High Power Laser Therapy

Original Editor - Pooja Sethi Top Contributors - Pooja Sethi, Lucinda hampton, Sai Kripa and Kim Jackson

Introduction[edit | edit source]

LASER means Light Amplification from Stimulated Emission of Radiation. Laser is created by specific process within the laser device to cause the controlled emission of radiation in form of light. Laser usually comes in one color and it comes in a thin beam. Lasers were first invented by physicist Gordon Gould in 1958 and first working model was built in 1960.They have been used in Europe and America for more than forty years and have been used in fields of dermatology, surgery. ophthalmology and physical medicine and rehabilitation. Laser is used by physiotherapists for relief of pain, to accelerate healing and decrease inflammation.[1]

Difference between Low Level Laser Therapy and High Power Laser Therapy[edit | edit source]

An output power of less than 0.5 Watts is classed as Low Level Laser Therapy LLLT ( class III in the USA) whereas lasers with an output powers greater than 500mW or 0.5 Watts are termed High Power Laser Therapy HPLT (Class IV lasers in the USA). HPLT creates heat on the surface of the skin due to their higher power density (irradiance). LLLT is often referred to as “Cold Lasers” since they do not create a heating sensation during treatment.[2]

Production of Laser[edit | edit source]

Laser device is made up of an optical cavity or chamber that contains active medium for which laser is named. The chamber has mirrors on either end that are perfectly parallel to each other within a single wavelength of light. One of the mirror is partially open. Electricity or energy is added to the medium which excites it. The active medium atoms are reflected back and forth across the mirrors within the chambers. This cause more excitation of atoms within the medium. Laser light is then emitted through the partially reflective end of mirror. The light production occurs in the following steps:

1.Electron is pumped to a higher energy level.

2.Pumping level is unstable so the electron quickly jumps to a slightly lower energy level.

3.Electron relaxes to a lower energy state and releases a photon.

4.Light and an electron in an excited energy level produces two photons of same wavelength and phase.

5.Mirror reflects the photons or laser light is emitted.[1]

Characteristics of Laser[edit | edit source]

Due to specific nature of laser production, it also has specific characteristics;

1. Monochromaticity - ‘mono’ means single. ‘Chromaticity’ meaning color. Laser when emitted produces single pure color because it has one specific wavelength.

2. Coherence- Laser rays are synchronous to each other. The crest and trough of individual rays matches each other.

3. Collimation- It is also termed as non-divergence. Laser rays travel parallel to each other. [1]

How does Laser Work[edit | edit source]

When the light source is placed against the skin, the photons penetrates several centimetres and gets absorbed by the mitochondria. The energy fuels many positive physiological responses resulting in restoration of normal cell morphology and function but at enhanced rate.Targeted in haemoglobin and cytochrome oxidase, the high power diode laser could help in respiration and then in result have a good performance therapy.[2]

[3]

Indications[edit | edit source]

Physiotherapists use HPLT basically on the presumption that energized cells from the laser increase the rate of healing.

Class IV hot laser therapy (high intensity laser therapy) can treat a variety of conditions, such as:

Contraindications[edit | edit source]

  • Pregnancy
  • Tumor
  • Hemorrhage
  • Pacemaker
  • Thrombosis[1]

Precautions[edit | edit source]

•Should  wear laser‐protective glasses or goggles

•Inappropriate  use of the goggles is more dangerous than their non‐use, as they may provide a false sense of security.

•Laser equipment should be placed in a controlled area with minimal access to avoid inadvertent exposure

•Avoid  laser reflection from mirrored surfaces

•Avoid –  exposure of eyes, unclosed fontanels of children.[1]

Evidence[edit | edit source]

The results of 2018 study entitled "Effectiveness of high-intensity laser therapy in the treatment of musculoskeletal disorders. A systematic review and meta-analysis of randomized controlled trials" concluded that HILT treatment for back and neck pain significantly improved pain and disability scores compared with controls. It also commented that additional well-designed studies involving larger samples with long-term follow-up were needed to further assess each laser application, treatment region, and comparator.[4]

A 2017 review titled "Effective treatment options for musculoskeletal pain in primary care: A systematic overview of current evidence" concluded that the evidence on effectiveness of laser therapy for shoulder pain or acute or chronic neck pain was inconclusive. With regards to knee pain low level laser therapy may confer added benefits to exercise and / or surgical treatment. [5]

References[edit | edit source]

  1. 1.0 1.1 1.2 1.3 1.4 1.5 William E. Prentice. Therapeutic modalities in rehabilitation. 3rd Edition, McGraw-Hill Medical, 2017
  2. 2.0 2.1 Lasers in Physical Therapy 10.10.2012 Laser Available from: http://www.mccc.edu/~behrensb/documents/LasersinPhysicalTherapy2012.pdf (last accessed 24.6.2019)
  3. BTLmedical High Intensity Laser - Medical Effects Available from: https://www.youtube.com/watch?v=kn7JXDGpEfI (last accessed 24.6.2019)
  4. Song HJ, Seo HJ, Lee Y, Kim SK. Effectiveness of high-intensity laser therapy in the treatment of musculoskeletal disorders: A systematic review and meta-analysis of randomized controlled trials. Medicine. 2018 Dec;97(51). Available from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6319951/ (last accessed 24.6.2019)
  5. Babatunde OO, Jordan JL, Van der Windt DA, Hill JC, Foster NE, Protheroe J. Effective treatment options for musculoskeletal pain in primary care: A systematic overview of current evidence. PloS one. 2017 Jun 22;12(6):e0178621. Available from: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC5480856/ (last accessed 24.6.2019)