Benjamin Land – Research Associate Professor of Pharmacology, University of Washington
Marijuana is produced by the cannabis plant, which is native to Asia but is now grown throughout the world. Individuals use marijuana for both its psychoactive, euphoria-inducing properties and its ability to relieve pain.
Chemicals produced by the cannabis plant are commonly known as cannabinoids. The two primary cannabinoids that occur naturally in the cannabis plant are THC – the psychoactive compound in marijuana – and CBD, which does not cause the sensation of being high.
Many marijuana users say they take it to treat pain, suggesting that readily available cannabinoids could potentially be used to offset the use of opioids such as morphine and oxycodone that are commonly used in pain treatment. A safer, natural alternative to opioid painkillers would be an important step toward addressing the ongoing opioid epidemic.
Intriguingly however, research suggests that cannabis use could also lessen the need for opioids directly by interacting with the body’s own natural opioid system to produce similar pain-relief effects.
I am a neuropharmacology scientist who studies both opioids and cannabinoids as they relate to pain treatment and substance abuse. My research focuses on the development of drug compounds that can provide chronic pain relief without the potential for overuse and without the tapering off of effectiveness that often accompanies traditional pain medications.
How opioids work
Our bodies have their own built-in opioid system that can aid in managing pain. These opioids, such as endorphins, are chemicals that are released when the body experiences stress such as strenuous exercise, as well as in response to pleasurable activities like eating a good meal. But it turns out that humans are not the only organisms that can make opioids.
In the 1800s, scientists discovered that the opioid morphine – isolated from opium poppy – was highly effective at relieving pain. In the last 150 years, scientists have developed additional synthetic opioids like hydrocodone and dihydrocodeine that also provide pain relief.
Other opioids like heroin and oxycodone are very similar to morphine, but with small differences that influence how quickly they act on the brain. Fentanyl has an even more unique chemical makeup. It is the most powerful opioid and is the culprit behind the current surge in drug overdoses and deaths, including among young people.
Opioids, whether naturally produced or synthetic, produce pain relief by binding to specific receptors in the body, which are proteins that act like a lock that can only be opened by an opioid key.
One such receptor, known as the mu-opioid receptor, is found on pain-transmitting nerve cells along the spinal cord. When activated, mu-receptors tamp down the cell’s ability to relay pain information. Thus, when these opioids are circulating in the body and they reach their receptor, stimuli that would normally cause pain are not transmitted to the brain.
These same receptors are also found in the brain. When opioids find their receptor, the brain releases dopamine – the so-called “feel-good” chemical – which has its own receptors. This is in part why opioids can be highly addicting. Research suggests that these receptors drive the brain’s reward system and promote further drug-seeking. For people who are prescribed opiates, this creates the potential for abuse.
Opioid drugs, which include heroin, oxycodone and fentanyl, are highly addictive. The opioid crisis: Painkillers are killing us.
Opioid receptors are dynamically regulated, meaning that as they get exposed to more and more opioids, the body adapts quickly by deactivating the receptor. In other words, the body needs more and more of that opioid to get pain relief and to produce the feel-good response. This process is known as tolerance. The drive to seek more and more reward paired with an ever-increasing tolerance is what leads to the potential for overdose, which is why opioids are generally not long-term solutions for pain.
The potential of THC and CBD for pain treatment
THC binds to cannabinoid receptors that are located throughout the central nervous system, producing a variety of responses. One of those responses is the high associated with cannabis use, and another is pain relief. Additionally, THC is believed to reduce inflammation in a manner similar to anti-inflammatory drugs like ibuprofen.
In contrast, CBD appears to bind to several distinct receptors, and many of these receptors can play a role in pain reduction. Importantly, this occurs without the high that occurs with THC.
Cannabinoids may also be helpful for other conditions as well. Many studies have demonstrated that cannabinoid drugs approved for medical use are effective for pain and other symptoms like spasticity, nausea and appetite loss.
Moving pain research forward
Along with the pairing of THC and CBD, researchers are beginning to explore the use of those two cannabinoids together with existing opioids for pain management. This research is being done in both animal models and humans.
These studies are designed to understand both the benefits – pain relief – and risks – primarily addiction potential – of co-treatment with cannabinoids and opioids. The hope would be that THC or CBD may lower the amount of opioid necessary for powerful pain relief without increasing addiction risk.
For example, one study tested the combination of smoked cannabis and oxycontin for pain relief and reward. It found that co-treatment enhanced pain relief but also increased the pleasure of the drugs. This, as well as a limited number of other studies, suggests there may not be a net benefit.
However, many more studies of this type will be necessary to understand if cannabinoids and opioids can be safely used together for pain. Still, using cannabinoids as a substitution for opioids remains a promising pain treatment strategy.
The next decade of research will likely bring important new insights to the therapeutic potential of cannabinoids for chronic pain management. And as marijuana legalization continues to spread across the U.S., its use in medicine will undoubtedly grow exponentially. (The CONVERSATION)