Fascia: An Overlooked Cause of Chronic Pain

By Dr. Adam Taylor, Lancaster University

We are constantly reminded about how exercise benefits our bone and muscle health or reduces fat. However, there is also a growing interest in one element of our anatomy that is often overlooked: our fascia.

Fascia is a thin casing of connective tissue, mainly made of collagen – a rope-like structure that provides strength and protection to many areas of the body. It surrounds and holds every organ, blood vessel, bone, nerve fibre and muscle in place. And scientists increasingly recognise its importance in muscle and bone health.

It is hard to see fascia in the body, but you can get a sense of what it looks like if you look at a steak. It is the thin white streaks on the surface or between layers of the meat.

Fascia provides general and special functions in the body, and is arranged in several ways. The closest to the surface is the superficial fascia, which is underneath the skin between layers of fat. Then we have the deep fascia that covers the muscles, bones and blood vessels.

The link between fascia, muscle and bone health and function is reinforced by recent studies that show the important role fascia has in helping the muscles work, by assisting the contraction of the muscle cells to generate force and affecting muscle stiffness.

Each muscle is wrapped in fascia. These layers are important as they enable muscles that sit next to, or on top of, each other to move freely without affecting each other’s functions.

Fascia also assists in the transition of force through the musculoskeletal system. An example of this is our ankle, where the achilles tendon transfers force into the plantar fascia. This sees forces moving vertically down through the achilles and then transferred horizontally into the bottom of the foot - the plantar fascia – when moving.

Similar force transition is seen from muscles in the chest running down through to groups of muscles in the forearm. There are similar fascia connective chains through other areas of the body.

When Fascia Gets Damaged

When fascia doesn’t function properly, such as after injury, the layers become less able to facilitate movement over each other or help transfer force. Injury to fascia takes a long time to repair, probably because it possesses similar cells to tendons (fibroblasts), and has a limited blood supply.

Recently, fascia, particularly the layers close to the surface, have been shown to have the second-highest number of nerves after the skin. The fascial linings of muscles have also been linked to pain from surgery to musculoskeletal injuries from sports, exercise and ageing. Up to 30% of people with musculoskeletal pain may have fascial involvement or fascia may be the cause.

A type of massage called fascial manipulation, developed by Italian physiotherapist Luigi Stecco in the 1980s, has been shown to improve the pain from patellar tendinopathy (pain in the tendon below the kneecap), both in the short and long term.

Fascial manipulation has also shown positive results in treating chronic shoulder pain.

One of the growing trends for helping with musculoskeletal injuries is Kinesio tape, which is often used in professional sports, although evidence for its effectiveness is mixed. It is also being used to complement the function of the fascia, and is used to treat chronic lower back pain where fascial involvement is a factor.

Fascia in Disease

Aside from getting damaged, fascia can also provide paths that infections can travel along, within muscles.

The spaces between fascial layers are usually closed (think of cling film being folded over), but when an infection occurs, germs can spread between these layers. This is a particular problem in the neck, where there are several layers of fascia for infections to travel along. In severe cases, surgery is often needed to remove the dead tissue and save the healthy remaining tissue.

One of the primary examples of fascia functioning in health, and the challenges its dysfunction can bring, is seen in the common complaint plantar fasciitis, which causes pain on around the heel and arch of the foot.

This incredibly common ailment affects 5-7% of people, rising to 22% in athletes. It is recognised as an overuse injury, causing the thickening of the fascial bands on the soles of the feet that help give the arch support.

Fascia can also be implicated in more serious health conditions, such as necrotising fasciitis. This is a rare but serious bacterial condition that can spread through the body quickly and cause death.

The condition is almost always caused by bacteria, specifically group A Streptococcus or Staphylococcus aureus. The initial infection comes from a cut or scratch, and then the bacteria travel along the fascia to other areas away from the initial site of access and multiply in the ideal environment afforded by the warm recesses of the body.

One reason fascia has been overlooked in health and disease is because it was difficult to see using current imaging technology. More recently, though, MRI and ultrasound imaging have been shown to be beneficial in visualising fascia, particularly in musculoskeletal conditions such as plantar fasciitis, and pathological changes in the fascia of the shoulder and neck.

With the growing interest in fascia and the growing understanding of its contribution to musculoskeletal health, it’s sensible to suggest that we look after it in the same way we do with the rest of the musculoskeletal system - by using it. Simple techniques like foam rollers and stretching are beneficial in increasing mobility, but there is still much to learn about our fascia and the role it plays in our day-to-day health.

Adam Taylor, PhD, is a Professor and Director of the Clinical Anatomy Learning Centre at Lancaster University. His research interests lie within the field of osteoarthritis and the degeneration of cartilage and bone.

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

Long Covid May Affect Genes Involved in Pain Signaling

By Pat Anson, PNN Editor

About 16 million people in the United States have Long Covid, a poorly understood disorder that causes body aches, headaches, fatigue, insomnia, brain fog and other symptoms long after an initial infection with COVID-19. For some, the symptoms are mild, but for other they are so severe they become disabling.

Why do some people quickly recover from Covid, while about one in five have lingering symptoms?

A new animal study found that thousands of genes involved in nervous system function are affected by SARS-CoV-2, and may cause lasting damage to dorsal root ganglia, the spinal nerves that carry pain and other sensory messages to the brain. Scientists believe that genetic damage may be what causes Long Covid.

“Several studies have found that a high proportion of Long Covid patients suffer from abnormal perception of touch, pressure, temperature, pain or tingling throughout the body. Our work suggests that SARS-CoV-2 might induce lasting pain in a rather unique way, emphasizing the need for therapeutics that target molecular pathways specific to this virus,” explains co-author Venetia Zachariou, PhD, chair of pharmacology, physiology & biophysics at Boston University’s Chobanian & Avedisian School of Medicine.

Zachariou and her colleagues infected hamsters with SARS-CoV-2 and studied how it affected the animals’ sensitivity to touch, both during the initial infection and after the infection had cleared. Then they compared the effects of SARS-CoV-2 to those triggered by an influenza A virus infection, and were surprised by what they found.

In the hamsters infected with Covid, researchers observed a slow but progressive increase in sensory sensitivity over time – one that differed substantially from influenza A infections, which caused a sudden hypersensitivity that returned to normal once the initial infection ended.

Although the studies were performed on animals, researchers say they align with the acute and chronic symptoms caused by Covid in humans. They hope further studies on human genes and sensory pathways affected by the Covid virus will lead to new treatments for Long Covid and conditions such as ME/CFS (myalgic encephalomyelitis/chronic fatigue syndrome),

“We hope this study will provide new avenues for addressing somatosensory symptoms of long COVID and ME/CFS, which are only just now beginning to be addressed by mainstream medicine. While we have begun using this information by validating one promising target in this study, we believe our now publicly available data can yield insights into many new therapeutic strategies,” adds Zachariou. 

The study findings appear online in the journal Science Signaling.

The federal government’s Covid public health emergency officially ends this week, but the impact of the pandemic will likely be felt for years to come.

Intractable Pain Syndrome Has 2 Kinds of Pain

By Forest Tennant, PNN Columnist

A major reason that persons with Intractable Pain Syndrome (IPS) experience such misery is that when pain is the constant, 24/7 variety, it has two parts: ascending and descending pain. Both types need to be treated for relief.

Picture your body running on electric currents. In your house, electric currents are conducted by wire. Although there is no good reason to avoid the term “wire” when it comes to the human body, we usually refer to our biologic wires as nerves, nerve roots or neurons.

Unfortunately, any disease or injury to one or more of our “wires” blocks the electric currents that normally flow through the nerves, nerve roots or neurons, and diverts electricity into the surrounding tissue to produce inflammation and pain.

Ascending Pain is caused when pain electricity travels from the disease or injury site up the nervous system to the brain. This is the most common type of pain. For example, if you have a sore knee, pain signals travel from the knee to the brain.

Descending Pain is caused when severe pain from any number of diseases and injuries sends so much electricity into the brain and spinal cord that it accumulates. Areas of inflammation develop and destroy and/or damage the dopamine-noradrenaline neurotransmitter systems that control descending pain.

The excess electricity from these inflamed sites travels down the nervous system into muscles, skin, tendons, joints, fatty tissues, and the large and small peripheral nerves. Small nerve endings in the skin can “burn out” due to all the descending electricity and a skin biopsy will probably show small fiber neuropathy.

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How do you know if you have descending pain? You have muscle aches all over which are often labeled as fibromyalgia. You hurt everywhere and experience episodes of overheating, sweating, and cold hands and feet, often at the same time!

Tips to Reduce Descending Pain

The critical point is that usual pain treatment only treats ascending pain, not descending pain. Opioids, antidepressants, anti-inflammatories and muscle relaxants do not usually do much for descending pain.

Each person with IPS must adopt a few simple but specific medical, physical, and dietary measures to attain some relief and recovery from both kinds of pain. You must maintain your dopamine-noradrenaline neurotransmitter systems daily, or you will have increased pain and misery, and believe that more drugs like opioids are the answer.

The understanding of blocked and diverted electric currents has led to the identification and labeling of a group of treatment agents that help normalize electric currents. These are known as neuropathic agents. The neurotransmitter most responsible for the proper conduction of electric currents is called gamma aminobutyric acid (GABA for short). It is synthesized by the body from the amino acid glutamine.

Neuropathic medications include gabapentin, pregabalin, carisoprodol, topiramate, duloxetine, and benzodiazepines.

In addition to neuropathic agents, there are simple “age-old” remedies that still work for most people because they help modulate electric currents so that they don’t divert, accumulate, and cause more inflammation and pain:

  • Water Soaking

  • Epsom or Herbal Salts

  • Magnets

  • Acupuncture

  • Copper Jewelry

  • Walking Barefoot

  • Dry Needling

  • Petting Fur

  • Magnesium

Every person with IPS needs a daily program of neuropathic agents and age-old remedies to minimize the consequences of accumulated electricity.

Forest Tennant is retired from clinical practice but continues his groundbreaking research on intractable pain and arachnoiditis. This column is adapted from newsletters recently issued by the IPS Research and Education Project of the Tennant Foundation. Readers interested in subscribing to the newsletter can sign up by clicking here.

The Tennant Foundation has given financial support to Pain News Network and is currently sponsoring PNN’s Patient Resources section.