Peter Vitruk, PhD

Peter Vitruk, PhD

By Peter Vitruk, Ph.D. For The Educational Series

Originally posted in Veterinary Practice News, November 2012 – Download as a PDF

The cutting and ablation of soft tissue by CO2 and diode lasers have been extensively studied and reported (Figures 1- 3). This article illustrates the easily observed practical differences between CO2 and diode lasers with respect to their soft tissue cutting and ablation abilities.

Water Absorption Spectrum

Figure 1

Wavelength-dependent laser light’s interaction with water (the dominant component of soft tissue) is the key to understanding how the laser light cuts soft tissue. See Figure 1.

The absorption/ penetration depth in water for the CO2 laser wavelength (10,600 nm) is 0.01 mm, which explains the very thin sub-100 μm thermal damage zone on the margins of the incision in soft tissue (Figure 1). Such short penetration depth enables high precision in removing the tissue, and provides for sufficient hemostasis for sub-0.5 mm diameter blood vessels.

The absorption/penetration depth in water for the diode laser wavelengths in the 800-1,000 nm range is a thousand times greater than for the CO2 laser wavelength. While hemoglobin and melanin do strongly absorb light in the 800-1,000 nm range, their relatively low concentrations in soft tissue result in a widely spread thermal damage zone of up to 8 millimeters (Figures 2 and 3).

Figure 2

Such deep subdermal penetration of diode laser light enables many useful non-surgical applications such as hair removal, spider vein reduction, biostimulation, etc.

CO2 Laser-tissue Interaction

Figures 2 and 3 illustrate the interaction of CO2 laser light at 10,600 nm with fresh poultry muscle tissue. The CO2 laser beam from an Aesculight AE-3020 laser, focused to 0.25 mm spot size (Aesculight Tipless Handpiece) at 7 watt continuous wave in SuperPulse mode, produces a clean incision with char-free (carbon-free with no evidence of burning) margins with minimal thermal damage; see Figure 2.

Figure 3

The same laser with a larger spot size (Aesculight Wide Ablation Tip) at similar average power (6 watt; mode A14 SuperPulse at 20 watt with 30 percent duty cycle) to the tissue produces a 3 mm wide sub-mm deep ablation path—see Figure 3—a useful modality for tumor debulking, scar removal, wound cleaning and a variety of dermatological applications, etc. The CO2 laser-tissue interaction is always predictable and is based on laser beam spot size, and laser beam power.

Diode Laser-tissue Interaction

Figures 4-7 illustrate the use of diode laser at 810 nm with the same tissue sample, the same average laser power (7 watts continuous wave) and similar spot size (0.3 mm) as used for CO2 laser cutting settings presented in Figure 2. Diode laser use in “non-contact” mode is represented in Figure 4A (laser beam on) and Figure 4B (laser beam off); no tissue is removed regardless of exposure time while sub-surface thermal necrosis may extend for up to 8 mm deep (Figure 2).

Figure 4A Figure 4B

Diode laser use in “contact” mode with a fresh and clean distal glass fiber tip firmly pressed against the soft tissue surface is presented in Figure 5A (laser beam on) and Figure 5B (post-lasing). Just as with “non-contact” mode, no tissue is removed regardless of exposure time while sub-surface thermal damage may be very wide spread and extensive (Figure 2).

Figure 5A Figure 5B

The key to soft tissue removal with the diode laser is the carbon-rich black ink or char deposited on the diode laser’s fiber glass tip in order to initiate or activate it—see Figure 6A. The char absorbs the diode laser light and blocks it inside the glass tip. The glass tip then heats up where it can burn the soft tissue upon contact; see Figure 6B.

Figure 6A Figure 6B

Such thermal tissue removal is a slow heat-conduction process that depends on how charred and how hot the glass tip is. Slow tissue removal induced thermal necrosis of up to 6 mm deep (Figure 3) is manifested by extensive char left at the margins of incision, and by white “seared” discoloration outside of the charred margins of incision, seen in Figure 6B. An often overlooked aspect of using a hot charred glass tip for soft tissue removal is the thermal stress induced fracture of the fiber and loss of the broken tip inside the tissue; see Figure 7.

Figure 7


Diode laser light does not ablate soft tissue; it is used indirectly to heat up the optically “black” char on the tip of glass fiber; then the hot charred glass tip cuts the tissue by burning it away upon contact. Excessive char and thermal necrosis along with the possibility of a thermal stress-induced fracture of the glass tip inside the surgical site make the diode laser a “What you don’t see can hurt you” tool for soft tissue surgery.

A diode’s fiber hot glass tip is best used surgically where the use of CO2 lasers is limited (fluid filled surgical site or with flexible endoscopes), while diode laser light has a number of non-surgical applications such as biostimulation, etc.

CO2 laser light’s ability to ablate and cut the waterrich soft-tissue with maximum precision and minimal collateral thermal effects (Figure 1) makes it a true “What you see is what you get” surgical laser with a short learning curve and a great variety of uses in general surgery. The sub-100 μm deep thermal effects on the margins of the incision are sufficient for sealing the blood vessels, lymphatics, and nerve endings, while the 10,600 nm laser light efficiently sterilizes the margins of incision by destroying surface bacteria.


Dr. Vitruk is the founder and CEO of LightScalpel, Aesculight LLC and Luxarcare LLC in Woodinville, Wash., and is a member of The Institute of Physics in London

This Education Series story was underwritten by Aesculight LLC of Woodinville, Wash., manufacturer of the only American-made veterinary surgical CO2 laser


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