabis was lit, hold the smoke in their lungs for ten seconds, and then exhale. The beginning of inhalation was recorded as the onset of the exposure. Subsequent doses were self-administered in the same manner three times daily at home for the first five days of each period.
Routine medications were continued throughout the trial. Use of breakthrough analgesia (acetaminophen) was allowed.
The study nurse explained the study to each participant, sought signed informed consent, obtained a medical history and performed a chart review. The study physician conducted a physical examination. Urinary drug screening was performed. Participants were contacted by telephone on three occasions during the first five days of the screening phase to calculate a baseline average pain score. A psychological evaluation was conducted by a clinical psychologist.
On the first day of each period, participants were followed for three hours. Vital signs and ratings of pain, “high,” relaxation, stress, happiness and heart rate were recorded, and blood was collected for tetrahydrocannabinol assays. On days one and five of each study period, blood was collected for hematologic and biochemical analyses. At the end of their first visit, participants were given four labelled containers for urine collection and 13 cannabis doses for the five days of treatment.
During the first five days of each period, participants were contacted daily by telephone to administer questionnaires on pain intensity, sleep, medication and adverse effects. Participants collected early morning urine samples daily. They returned on day five to return the urine samples, to undergo urinary and blood tests, and to complete questionnaires on pain quality, mood, quality of life and assessments of potency. At the end of the study, participants completed final adverse event reports and potency assessments. Participants were advised not to drive a vehicle or operate heavy machinery while under the influence of the study drug.
Outcome measures were selected following published recommendations for clinical trials of chronic pain. 18 Pain intensity was measured using an 11-item numeric rating scale, with “no pain” and “worst pain possible” as anchors. The numeric rating scale was administered once daily for present, worst, least and average pain intensity during the previous 24 hours. As per protocol, the average pain intensity score over the five days on study drug constituted the primary outcome. Acute effects on pain intensity were measured using a 100-mm visual analogue scale. Pain quality was assessed using the McGill Pain Questionnaire. 19 Sleep was assessed using the Leeds Sleep Evaluation Questionnaire. 20 The short-form Profile of Mood States was used to examine mood effects. 21 Quality of life was assessed using the EQ-5D health outcome instrument. 22 The items “high,” “relaxed,” “stressed,” and “happy” were measured using a 100-mm visual analogue scale (0 = not at all, 10 = extremely). 23 – 25 Potency assessments were conducted by asking participants on the fifth day of each period to guess which potency they had received. At the end of the trial, participants were asked to guess the order in which they received the treatments. Standard assays for plasma tetrahydrocannabinol assays were used (Appendix 1).
Our primary hypothesis was that smoked cannabis containing 9.4% tetrahydrocannabinol is superior to 0% tetrahydrocannabinol in reducing average pain intensity. The comparison of within-patient average weekly pain intensity when assigned 9.4% tetrahydrocannabinol cannabis compared with placebo was the contrast of primary interest. A sample size of 32 patients was targeted assuming a within-patient difference of 10 mm 26 in the primary outcome between active and placebo drug, on a 100 mm scale, with a standard deviation of 20 mm, and with 80% power and 5% significance.
A generalized linear model including drug, period and first-order carryover effects was fitted. If the carryover effect or period effect was not significant, then a reduced model was refitted. Nine-five per cent confidence intervals were generated. Significance tests were performed at a 5% level. An identical procedure to that described above for the primary outcome was performed to assess the secondary outcomes, including the McGill Pain Questionnaire, the Leeds Sleep Evaluation Questionnaire, the Profile of Mood States, and EQ-5D. Statistical procedures for day one assessments and EQ-5D analyses are shown in Appendix 1. Data from all randomized participants were included in all safety and efficacy analyses.
All reported adverse events were classified according to severity, seriousness and relationship to the study drug. An independent data-monitoring committee monitored the safety-related aspects of the trial.
In conducting the study, we followed the Good Clinical Practice guidelines of the International Conference on Harmonisation of Technical Requirements for Registration of Pharmaceuticals for Human Use. 27 The trial was registered with the International Standard for Randomised Controlled Trials Register (ISRCTN683140063).
We screened 116 potential participants over a 30-month period (August 2003 to January 2006), of whom 93 were ineligible. Twenty-three participants underwent random assignment to treatment, of whom 21 completed all four cycles. Two participants withdrew within the first five days of the study; one (who was receiving placebo at the time) withdrew because of a positive result on urinary screening for cannabinoid and the other (who was receiving 6% tetrahydrocannabinol at the time) because of increased pain ( Figure 1 ). Demographic and baseline pain characteristics of participants are shown in Table 1 .
Flow of patients through the randomized controlled trial.
Demographic and baseline characteristics of participants
|Characteristic||No. (%) of subjects *
n = 23
|Mean (SD)||45.4 (12.3)|
|Primary or elementary||1 (4.3)|
|Secondary or high school||8 (34.8)|
|University or college||14 (60.9)|
|Full-time or part-time||4 (17.4)|
|Short-term disability or disabled||14 (60.9)|
|Never smoked||8 (34.8)|
|Current smoker||9 (39.1)|
|Ever used alcohol|
|Ever used cannabis|
|Average daily pain at baseline|
|Mean (SD)||6.89 (1.37)|
Note: NSAIDS = nonsteroidal anti-inflammatory drugs, SD = standard deviation.
We found no evidence of significant carryover or period effects for any outcome. The average daily pain intensity was significantly lower on 9.4% tetrahydrocannabinol cannabis (5.4) than on 0% tetrahydrocannabinol (6.1) (p = 0.023; difference = 0.7, 95% CI 0.02–1.4). All pairwise differences between groups are shown with 95% CIs in Table 2 . The average daily pain scores for each level of tetrahydrocannabinol, along with other secondary outcomes, are shown in Table 2 .
Pairwise comparisons of the effects of four potencies of smoked cannabis on average daily pain
|Potency, % of THC||Potency, % of THC, mean difference (95% CI)|
|2.5||−0.13||(−0.83 to 0.56)||–||–||–||–||–||–|
|6.0||−0.09||(−0.78−0.60)||0.04||(−0.64 to 0.73)||–||–||–||–|
|9.4||−0.71||(−1.40 to −0.02)||−0.58||(−1.27 to 0.11)||−0.63||(−1.30 to 0.06)||–||–|
Note: CI = confidence interval, THC = tetrahydrocannabinol.
There was a trend toward improvement in all outcomes with increasing tetrahydrocannabinol content ( Table 3 ). Participants using 9.4% tetrahydrocannabinol cannabis reported significantly more drowsiness and reported getting to sleep more easily, faster and with fewer periods of wakefulness compared with those using placebo (p < 0.05). Anxiety and depression were improved in the 9.4% tetrahydrocannabinol group compared with placebo on the EQ-5D subscale (p < 0.05). No significant differences were noted on the Profile of Mood States. No difference in the “high,” “happy,” “relaxed” or “stressed” scores on the visual analogue scale were observed between tetrahydrocannabinol potencies.
Effects of smoked cannabis and secondary outcomes, by potency of tetrahydrocannabinol (THC) received
|Outcome||Potency of THC, %; outcome measure, mean (SD) *|
|Average daily pain||6.1 (1.6)||5.9 (1.9)||6.0 (1.8)||5.4 (1.7) †|
|Highest daily pain||7.1 (1.4)||7.0 (1.6)||7.0 (1.5)||6.5 (1.6)|
|Lowest daily pain||5.1 (2.1)||5.0 (2.4)||4.8 (2.4)||4.4 (2.2)|
|McGill Pain Questionnaire|
|Sensory||17.2 (10.5)||17.1 (9.9)||14.8 (9.2)||15.6 (8.7)|
|Affective||3.5 (3.0)||3.8 (3.6)||3.3 (3.4)||3.0 (3.1)|
|Evaluative||2.2 (1.5)||2.8 (1.3)||2.1 (1.5)||1.7 (1.5)|
|Miscellaneous||6.2 (4.3)||6.8 (4.4)||5.5 (2.9)||4.5 (3.6)|
|Total score||29.1 (17.0)||30.4 (18.1)||25.8 (14.5)||24.8 (14.7)|
|Present pain intensity||2.8 (1.2)||3.0 (1.0)||2.8 (1.0)||2.5 (1.1)|
|Leeds Sleep Evaluation Questionnaire ‡|
|Getting to sleep|
|Harder — easier than usual||5.4 (1.5)||5.5 (1.6)||6.1 (1.5)||6.8 (1.8) †|
|Slower — faster than usual||5.3 (1.3)||5.6 (1.4)||6.2 (1.7)||6.9 (1.7) †|
|Less — more drowsy than usual||5.3 (1.1)||5.9 (1.4)||5.7 (1.3)||6.6 (1.5) †|
|Quality of sleep|
|More restless — more restful||5.5 (1.6)||5.4 (1.7)||5.9 (2.0)||6.5 (2.1)|
|More — less period wakefulness than usual||5.3 (1.5)||5.0 (1.5)||5.5 (1.7)||6.3 (1.8) †|
|Awakening this morning|
|More difficult — easier||4.6 (1.2)||4.4 (0.8)||4.7 (1.4)||4.8 (1.0)|
|Took longer — shorter||4.4 (0.8)||4.4 (0.9)||1.7 (1.1)||5.0 (1.0)|
|Feeling on waking-up|
|Tired — alert||4.3 (1.9)||4.0 (1.5)||5.2 (1.9)||4.9 (1.9)|
|Tired — alert||4.1 (1.5)||1.3 (1.7)||4.9 (2.0)||4.0 (1.7)|
|Sense of balance|
|More — less clumsy than usual||4.9 (0.4)||4.8 (0.4)||4.9 (0.4)||5.0 (1.2)|
|EQ-5D health outcomes §|
|Mobility, no. (%)||10 (48)||11 (52)||11 (52)||11 (55)|
|Self-care, no. (%)||14 (67)||12 (57)||15 (71)||14 (70)|
|Usual activities, no. (%)||3 (14)||3 (14)||4 (19)||5 (25)|
|Pain or discomfort, no. (%)||11 (52)||10 (48)||14 (67)||14 (75)|
|Anxiety or depression, no. (%)||4 (19)||5 (23)||7 (33)||9 (45) †|
|State of health, no. (%)||3 (14)||2 (9)||4 (19)||7 (35)|
|State of health (VAS)||54.1 (19.5)||48.6 (18.9)||52.9 (22.0)||56.3 (20.4)|
|Profile of Mood States (POMS) ¶|
|Depression||10.6 (6.5)||10.4 (6.7)||9.3 (6.6)||9.4 (5.7)|
|Vigour||7.3 (4.3)||7.3 (5.4)||6.2 (4.6)||8.0 (4.6)|
|Anger||9.2 (7.0)||7.7 (6.3)||7.9 (7.6)||6.5 (6.0)|
|Tension||8.5 (5.1)||9.3 (4.6)||9.0 (5.6)||7.2 (5.2)|
|Confusion||6.3 (3.7)||6.7 (4.0)||6.0 (4.3)||5.7 (4.1)|
|Fatigue||11.9 (4.1)||11.1 (5.0)||11.1 (4.8)||10.5 (5.0)|
|Total mood disturbance||39.1 (22.7)||38.0 (24.5)||36.9 (25.9)||31.2 (22.4)|
Note: EQ-5D = health outcome instrument, 22 SD = standard deviation, VAS = visual analog scale.
§ Data are presented as a proportion of subjects reporting the most favourable responses; thus, a higher proportion suggests a better health outcome.
A total of 248 mild and six moderate adverse events (fall, 2 increased pain, 1 numbness, 1 drowsiness 1 and pneumonia 1 ) were reported during the trial ( Table 4 ). No serious or unexpected adverse events were reported. The total number of adverse events and the number of participants reporting at least one adverse event increased with tetrahydrocannabinol potency. The most frequent drug-related adverse events reported in the group receiving 9.4% tetrahydrocannabinol were headache, dry eyes, burning sensation, dizziness, numbness and cough. Feeling “high” and euphoria were reported once in each of the 2.5%, 6% and 9.4% tetrahydrocannabinol periods. No significant changes in vital signs, heart-rate variability, hematological, biochemistry or renal function blood tests were detected.
Adverse events reported during the study, by potency of tetrahydrocannabinol (THC)
|Adverse event||% of THC|
n = 21
n = 22
n = 21
n = 22
|Nervous system disorders|
|Decreased motor skill||1|
|Not sleeping well||1|
|General disorders and conditions specific to site of administration|
|Bad taste in oral cavity||1||1|
|Irritation of oral cavities||1|
|Itchiness in face||1|
|Itchiness of nose||2||1|
|Craving for sweets||1|
|Disinterest in surroundings||1|
|Foggy mental state||1||1|
|Lack of concentration||1||2||2||2|
|Lost in time||1|
|Foggy mental state||1||1|
|Lack of concentration||1||2||2||2|
|Lost in time||1|
|Respiratory, thoracic and mediastinal disorders|
|Short of breath||1||1|
|Loss of appetite||1|
|Ear and labyrinth disorders|
|Itchiness of eyes||1||2||1|
|Musculoskeletal and connective tissue disorders|
|Bruise on left back shoulder||1|
|Heaviness in leg||1|
|Injury to right knee||1|
|Muscles of jaw contracted||1|
|Weakness of right leg||1|
|Infections and infestations|
|Renal and urinary disorders|
|Disorders of skin and subcutaneous tissue|
|Surgical and medical procedures|
|Total adverse events||46||61||65||82|
Note: THC = tetrahydrocannabinol.
On day five of the first cycle, 1 of 5 participants (20%) assigned to placebo correctly identified this assignment, while 9 of the 16 participants (56%) who received placebo during later cycles did so. Of the 5 participants administered 9.4% tetrahydrocannabinol in their first cycle, none correctly identified this assignment, while 10 of 16 patients (63%) did so during later cycles. At the end of the trial, 16 (76%) of the participants were able to correctly identify the 9.4% tetrahydrocannabinol period and 13 (62%) were able to identify the 0% tetrahydrocannabinol period, whereas the 6% tetrahydrocannabinol period was identified by 8 participants (38%) and the 2.5% period by 7 (33%).
Compliance with the study was excellent, and all dispensed capsules were returned. With the exception of one participant who withdrew from the study, there were no positive urine tetrahydrocannabinol tests during the 0% tetrahydrocannabinol period or on any day one before exposure (Appendix 1).
Plasma tetrahydrocannabinol assays revealed dose–response pharmacokinetics ( Figure 2 ) and confirmed that participants did not use cannabis during placebo phases (Appendix 1).
Levels of tetrahydrocannabinol (THC) in plasma after inhalation of a single dose. Data are presented as means and standard deviations.
Pharmacy dispensing was satisfactory. No legal issues arose during the study and there were no reports or allegations of diversion of the study drug.
We found that 25 mg herbal cannabis with 9.4% tetrahydrocannabinol, administered as a single smoked inhalation three times daily for five days, significantly reduced average pain intensity compared with a 0% tetrahydrocannabinol cannabis placebo in adult participants with chronic post-traumatic or postsurgical neuropathic pain. We found significant improvements in measures of sleep quality and anxiety. We have shown the feasibility of a single-dose delivery method for smoked cannabis, and that blinding participants to treatment allocation is possible using this method.
The mean reduction in pain (0.7) from 6.1 to 5.4 on a 10-cm scale that we detected in this study is modest when compared with that from other drugs for chronic neuropathic pain, such as gabapentin (1.2) and pregabalin (1.3). 28 , 29 However, our study involved participants with refractory pain for which conventional therapies had failed, and this characteristic may have limited the potential for findings of a larger pain reduction.
The effects of cannabinoids on sleep are recognized. 7 , 9 The consistent trend toward improvement in all other outcomes for 9.4% tetrahydrocannabinol compared with placebo in our trial suggests that the reported effects on pain, mood and sleep may have been part of an overall improvement in many aspects of patients’ conditions.
Limitations and strengths
There were several limitations to this trial. The number of participants recruited was smaller than planned, owing to delays in obtaining licences, approvals and the study drug, and to restrictive criteria for eligibility. Most of our participants had prior experience with cannabis, which had been an early ethics requirement; none was using cannabis at the time of enrolment and they were not “experienced” users, so that the lessons learned would be applicable to naive users of medical cannabis. The use of small, fixed doses with a short trial duration may have reduced the effect size. We used a low dose to minimize exposure to smoke and to reduce psychoactive effects. Previous work has shown that a single dose of 0.4 mg/kg can be inhaled in a single lungful from a pipe, 24 , 30 which for a 70-kg person approximates to 25 mg per dose. The frequency of dosing was based on a duration of action of inhaled tetrahydrocannabinol of two to three hours 31 and was administered three times daily. We used a fixed dosing schedule because the study was too short to allow dose titration and we wanted the tetrahydrocannabinol potency to be the only difference between cycles. Finally, the highest tetrahydrocannabinol-content cannabis (9.4%) legally available at the time of the study was used. Additional studies with higher potencies and flexible dosing strategies are needed to explore dose–response effects.
With respect to our analysis, we are aware of issues surrounding the use of early tests for carryover effects. However, examination of pain scores during the washout period showed that the washout was adequate (data not shown), and therefore we believe our approach was appropriate.
Our trial had several important strengths, including a credible placebo, good compliance and good safety reporting. Finding a suitable placebo for smoked cannabis is not a trivial issue. During protocol reviews, it was stated that participants smoking cannabis would immediately know, based on the acute psychoactive effects, whether they had received active drug; however, our results do not support this view. Instead, our data suggest that short-term placebo-controlled trials of smoked cannabis are feasible.
The safety of smoked cannabis is a concern for patients and physicians, and we made a concerted effort to collect data on adverse events and describe short-term physiologic effects. The frequency of adverse events increased with tetrahydrocannabinol potency. Psychoactive effects did not result in participants withdrawing from the study. Euphoria or “high” was reported on only three occasions throughout the trial. There was no evidence of euphoria during the three hours following the first dose of each cycle regardless of tetrahydrocannabinol potency, possibly because plasma levels (mean 45 ng/mL) did not reach levels found with recreational users (> 100 ng/mL). 31
Our results support the claim that smoked cannabis reduces pain, improves mood and helps sleep. We believe that our trial provides a methodological approach that may be considered for further research. Clinical studies using inhaled delivery systems, such as vaporizers, 32 , 33 are needed.
Cannabis for chronic nerve pain: A half-baked solution?
Pain can be a good thing. After all, it warns us of threats to our well-being. But when pain becomes a long-term issue, it can have a significant impact on our quality of life. The approaching legalization of cannabis – better known as marijuana – in Canada has many wondering if it is a good option for pain relief.
Chronic pain is no stranger to many Canadians – nearly 20% of adults live with it on a daily basis (1). Unfortunately, the odds of suffering from chronic pain increase with age, and women are more likely to be affected than men.
Neuropathic pain – which arises from damage to the nerves – accounts for about one in five cases of chronic pain (2). Common culprits of this type of pain include accidents, injuries, or surgery, and symptoms or complications of an illness such as diabetes (3). People will often experience sensations like numbness, tingling, jabbing, freezing, or burning (4).
Neuropathic pain is also notoriously difficult to treat (2). Medications that are normally prescribed for other types of pain (e.g., non-steroidal anti-inflammatories or opioids) are often ineffective (3). Studies suggest that cannabis may help relieve chronic neuropathic pain (5). But does the evidence stand up to the hype, or are the pain-relieving properties of cannabis all smoke and mirrors?
What the research tells us
Two compounds in cannabis – THC and CBD – are thought to contribute to cannabis’s ability to relieve pain. THC can alter pain perception by reducing anxiety and stress, while CBD combats pain through its anti-inflammatory action. Cannabis-based medications come in several forms and can by inhaled by pipe or cigarette, or can be taken orally by spray or capsule.
Overall, the quality of the research around cannabis for neuropathic pain relief is low. That is not to say that neuropathic pain sufferers should disregard cannabis as a treatment option – it may work for some, but not for others. The bottom line is that there is currently a lack of good evidence supporting cannabis-based medicines for neuropathic pain relief. More high-quality research is needed to confirm its benefits. New research may be particularly important in older adult populations, and in people with health conditions that predispose them to nerve pain. In the meantime, cannabis may be a useful option for people who fail to get adequate relief from established treatment options (5).