Dimed Laser Treatment For Veterinary Pain Management , 810 / 910 / 980nm

LASER FUNDAMENTALS

Therapeutic lasers help modulate cellular functions through a process called photobiomodulation, a photochemical process in which photons from a laser source interact with the target cells via a non-thermal mechanism to cause either stimulation or inhibition of biochemical pathways. While the precise mechanism for photobiomodulation is not completely understood, it appears that cytochrome C, located in the mitochondria, serves as an important photoreceptor. Once light is absorbed by cytochrome C, mitochondrial respiration and ATP production increase, leading to global tissue effects.

BENEFITS OF THERAPEUTIC LASER

Most responses of cells and tissues to therapeutic laser have been studied in in vitro models (cell culture). There appear to be many distinct benefits to using therapeutic laser for its tissue effects. Therapeutic laser has been demonstrated to relieve both chronic and acute pain by modulating peripheral nerve function and nerve conduction velocities. Laser energy increases the speed of tissue repair by increasing local microcirculation as well as stimulating the immune system and reducing inflammation. Laser energy also enhances collagen and muscle tissue development, which in turn enhances healing.

There are several important “downstream” tissue effects from the application of laser light. These effects include:

• Neovascularization

• Angiogenesis

• Collagen synthesis which enhances wound healing

• Stimulation of nerve healing

• Enhanced healing of tendons, cartilage, and bones

• Reduced swelling from injury

• Modulation of degenerative tissue changes

• Mitigation of CNS damage following traumatic brain injury and spinal cord injury

When creating a treatment protocol for therapeutic laser, it is important to consider these effects in order to maximize patient outcome. The actual time the tissue is exposed to light energy may also affect the outcome.

LASER SAFETY

There are some important safety considerations when incorporating therapeutic laser into treatment protocols. Protective glasses with lenses rated to the specific wavelength of the treatment laser are important for both humans and patients in order to protect retinal tissue. Laser energy should not be applied over a pregnant uterus, over tumors, over an open fontanel, over the growth plates of immature animals, or over the thyroid gland. Be careful if the pet has a tattoo, black fur, or black skin because of the potential for light absorption and tissue heating.

APPLYING THERAPEUTIC LASER TO DOGS AND CATS

The optimal wavelengths, intensities, and dosages for laser therapy in pets have not yet been adequately studied or determined, but this is sure to change as studies are designed and as more case-based information is reported. To maximize laser penetration, the pet’s hair should be clipped. When treating traumatic, open wounds, the laser probe should not contact the tissue, and the dose often quoted is 2 J/cm2 to 8 J/cm2. When treating a post-operative incision, a dose of 1 J/cm2 to 3 J/ cm2 per day for the first week after surgery is described. Lick granulomas may benefit from therapeutic laser once the source of the granuloma is identified and treated. Delivering 1 J/cm2 to 3 J/cm2 several times per week until the wound is healed and the hair is re-growing is described. Treatment of osteoarthritis (OA) in dogs and cats using therapeutic laser is commonly described. The laser dose that may be most appropriate in OA is 8 J/cm2 to 10 J/cm2 applied as part of a multi-modal arthritis treatment plan. Finally, tendonitis may benefit from laser therapy due to the inflammation associated with the condition.

LASER THERAPY OF THE FUTURE

Therapeutic laser is of special interest in the area of nerve regeneration, particularly in human medicine. Veterinary patients experience peripheral nerve issues as they age, as osteoarthritis develops and progresses, in the wake of intervertebral disk disease, and when they develop nervous system decline as occurs in degenerative neuropathy/myelopathy. Photobiomodulation has been demonstrated to support nerve regeneration, re-innervation of denervated muscle, and functional recovery following peripheral nerve injury. This is an area of active research that promises to provide a significant impact on both human and veterinary patients.