Wavelengths Used in Laser Therapy
Understanding how different wavelengths interact with tissue—and why wavelength selection is one of the most critical factors in laser therapy efficacy.
Wavelength is one of the most important—and often most misunderstood—operating parameters in cold lasers, PBM, and laser therapy. Each wavelength interacts with tissue in a unique way, affecting penetration depth, cellular response, and overall treatment efficacy.
This guide reviews the science behind wavelength selection and helps you understand what different wavelengths actually do in the body.
The Optical (Therapeutic) Window
When light enters tissue, different components of the body absorb it at different rates. There's a "valley" in the absorption spectrum—a range where light can travel the greatest distance through tissue. This is called the optical window or therapeutic window.
The Therapeutic Window: 650nm – 900nm
This range provides the best combination of:
- Depth of penetration (low absorption by water and blood)
- Cellular interaction (triggers photobiomodulation)
- Energy transfer efficiency (photons reach target cells)
The window extends up to about 940nm, but effectiveness drops as you move toward the edges. Most successful therapy lasers operate within this range.
Outside this window, light is quickly absorbed by water (at higher wavelengths) or melanin and hemoglobin (at lower wavelengths)—meaning less energy reaches deep tissue.
Wavelength-by-Wavelength Analysis
Red Light: 600–660nm
Superficial ApplicationsMuch of the energy from red wavelengths interacts with melanin near the surface and hemoglobin in the blood. There's also reaction with mitochondria at the secondary peak of the Cytochrome C Oxidase absorption curve.
Best Applications:
- Superficial issues: scar tissue, burns, cosmetic applications
- Neuropathy (pain sensors are close to the surface)
- Lymphatic system treatment
- Acupuncture and trigger points
- Complex problems where exact treatment location is unknown (energy transfers via bloodstream)
Red light is also useful as a visible guiding light when combined with invisible infrared lasers.
Near Infrared: 760–860nm
Primary Therapeutic RangeThis is the most important wavelength range for photobiomodulation. The peak is around 808/810nm, though manufacturing tolerances mean "810nm" diodes typically range from 800nm to 830nm.
This range is optimized to interact with deep cell mitochondria, triggering increases in Cytochrome C Oxidase and ATP (adenosine triphosphate)—two key chemicals in the photobiomodulation process. About 70% of therapy lasers on the market operate in this range.
Why 808-810nm is the Sweet Spot:
- Best combination of penetration depth and cellular interaction
- Not quickly absorbed by water or hemoglobin
- Peak absorption by Cytochrome C Oxidase
- Numerous studies showing excellent results in tissue regeneration
Super-Pulsed: 905–915nm
Oxygenation & SafetyMost 905/915nm lasers are "super-pulsed"—turned on and off rapidly to keep the diode cool. This wavelength is popular because super-pulsing reduces eye damage risk, making it common in home-use systems.
This wavelength is unique because it interacts primarily with the iron in hemoglobin. When 905nm light hits hemoglobin, it oxygenates the area—and oxygen is critical for tissue recovery. Some conditions get the best results with super-pulsed lasers for this reason.
Key Characteristics:
- Interacts with iron in hemoglobin
- Oxygenates treatment area
- Safer due to super-pulsing (reduced eye damage risk)
- Most common wavelength for home systems
- Often combined with other wavelengths in multi-wavelength systems
High Absorption: 980nm
Pain Control & CirculationAt 980nm, we're outside the optical window and approaching peak interaction with water in the body. While some energy still interacts with tissue like an 800-850nm laser, the bulk creates thermal gradients in water that increase circulation and blood flow.
The 980nm Trade-Off:
Many doctors feel 980nm provides the highest level of pain control. It's popular in high-end pain clinics and has thousands of satisfied users. However, there's a fundamental issue: energy converted to heat cannot be converted to chemical energy—which is the main goal of photobiomodulation.
Our Recommendation:
980nm works well as a secondary wavelength for people who want maximum pain control, circulation, and muscle relaxation—but shouldn't be the only wavelength.
Market reality: The first high-power Class 4 lasers were all 980nm, which became the standard. 980nm diodes are also used in surgical lasers, so high volumes pushed costs down—a high-power 980nm module costs less than half of a comparable 810nm module. 980nm dominates the high-end market partly because it's more profitable for manufacturers, not because it's scientifically superior.
Long Wavelength: 1064nm+
Thermal EffectsLight sources at 1064nm and above are less effective at driving energy deep into tissue and triggering photochemical reactions because they're absorbed near the surface and converted to heat.
This can make them useful for pain control, inflammation control, and increasing blood flow—but as a secondary or tertiary wavelength, rarely as the only wavelength.
Wavelengths to Approach with Caution
UV Range: 200–400nm
Some products integrate UV light for antibacterial/antiviral properties. At lower power levels this can work, but wavelengths below 400nm can disrupt DNA at higher power levels. This range should generally be avoided for therapy applications.
UVB (290-320nm) causes DNA damage. UVA (320-400nm) is less harmful but still problematic. Some interest exists in systems just outside UV range at 405-450nm.
Violet/Blue: 405–450nm
A recent development promoted by some manufacturers. The 405nm wavelength is just above the UV range, holding promise for antibacterial, antifungal, and antiviral properties without UV's downsides. Still an emerging area with limited long-term data.
Pink, Green, Yellow
Some consumer-targeted products from fringe manufacturers include these wavelengths. We haven't found substantial science behind their use for cellular therapy. None of the established, successful laser manufacturers use these wavelengths because there's little scientific justification.
Companies using exotic wavelengths often also make exaggerated claims about their products. These wavelengths might someday prove useful, but right now they're mostly marketing differentiation.
Is There One "Magic" Wavelength?
Some manufacturers claim one specific wavelength is superior and similar wavelengths are less effective. The reality is more nuanced:
Manufacturing Reality
Laser diode specifications show that an "810nm" diode can actually range from 800nm to 830nm based on chemical composition. It's questionable to claim any single wavelength is significantly better when both are within standard manufacturing tolerances.
Temperature Effects
Output wavelength changes with diode temperature—typically 0.3nm per °C. The wavelength when you first turn on a system (20°C) will be 3-10 nanometers less than at full operating temperature (up to 40°C). Any manufacturer claiming a single wavelength is definitively superior is probably over-marketing.
The Consensus
There's no general agreement on an exact optimal wavelength beyond "somewhere in the 780nm to 830nm range." For some conditions, lower wavelengths work best; for others, higher wavelengths. Having a system capable of multiple wavelengths provides the most flexibility.
Multiple Wavelengths: Simultaneous vs. Sequential
Should you treat with one wavelength at a time or multiple bands simultaneously? Manufacturers disagree on this point.
Simultaneous (Shotgun Approach)
Multi-wavelength systems fire all wavelengths at once, interacting with many different cell types in many different ways. This produces varied effects without the operator needing to configure each wavelength separately.
Best for: Practitioners who won't take time to optimize dosage for each wavelength. You might only get 1% of the desired dosage at a specific wavelength, but that's better than nothing.
Sequential (Precision Approach)
Single-wavelength-at-a-time systems let you control dosage for each wavelength independently, achieving appropriate energy levels for each.
Best for: Practitioners who care about precise dosage and want optimal results. Requires more time and training to determine proper dosage for each wavelength.
In theory, treating each area with optimum dosage per wavelength is better if you have time and training. In practice, combining wavelengths simplifies protocols, reduces treatment time, and ensures patients get at least some energy at the wavelength that might have the biggest impact.
Key Takeaways
800-860nm (especially 808-810nm) is the primary therapeutic range for deep tissue work—not quickly absorbed by hemoglobin or water, optimal for photobiomodulation.
600-660nm (red) is best for superficial applications, neuropathy, lymphatic system, acupuncture points, and trigger points.
905-915nm (super-pulsed) interacts with hemoglobin to oxygenate tissue. Safest option for home use due to pulsing.
980nm provides excellent pain control and circulation but converts much energy to heat. Best as a secondary wavelength, not primary.
Multiple wavelengths provide flexibility—each can excite cells differently, giving practitioners several mechanisms to address the same problem.
Avoid exotic wavelengths (pink, green, yellow, UV) without scientific justification—they're mostly marketing differentiation.
In addition to wavelength, other equally important factors include power level, dosage accuracy, protocol range, and treatment area size. All quality lasers on the market have unique value propositions—the key is matching the right wavelength(s) to your specific applications.
Need help choosing the right wavelength?
We'll help you match wavelength capabilities to your specific treatment needs—whether you need deep tissue penetration, superficial applications, or multi-wavelength flexibility.