Wrist Watch hyperviscosity Treatment 650nm Low Level ...

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Every day, the human body harnesses the power of light through a series of intricate photochemical reactions. From the photosensitive cells that enable our vision to the synthesis of vitamin D in our skin, light plays an indispensable role in our physiological processes. Given this intimate relationship between light and cellular activity, one naturally wonders: how might other cells in our body respond to light, and can we leverage this response for therapeutic purposes? Enter Low-Level Laser Therapy (LLLT) &#; also known as Cold Laser Therapy or Photobiomodulation (PBM) Therapy &#; a groundbreaking treatment method that delves into the fascinating intersection of light and cellular health.

Erchonia&#;s EVRL® Laser

: The only LLLT device to be FDA Market Cleared for treating chronic / acute back, neck, and shoulder pain, and pain associated with surgery.

What Is Low-Level Laser Therapy (LLLT)?

Discovered in by Endre Mester, Low-Level Laser Therapy involves placing a low-power laser near to or on the skin, allowing the photons to move through the tissue and interact with cells in the body.

A Low-Level Laser can be roughly categorised as having a power output of less than 500mW, and is classified by the FDA as either &#;Class IIIB Lasers&#;, &#;Class IIIR Lasers&#;, or &#;Class II Lasers&#; (i.e. low risk of hazard). Various dosimetry parameters (e.g. wavelength, fluence, power density) are used depending on the device / treatment type.

What Are the Benefits of Low-Level Laser Therapy (LLLT) and How Does It Work?

Since the development of the procedure, the benefits of LLLT have been studied at length &#; the photochemical changes that occur in cells as a reaction to the application of light can help in many ways, including:

1. Pain Management
   Pain is the most common reason that people see doctors, with roughly one in ten people affected by chronic pain each year
   . Low-Level Laser Therapy has been explored in clinical studies as a way of decreasing several types of pain, including:
   
   &#; Orthopaedic pain: LLLT has pain-reducing effects on musculoskeletal conditions
   such as those experienced by patients recovering from sprains, whiplash, muscular pain, cervical or lumbar radiculopathy, tendinitis, and carpal tunnel syndrome. It has also shown positive effects on individuals with chronic conditions
   like arthritis and osteoarthritis, and in treating post-surgical dental pain
   .
   
   &#; Neuropathic pain: Neuropathic pain conditions can be treated effectively
   with LLLT, including various types of neuralgia and diabetic neuropathy.
   
   Although we still have a lot to learn about the effects of light energy on different types of cells, the leading theory is that Low-Level Laser Therapy generates therapeutic effects through stimulating and enhancing specific biochemical processes. Intuitively speaking, laser energy activates a key enzyme in our cells&#; powerhouses (mitochondria), boosting energy production and cellular activity. This process enhances cell function, aids in cell repair and growth, and supports overall cellular health, leading to improved healing and regeneration.
   
   More specifically, utilising the first law in photochemistry (Grotthuss-Draper law), laser energy is transferred to cytochrome c oxidase (CcO) &#; a respiratory energy-transducing enzyme which is involved in the electron transport chain in mitochondria. This energy transfer causes photodissociation of inhibitory nitric oxide from CcO, leading to an enhancement of enzyme activity, electron transport, mitochondrial respiration, and adenosine triphosphate (ATP) production. Consequently, by altering the cellular redox state, LLLT induces the activation of numerous intracellular signalling pathways, and alters the affinity of transcription factors concerned with cell proliferation, survival, repair, and regeneration.

2. Fat Removal
   Multiple studies have been conducted to determine whether Low-Level Laser Therapy can be used for fat reduction, with positive results. One review
    found that LLLT is effective at reducing fat and cellulite and improves blood lipid profiles with little to no side effects.
   
   The current theory as to why LLLT is effective in this area is that it creates transient pores in adipocytes (fat cells), allowing lipids (fatty liquids) to leak out. The fatty liquids are then naturally flushed out through the lymphatic system.
   
   The result is that the fat cells shrink instead of being killed. When this happens, the shrunken fat cells begin to act and function like healthy lean cells, releasing the correct messages to the brain and creating a communication effect throughout the fat organ, causing other fat cells to release their content and return their hormone responses to the positive.
   
   Procedures that have been popular in the past (such as fat freezing) focus on the elimination of fat cells, but recent research has shown this approach to be less effective, and in the worst-case scenario, providing counterproductive results
   .

Erchonia&#;s Emerald® Laser

: Fully automated Laser Lipo machine &#; only device on the market that is FDA-cleared for body circumference reduction on up to 40 BMI.

3. Fungal Nail Treatment
   The unsightly onychomycosis is a fungal infection of the nails that causes discoloration, thickening, and separation from the nail bed. It is a very common condition
   , occurring in approximately 10% of the general population, with those over 60 being especially affected (20% &#; 50%).
   
   The most common treatments for fungal nail infections include antifungal nail creams (largely ineffective) and prescription antifungal medications taken orally (can cause side effects). Low-Level Laser Therapy has been shown to effectively treat nail fungus
   with little to no side effects.
   
   Although the exact mechanism of action is currently unclear, it is theorised that LLLT triggers a photochemical reaction, producing Reactive Oxygen Species (ROS) which is converted to Hydrogen Peroxide &#; a natural antiseptic that kills onychomycosis. In addition, LLLT induces the production of Adenosine Triphosphate (ATP) which is converted to Nitric Oxide, aiding the natural immune response in fighting the infection.

Erchonia&#;s Lunula® Laser: The only fully automated machine for treating nail fungus, and the only cold laser to be FDA-cleared for fungal nail treatment.

4. Hair Regrowth
   Low-Level Laser Therapy has shown promising results

   With competitive price and timely delivery, Easetak sincerely hope to be your supplier and partner.

   in the treatment of hair loss. LLLT is often used to address various forms of hair thinning and baldness, such as androgenetic alopecia
   (pattern baldness) and telogen effluvium
   (temporary hair shedding).
   
   The primary mechanism behind LLLT for hair loss involves the absorption of laser light by the cells in the hair follicles. This light energy is believed to trigger the release of nitric oxide, which improves vascularization and oxygen supply to the follicles. Additionally, LLLT can increase the levels of ATP in follicular cells, providing them with the necessary energy to grow thicker, healthier hair.
   
   While more research is needed to fully understand the extent of LLLT&#;s benefits for different types of hair loss, current studies and clinical trials indicate that it is a safe and effective option for those seeking to improve their hair growth and density.

What Are the Side Effects of Low-Level Laser Therapy (LLLT) and Is It Safe?

Low-Level Laser Therapy is widely regarded as a safe treatment choice, particularly when conducted under the expert guidance of medical professionals. The non-invasive nature of the therapy and its avoidance of high heat reduce the risk of complications, affirming its safety profile. Regulatory bodies such as the FDA categorise LLLT devices as low-risk, further validating their safety for therapeutic use.

Despite its well-documented benefits and robust safety record, LLLT may cause minor side effects, such as temporary discomfort at the treatment site, mild skin irritation, or occasionally, an increase in pain or swelling immediately post-treatment. These symptoms are generally transient and resolve on their own.

Overall, the low incidence of side effects makes LLLT a compelling option for the management of various conditions, underscoring its effectiveness and safety.

What Is the Difference Between Low-Level Laser Therapy (LLLT) and High-Level Laser Therapy (HLLT)?

To understand the difference between High-Level Laser Therapy (HLLT &#; also known as High-Power Laser Therapy or High-Intensity Laser Therapy) and Low-Level Laser Therapy, it is first important to understand their classification by the FDA:

• HLLT devices are classified as &#;Class IV Lasers&#; by the FDA in virtue of having a power output that&#;s greater than 500mW (i.e. high risk of hazard). The vast majority of HLLT devices have longer near-infrared wavelengths.
• LLLT devices are classified as either &#;Class IIIB Lasers&#;, &#;Class IIIR Lasers&#;, or &#;Class II Lasers&#; in virtue of having a power output of 5-500mW, 1-5mW, or <1mW respectively (i.e. lower risk of hazard). The vast majority of LLLT devices have shorter wavelengths.

There is a common misconception, often propagated by the manufacturers of Class 4 Lasers, that high power with longer wavelengths results in:

1. Deeper penetration, allowing for the treatment of a wider range of conditions.
2. More efficacious results, due to the delivery of more energy into the cells.

This however, is not correct for the following well-documented reasons:

1. Laser light with wavelengths exceeding 950nm is highly absorbed by water, preventing much of its energy from penetrating the dermis. This strong absorption can also cause localised heating, leading to discomfort or pain, which may restrict its therapeutic application.
2. There is an optimal &#;dose&#; of laser energy (typically 2-4 joules / cm²) required for therapeutic biostimulation. Deviating from this dose, either by providing significantly less or more energy, can be counterproductive. HLLT devices, with their substantial power outputs, risk surpassing this optimal range.
3. It is theorised that a minimum energy of 1.7eV per photon is required for therapeutic biostimulation via photochemical means &#; wavelengths exceeding 730nm cannot deliver this 1.7eV. As a result, HLLT devices, which often operate within these longer wavelengths, may not primarily function through inducing photochemical reactions. Instead, they might rely on alternative mechanisms, such as the therapeutic influence of localised heat generation. However, this approach may be less efficacious compared to biostimulation by photochemistry.

Low-Level Laser Therapy devices, on the other hand, aim to deliver energy via low output, short wavelength beams of light. The general theory is that this approach transfers the optimal amount of energy for stimulating and enhancing cell function, while not damaging cells or producing painful heat sensations.

Within the LLLT sector however, some of the higher output devices still generate heat / pain. Furthermore, many devices are advertised as &#;lasers&#;, when in fact they are Light Emitting Diodes (LEDs) or Superluminescent Diodes (SLDs). In contrast to LEDs or SLDs, &#;true&#; lasers generate monochromatic, collimated, and coherent beams of light. These three properties of true lasers make them the most effective and efficient devices within the Laser Therapy sector.

To separate Erchonia® from such technologies, and from HLLT more generally, we say that Erchonia® lasers are &#;non-thermal, true lasers&#;. That is, our lasers do not produce any heat or painful sensations, and are monochromatic, collimated, and coherent.

Common FAQs

For more Low Level Laser Therapy For Hyperviscosityinformation, please contact us. We will provide professional answers.