Anchored in Science: The most optimal mechanism for laser treatment, providing maximum photonic density without hazardous thermal effect.
Do not confuse the “pulsing” of continuous wave lasers with the super pulsed technology of Multi Radiance lasers. Continuous wave “pulsing” is accomplished literally by "chopping the beam", i.e., mechanically turning the laser on and off. This not only limits the power and depth of penetration offered by continuous wave lasers, it also encourages the body to adapt to its effects, limiting its treatment ability.
With Multi Radiance technology, you can super pulse up to 50,000mW of power which is more than most Class IV lasers, yet with a higher degree of safety. The laser and electronic technologies required to use super pulsed diodes are more advanced and the diodes themselves are more expensive than the continuous wave diodes. This is probably why most lasers in the North American market are low powered Gallium Aluminum Arsenide continuous wave lasers.
Multi Radiance Super Pulsed Lasers use innovative technology to deliver light energy to tissue, which reduces pain and increases circulation.
Cascading Energy Effect™ Multi Radiance Super Pulsed Lasers combine three clinically proven wavelengths to create the Cascading Energy Effect™, allowing for deeper penetration and enhanced absorption of light.
Super Pulsed Laser
The super pulsed laser (905nm) produces high powered light in billionth-of-a-second pulses. The power of each pulse drives the photons deep into the target tissue. Multi Radiance Medical’s technology’s power of up to 50,000mW creates a high photon density, strongly reducing pain and improving micro-circulation.
Pulsed broad band infrared emitting diodes (875nm) penetrate shallower tissue depths than the laser but provide a broader spectrum of coverage.
Pulsed Red Light
Pulsed red light (660nm) penetrates shallower depths.
Pulsed Blue Light
Pulsed Blue Light (465nm) superficial penetration.
Static Magnetic Field
Static magnetic field keeps ionized molecules of tissue in a dissociated state, enhancing the body’s potential to absorb energy.
Electrical stimulation (LaserStim)
LaserStim delivers electrical impulses and light through the skin and tissue, with the help of our exclusive TARGET (Treatment Area Recognition and Guidance Enhanced Technology)
Super pulsed infrared laser (905 nm) GaAS is the essential component of Multi Radiance Medical technology. Multi Radiance Medical super pulsed lasers deliver billionths-of-a-second pulses, combined with up to 50,000 mW of peak power for a higher concentration of light energy, or photons, driven deeper into the target tissue without any risk of overheating.
Super pulsing allows for deeper penetration than a laser of the same wavelength that is not super pulsed but has the same average output power. This is because short pulses allow for quick absorption. In addition, the period between pulses promotes a better environment for optimal pain relief.
Super pulsed infrared laser penetrates deeply into target tissues and exerts powerful stimulating influences upon blood microcirculation. In general, laser diodes are either continuous wave or pulsed. The continuous wave diodes emit laser energy for the entire time they are electrically driven, hence the name. They provide a fixed level of power during emission. Super pulsed diodes emit a series (frequency) of radiation impulses with high amplitude in an extremely short duration (typically 100 to 200 nanoseconds). The mean output of power of a Multi Radiance Medical super pulsed laser will increase as the pulse repetition is increased.
Each impulse of the super pulsed laser produces high peak power delivered for a very brief duration. It is the high power level during each pulse that creates the energy density necessary to deliver adequate doses to the target tissue. Even though the pulse peaks at a high power level, there are no thermal effects in the tissue. Therefore, the peak power of a pulsed laser is high compared to its average output power. By using super pulsed lasers, one is able to more effectively deliver higher densities of light energy into the tissue without the associated deleterious thermal effects.