Why Some Drugs Work Better on Different Types of Pain

By Dr. Rebecca Seal and Dr. Benedict Alder

Without the ability to feel pain, life is more dangerous. To avoid injury, pain tells us to use a hammer more gently, wait for the soup to cool or put on gloves in a snowball fight. Those with rare inherited disorders that leave them without the ability to feel pain are unable to protect themselves from environmental threats, leading to broken bones, damaged skin, infections and ultimately a shorter life span.

In these contexts, pain is much more than a sensation: It is a protective call to action. But pain that is too intense or long-lasting can be debilitating. So how does modern medicine soften the call?

As a neurobiologist and an anesthesiologist who study pain, this is a question we and other researchers have tried to answer. Science’s understanding of how the body senses tissue damage and perceives it as pain has progressed tremendously over the past several years. It has become clear that there are multiple pathways that signal tissue damage to the brain and sound the pain alarm bell.

Interestingly, while the brain uses different pain signaling pathways depending on the type of damage, there is also redundancy to these pathways. Even more intriguing, these neural pathways morph and amplify signals in the case of chronic pain and pain caused by conditions affecting nerves themselves, even though the protective function of pain is no longer needed.

Painkillers work by tackling different parts of these pathways. Not every painkiller works for every type of pain, however. Because of the multitude and redundancy of pain pathways, a perfect painkiller is elusive. But in the meantime, understanding how existing painkillers work helps medical providers and patients use them for the best results.

Anti-Inflammatories

A bruise, sprain or broken bone from an injury all lead to tissue inflammation, an immune response that can lead to swelling and redness as the body tries to heal. Specialized nerve cells in the area of the injury called nociceptors sense the inflammatory chemicals the body produces and send pain signals to the brain.

Common over-the-counter anti-inflammatory painkillers work by decreasing inflammation in the injured area. These are particularly useful for musculoskeletal injuries or other pain problems caused by inflammation such as arthritis.

Nonsteroidal anti-inflammatories like ibuprofen (Advil, Motrin), naproxen (Aleve) and aspirin do this by blocking an enzyme called COX that plays a key role in a biochemical cascade that produces inflammatory chemicals. Blocking the cascade decreases the amount of inflammatory chemicals, and thereby reduces the pain signals sent to the brain.

While acetaminophen (Tylenol), also known as paracetamol, doesn’t reduce inflammation as NSAIDs do, it also inhibits COX enzymes and has similar pain-reducing effects. Prescription anti-inflammatory painkillers include other COX inhibitors, corticosteroids and, more recently, drugs that target and inactivate the inflammatory chemicals themselves. Aspirin and ibuprofen work by blocking the COX enzymes that play a key role in pain-causing processes.

Because inflammatory chemicals are involved in other important physiological functions beyond just sounding the pain alarm, medications that block them will have side effects and potential health risks, including irritating the stomach lining and affecting kidney function. Over-the-counter medications are generally safe if the directions on the bottle are followed strictly.

Corticosteroids like prednisone block the inflammatory cascade early on in the process, which is probably why they are so potent in reducing inflammation. However, because all the chemicals in the cascade are present in nearly every organ system, long-term use of steroids can pose many health risks that need to be discussed with a physician before starting a treatment plan.

Topical Medications

Many topical medications target nociceptors, the specialized nerves that detect tissue damage. Local anesthetics, like lidocaine, prevent these nerves from sending electrical signals to the brain.

The protein sensors on the tips of other sensory neurons in the skin are also targets for topical painkillers. Activating these proteins can elicit particular sensations that can lessen the pain by reducing the activity of the damage-sensing nerves, like the cooling sensation of menthol or the burning sensation of capsaicin.

Because these topical medications work on the tiny nerves in the skin, they are best used for pain directly affecting the skin. For example, a shingles infection can damage the nerves in the skin, causing them to become overactive and send persistent pain signals to the brain. Silencing those nerves with topical lidocaine or an overwhelming dose of capsaicin can reduce these pain signals.

Nerve Injury Medications

Nerve injuries, most commonly from arthritis and diabetes, can cause the pain-sensing part of the nervous system to become overactive. These injuries sound the pain alarm even in the absence of tissue damage. The best painkillers in these conditions are those that dampen that alarm.

Antiepileptic drugs, such as gabapentin (Neurontin), suppress the pain-sensing system by blocking electrical signaling in the nerves. However, gabapentin can also reduce nerve activity in other parts of the nervous system, potentially leading to sleepiness and confusion.

Antidepressants, such as duloxetine and nortriptyline, are thought to work by increasing certain neurotransmitters in the spinal cord and brain involved in regulating pain pathways. But they may also alter chemical signaling in the gastrointestinal tract, leading to an upset stomach.

All these medications are prescribed by doctors.

Opioids

Opioids are chemicals found or derived from the opium poppy. One of the earliest opioids, morphine, was purified in the 1800s. Since then, medical use of opioids has expanded to include many natural and synthetic derivatives of morphine with varying potency and duration. Some common examples include codeine, tramadol, hydrocodone, oxycodone, buprenorphine and fentanyl.

Opioids decrease pain by activating the body’s endorphin system. Endorphins are a type of opioid your body naturally produces that decreases incoming signals of injury and produces feelings of euphoria – the so-called “runner’s high.” Opioids simulate the effects of endorphins by acting on similar targets in the body.

While opioids can provide strong pain relief, they are not meant for long-term use because they are addictive.

Although opioids can decrease some types of acute pain, such as after surgery, musculoskeletal injuries like a broken leg or cancer pain, they are often ineffective for neuropathic injuries and chronic pain.

Because the body uses opioid receptors in other organ systems like the gastrointestinal tract and the lungs, side effects and risks include constipation and potentially fatal suppression of breathing. Prolonged use of opioids may also lead to tolerance, where more drug is required to get the same painkilling effect. This is why opioids can be addictive and are not intended for long-term use. All opioids are controlled substances and are carefully prescribed by doctors because of these side effects and risks.

Cannabinoids

Although cannabis has received a lot of attention for its potential medical uses, there isn’t sufficient evidence available to conclude that it can effectively treat pain. Since the use of cannabis is illegal at the federal level in the U.S., high-quality clinical research funded by the federal government has been lacking.

Researchers do know that the body naturally produces endocannabinoids, a form of the chemicals in cannabis, to decrease pain perception. Cannabinoids may also reduce inflammation. Given the lack of strong clinical evidence, physicians typically don’t recommend them over FDA-approved medications.

Matching Pain to Drug

While sounding the pain alarm is important for survival, dampening the klaxon when it’s too loud or unhelpful is sometimes necessary.

No existing medication can perfectly treat pain. Matching specific types of pain to drugs that target specific pathways can improve pain relief, but even then, medications can fail to work even for people with the same condition. More research that deepens the medical field’s understanding of the pain pathways and targets in the body can help lead to more effective treatments and improved pain management.

Rebecca Seal, PhD, is an Associate Professor of Neurobiology at University of Pittsburgh Health Sciences. Benedict Alter, MD, is an Assistant Professor of Anesthesiology and Perioperative Medicine, at University of Pittsburgh Health Sciences.

This article originally appeared in The Conservation and is republished with permission.

The Conversation

Guideline Recommends Topical Pain Relievers for Muscle Aches and Joint Sprains

By Pat Anson, PNN Editor

A new guideline for primary care physicians recommends against the use of opioid medication in treating short-term, acute pain caused by muscle aches, joint sprains and other musculoskeletal injuries that don’t involve the lower back.

The joint guideline by the American College of Physicians (ACP) and the American Academy of Family Physicians (AAFP) – which collectively represent nearly 300,000 doctors in the U.S. – recommends using topical pain creams and gels containing non-steroidal anti-inflammatory drugs (NSAIDs) as first line therapy. Other recommended treatments include oral NSAIDs, acetaminophen, specific acupressure, or transcutaneous nerve stimulation (TENS).

Musculoskeletal injuries, such as ankle, neck and knee injuries, are usually treated in outpatient settings. In 2010, they accounted for over 65 million healthcare visits in the U.S., with the annual cost of treating them estimated at over $176 billion.

"As a physician, these types of injuries and associated pain are common, and we need to address them with the best treatments available for the patient. The evidence shows that there are quality treatments available for pain caused by acute musculoskeletal injuries that do not include the use of opioids," said Jacqueline Fincher, MD, president of ACP.

Opioids, including tramadol, are only recommended in cases of severe injury or intolerance to first-line therapies. While effective in treating pain, the guideline warns that a “substantial proportion” of patients given opioids for acute pain wind up taking them long-term.   

The new guideline, published in the Annals of Internal Medicine, recommends topical NSAIDs, with or without menthol, as the first-line therapy for acute pain from non-low back, musculoskeletal injuries. Topical NSAIDs were rated the most effective for pain reduction, physical function, treatment satisfaction and symptom relief.

Treatments found to be ineffective for acute musculoskeletal pain include ultrasound therapy, non-specific acupressure, exercise and laser therapy.

"This guideline is not intended to provide a one-size-fits-all approach to managing non-low back pain," said Gary LeRoy, MD, president of AAFP. "Our main objective was to provide a sound and transparent framework to guide family physicians in shared decision making with patients."

Guideline Based on Canadian Research

Interestingly, the guideline for American doctors is based on reviews of over 200 clinical studies by Canadian researchers at McMaster University in Ontario, who developed Canada’s opioid prescribing guideline. The Canadian guideline, which recommends against the use of opioids as a first-line treatment, is modeled after the CDC’s controversial 2016 opioid guideline.  

After reviewing data from over 13 million U.S. insurance claims, McMaster researchers estimated the risk of prolonged opioid use after a prescription for acute pain was 27% for “high risk” patients and 6% for the general population.

"Opioids are frequently prescribed for acute musculoskeletal injuries and may result in long-term use and consequent harms," said John Riva, a doctor of chiropractic and assistant clinical professor in the Department of Family Medicine at McMaster. "Potentially important targets to reduce rates of persistent opioid use are avoiding prescribing opioids for these types of injuries to patients with past or current substance use disorder and, when prescribed, restricting duration to seven days or less and to lower doses."

Riva and his colleagues said patients are also at higher risk of long-term use if they have a history of sleep disorders, suicide attempts or self-injury, lower socioeconomic status, higher household income, rural residency, lower education level, disability, being injured in a motor vehicle accident, and being a Medicaid recipient.

A history of alcohol abuse, psychosis, episodic mood disorders, obesity, and not working full-time “were consistently not associated with prolonged opioid use.”

The McMaster research, also published in the Annals of Internal Medicine, was funded by the National Safety Council (NSC), a non-profit advocacy group in the U.S. supported by major corporations and insurers. The NSC has long argued against the use of opioid pain relievers, saying they “do not kill pain, they kill people.”