Light Therapy and Arthritis

Some sources of near infrared and red light have actually been used clinically for the treatment of arthritis since the late 1980s. By the year 2000, enough scientific evidence existed to recommend it for all arthritis sufferers1 regardless of cause or severity. Since then there have been several hundred quality clinical studies trying to refine the parameters for all joints that can be affected. The effectiveness is apparent in some people, as this news report shows:

Light therapy and its use on arthritis

The first major symptom of arthritis is pain, often excruciating and debilitating as the condition progresses. This is the first way in which light therapy is studied – by potentially reducing the inflammation in the joint and thus reducing the pain. Practically all areas have been studied in human clinical trials including on; the knees [5-12],[33], shoulders [15,38], jaw [26,27,36,37,] fingers/hands/wrists [14,15,40], back [34,35], elbows, neck [17,29] and ankles/feet/toes.

The knees seem to be the most well studied joint in humans, which is understandable considering it is perhaps the most commonly affected area. Arthritis of any type here has serious implications like disability and inability to walk. Fortunately most studies using red/IR light on the knee joint show some interesting effects, and this is true over a wide range of treatment types. Fingers, toes, hands and wrists appear to be the simplest to address of all arthritic problems, due to their relatively small size and shallow depth.

Osteoarthritis and rheumatoid arthritis are the major types of arthritis being studied, due to their prevalence, although there is reason to believe the same treatment might be of interest for other types of arthritis (and even unrelated joint problems such as injury or post-surgery) such as psoriatic, gout and even juvenile arthritis. Treatments for osteoarthritis tend to involve direct application of light over the affected area. Successful treatments for rheumatoid arthritis can be the same but some also involve application of light to the blood [18,19,21]. As rheumatoid arthritis is an autoimmune condition this makes sense – the joints are just the symptom, the actual root problem is in the immune cells.

The mechanism – what red/infrared light does

Before we can understand the interaction of red/IR light with arthritis, we need to know what causes arthritis.

Causes

Arthritis can be the result of chronic inflammation of a joint, but can also develop suddenly, after periods of stress or injury (not necessarily injury to the arthritic area). Usually the body is able to repair the daily wear and tear on joints, but can lose this ability, leading to the onset of arthritis.

  • A reduction in oxidative metabolism, the ability to convert glucose/carbohydrates into energy is linked strongly to arthritis.

    • Clinical hypothyroidism is frequently associated with arthritis30, with both often diagnosed around the same time.
    • More recent studies have shown more details of the metabolic defect in glucose metabolism is linked to rheumatoid arthritis
  • There’s a definite hormonal link to most types of arthritis

    • This is shown by how becoming pregnant can completely clear up (or at least change) arthritic symptoms in some women.

    • Rheumatoid arthritis is also 3+ times more frequent in women than in men (and harder to women to cure), further confirming the hormonal link.

    • Adrenal hormones (or lack thereof) have also been linked to all arthritis for over 100 years now [20].

    • Changes in liver health/function are strongly linked to rheumatoid arthritis

  • Calcium deficiency is also linked to arthritis, along with various other nutrient deficiencies.

    • In fact, abnormal calcium metabolism is present in all types of arthritis.

The list of causes goes on, with many factors potentially playing a role. While the exact cause of arthritis is still debated in general (and different for osteo / rheumatoid etc.), it’s obvious there is some connection to lowered energy production and the downstream effect that has on the body, eventually leading to the joint inflammation.

Early treatment of arthritis with ATP (the cellular energy metabolism product) had positive results20, and this is the same energy molecule that red/IR light therapy helps our cells to produce….

Mechanism

The main hypothesis behind light therapy is that red and near infrared wavelengths of light between 600nm and 1000nm are absorbed by our cells39, increasing natural energy (ATP) production. This process is termed ‘photobiomodulation’ by researchers in the field. Specifically we see an increase in mitochondrial products such as ATP, NADH, and even co2 – the normal result of a healthy, unstressed metabolism.

It even seems that our bodies have evolved to be penetrated by, and usefully absorb, this type of light. The controversial part of the mechanism is the specific chain of events on the molecular level, of which there are several hypotheses:

  • Nitric oxide (NO) is released from cells during light therapy. This is a stress molecule that inhibits respiration, so sending it out of the cells is a good thing. The specific idea is that red/IR light is dissociating NO from cytochrome c oxidase in the mitochondria, thus allowing oxygen to be processed again.
    • Reactive oxygen species (ROS) are released in small amounts after light therapy.
    • Vasodilation is potentially stimulated by red/IR light therapy – something related to NO and very significant for joint inflammation and arthritis.

Red/IR light also has an effect on (cellular) water, increasing the distance between each water molecule. What this means is the physical properties of a cell change – reactions happen more smoothly, enzymes and proteins have less resistance, diffusion is better. This is inside cells but also in the blood and other intercellular spaces. Much of life (on the cellular level) is not yet understood and red/IR light seems to be fundamental to life in some way, much more so than many other colours/wavelengths of light. Based on the evidence, it seems likely that both of the above hypotheses are happening, and probably other as yet unknown mechanisms too.

There is plenty of evidence of a broader systemic effect from irradiating veins and arteries anywhere on the body, plus increased blood flow/microcirculation and reduced inflammation locally. The bottom line is that red/IR light reduces local stress and so helps your cells to function optimally again – and the cells of the joints are no different in this.

Red or Infrared?

The main difference between red (600-700nm) and infrared (700-100nm) light seems to be the depth to which they can penetrate, with wavelengths higher than 740nm penetrating better than wavelengths under 740nm – and this has practical implications for arthritis. A low power red light may be appropriate for arthritis of the hands and feet, but it could fall short for arthritis of the knees, shoulders and bigger joints. The majority of arthritis light therapy studies use infrared wavelengths for this very reason and the studies comparing red and infrared wavelengths show better results from the infrared.

Ensuring penetration to the joints

The two main things affecting tissue penetration are the wavelengths and the strength of the light hitting the skin. In practical terms, anything below the wavelength of 600nm or over the wavelength of 950nm won’t penetrate deeply. The 740-850nm range seems to be the sweet spot for optimal penetration and around 820nm for maximum effects on the cell. Strength of the light (aka power density / mW/cm²) also affects penetration with 50mW/cm² over a few cm² area being a good minimum. So essentially, this boils down to a device with wavelengths in the 800-850nm range and greater than 50mW/cm² power density.

References:

References

  1. Low level laser therapy for osteoarthritis and rheumatoid arthritis: a metaanalysis. Brosseau et al. 2000.
  2. Low level laser therapy (Classes I, II and III) for treating osteoarthritis. Brosseau et al. 2004.
  3. Effect of low-level laser therapy on the expression of inflammatory mediators and on neutrophils and macrophages in acute joint inflammation. Alves et al. 2013.
  4. Can osteoarthritis be treated with light? Michael R Hamblin, 2013.
  5. Effect of low-level laser therapy (904 nm) and static stretching in patients with knee osteoarthritis: a protocol of randomised controlled trial. Ferreira de Meneses et al. 2015.
  6. Does addition of low-level laser therapy (LLLT) in conservative care of knee arthritis successfully postpone the need for joint replacement? Ip et al. 2015.
  7. High-intensity versus low-level laser therapy in the treatment of patients with knee osteoarthritis: a randomized controlled trial. Kheshie et al. 2014
  8. Short-term efficacy of physical interventions in osteoarthritic knee pain. A systematic review and meta-analysis of randomised placebo-controlled trials. Bjordal et al. 2007.
  9. Efficacy of low-level laser therapy applied at acupuncture points in knee osteoarthritis: a randomised double-blind comparative trial. Al Rashoud et al. 2014.
  10. Effect of low-level laser therapy in patients with chronic knee osteoarthritis: a single-blinded randomized clinical study. Alghadir et al. 2014.
  11. Influence of various laser therapy methods on knee joint pain and function in patients with knee osteoarthritis. Gworys et al. 2012.
  12. Efficacy of low level laser therapy associated with exercises in knee osteoarthritis: a randomized double-blind study. Alfredo et al. 2012.
  13. The effect of low-level laser in knee osteoarthritis: a double-blind, randomized, placebo-controlled trial. Hegedus et al. 2009.
  14. Synergic effects of ultrasound and laser on the pain relief in women with hand osteoarthritis. Paolillo et al. 2015.
  15. A systematic review of low level laser therapy with location-specific doses for pain from chronic joint disorders. Bjordal et al. 2003.
  16. Meta-Analysis of Pain Relief Effects by Laser Irradiation on Joint Areas. Ho Jang et al. 2012.
  17. Low Level Laser Therapy (LLLT) for Neck Pain: A Systematic Review and Meta-Regression. Anita R Gross et al. 2013.
  18. The influence of intravenous laser irradiation of the blood on the dynamics of leptin levels and the quality of life of the patients presenting with rheumatoid arthritis. Burduli et al. 2015.
  19. Reduction of IL-20 Expression in Rheumatoid Arthritis by Linear Polarized Infrared Light Irradiation. Imaoka et al. 2014.
  20. Treatment of Rheumatoid Arthritis with ATP. Birger Carlström and Olle Lövgren. 1949.
  21. Low-level laser therapy in different stages of rheumatoid arthritis: a histological study. Alves et al. 2013.
  22. Low-level laser therapy for zymosan-induced arthritis in rats: Importance of illumination time. Castano et al. 2007.
  23. Effects of low-level laser therapy at wavelengths of 660 and 808 nm in experimental model of osteoarthritis. da Rosa et al. 2012.
  24. Anti-inflammatory activities of light emitting diode irradiation on collagen-induced arthritis in mice (a secondary publication). Kuboyama et al. 2014.
  25. Photobiomodulation of pain and inflammation in microcrystalline arthropathies: experimental and clinical results. Soriano et al. 2006.
  26. Low-level laser therapy stimulates tissue repair and reduces the extracellular matrix degradation in rats with induced arthritis in the temporomandibular joint. Lemos et al. 2016.
  27. Effect of low-level laser on healing of temporomandibular joint osteoarthritis in rats. Peimani et al. 2014.
  28. Effect of light-emitting diode (LED) therapy on the development of osteoarthritis (OA) in a rabbit model. Oshima Y. 2011.
  29. Efficacy of low-level laser therapy in the management of neck pain: a systematic review and meta-analysis of randomised placebo or active-treatment controlled trials. Chow et al. 2009.
  30. Rheumatoid arthritis and thyroid abnormalities. Staykova. 2007.
  31. Laser Ther. 2011; 20(3): 205–215. Is light-emitting diode (LED) phototherapy really effective? Won-Serk Kim and R Glen Calderhead
  32. An Bras Dermatol. 2014 Jul-Aug;89(4):616-23. Effects of low-power light therapy on wound healing: LASER x LED. Chaves ME et al., 2014.
  33. Improvement of pain and disability in elderly patients with degenerative osteoarthritis of the knee treated with narrow-band light therapy. Stelian et al. 1992.
  34. In chronic low back pain, low level laser therapy combined with exercise is more beneficial than exercise alone in the long term: a randomised trial. Djavid et al. 2007.
  35. Laser therapy: a randomized, controlled trial of the effects of low-intensity Nd:YAG laser irradiation on musculoskeletal back pain. Basford et al. 1999.
  36. Evaluation of low-level laser therapy in the treatment of temporomandibular disorders. Cetiner et al. 2006.
  37. Lasertherapy efficacy in temporomandibular disorders: control study. Santos Tde et al. 2010.
  38. Low-power laser treatment in patients with frozen shoulder: preliminary results. Stergioulas. 2008.
  39. Exact action spectra for cellular responses relevant to phototherapy. Karu et al. 2005.
  40. Positive effects of low level laser therapy (LLLT) on Bouchard’s and Heberden’s osteoarthritis. Baltzer et al. 2016