Lasers (Light Amplification by Stimulated Emission of Radiation) | Figure 6.6 Chromophore absorption spectrum
(Reprint from Teichman O, Herrmann T, Bach T.
Technical aspects of lasers in urology. World Journal
of Urology. June 2007: 25(3); 221–225) |
(Tables 6-23, 6-24, 6-25, 6-26) - Laser light: monochromatic (single, discrete wavelength), spatially coherent (light in phase), collimated (light in parallel fashion)
- Laser treatment based on principle of selective thermolysis: targeted lesion may be destroyed by chromophore absorption of laser light without significant thermal damage to surrounding normal tissue; pulse duration (exposure time) must be equal to or shorter than the target’s thermal relaxation time (TRT, cooling time or time for target to lose 50% heat) to confine thermal damage
- Thermal damage time (TDT): time required to irreversibly damage target with sparing of surrounding tissue; pulse duration ≤ TDT allows for efficacy with ↓ epidermal damage
- Depth of penetration directly proportional to wavelength (i.e., Nd:Yag 1064 nm penetrates deeper than PDL 585 nm); ↑ scattering with decreasing λ (scattering mostly due to collagen)
- Chromophores: components in skin which absorb laser light
- Endogenous: hemoglobin, melanin, water; exogenous: tattoo ink
- Laser characteristics: wavelength, pulse duration, spot size, fluence (J/cm2), power (J/s)
- Gain medium determines wavelength of light: liquid (dye lasers), gas (argon, CO2, helium-neon), solid (Nd:Yag, ruby)
- Pulse duration (exposure time of laser):
- Determines confinement of heat and extent of thermal injury in tissue
- Best if pulse duration ≤ TRT
- Spot size : Larger spot size allows for deeper energy penetration (less scattering)
- Cooling : different types of epidermal cooling to minimize epidermal damage: passive (aqueous gel), active contact cooling (water encased in sapphire or glass housing), dynamic active cooling (cryogen spray), forced air cooling
- Q-switched or “quality-switched”: allows accumulation of excessive energy in laser cavity prior to emission; extremely short pulses of very high power (nanosecond range); used mainly for removal of tattoo pigment and superficial pigmented lesions
- Hair removal:
| | | | | | TRT: proportional to square of target’s diameter (so shortest TRT in chromophore with smallest size) | | | | | |
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- Best when pulse duration ≤ TRT of hair follicle (40–100 ms for terminal hairs) and ≥ TRT of epidermis (3–10 ms) to minimize epidermal damage; thus, optimum pulse duration 10–50 ms; use shorter wavelength laser (ruby) for blond, white, red, and gray hairs since better absorption of melanin
- Pigmented lesions (epidermal pigment):
- Use QS lasers (↓↓ pulse duration): QS KTP, QS ruby, QS Nd:Yag (532 nm)
- Target endpoint: uniform but faint whitening, no epidermal disruption (higher fluences will have solid whitening w/ epidermal disruption and pinpoint bleeding)
- Tattoos:
- QS lasers used to remove tattoo pigment; of note, white/peach/pink/flesh-toned tattoo color may turn dark gray immediately after treatment with QS laser (reduction of ferric oxide to ferrous oxide)
- Amateur tattoo: usually clears after 3–5 treatments with QS laser
- Professional tattoo: may require ten or more treatments (dense pigment)
| | | | | | | Table 6-23 Chromophores | | | Chromophore | | Absorption Peaks | | Laser | | | Hemoglobin | | 418 nm, 542 nm, 577 nm | | Argon, copper vapor, KTP, pulsed dye | | | Melanosome | | 300–1000 nm (peak 335 nm) | | PDL, KTP, ruby, alexandrite, diode, Nd:Yag | | | Water | | 1450 nm, 1950 nm, 3000 nm | | CO2, erbium, diode (1450 nm), Nd:Yag (1320 nm) | | | | | | | | | | | | | | | | | | | | | | | | ↑ Absorption of melanin at lower λ (300–600 nm) but ↑ scattering, ↓ penetration, and competing chromophores (Hgb) occur with lower λ lasers, which is why higher λ used (694+) for hair removal and often for pigmented lesions | | | | | | | | |
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| | | | | | | Table 6-24 Lasers | | | Laser | | Wavelength | | Chromophore | | Comments | | | Excimer (XeCl) | | 308 nm | | Protein | | Psoriasis | | | Argon | | 488 nm, 514 nm | | Melanin, Hgb | | Vascular and pigmented lesions, ↑ risk scarring | | | Pulsed dye
(short wavelength) | | 510 nm | | Melanin | | Pigmented lesions | | | Copper vapor | | 511 nm, 578 nm | | Melanin, Hgb | | Vascular and pigmented lesions | | | KTP
(potassium titanyl phosphate) | | 532 nm | | Melanin, Hgb | | Pigmented and superficial vascular lesions | | | QS Nd:Yag
(frequency doubled) | | 532 nm | | Tattoo pigment | | Superficial pigmented lesions, red/orange/yellow tattoos | | | Pulsed dye (PDL) | | 585–595 nm | | Hgb | | Vascular lesions, hypertrophic scars, verrucae | | | Ruby | | 694 nm | | Melanin | | Hair removal, nevus of Ota | | | QS Ruby | | 694 nm | | Melanin, tattoo pigment | | Superficial pigmented lesions
(i.e., solar lentigo), blue/black/green tattoos | | | Alexandrite | | 755 nm | | Melanin | | Hair removal | | | QS Alexandrite | | 755 nm | | Melanin, tattoo pigment | | Pigmented lesions, blue/black/green tattoos | | | Diode | | 800–810 nm | | Melanin, Hgb | | Hair removal, leg veins | | | Nd:Yag (long-pulsed)
{Concern for retinal damage with Nd:Yag as laser penetrates deep and emits invisible radiation} | | 1064 nm | | Melanin, Hgb | | Hair removal, nonablative dermal remodeling, leg veins | | | QS Nd:Yag | | 1064 nm | | Melanin, tattoo pigment | | Pigmented lesions, blue/black tattoos | | | Nd:Yag (long-pulsed) | | 1320 nm | | Water | | Nonablative remodeling | | | Diode | | 1450 nm | | Water | | Nonablative remodeling | | | Er:Yag | | 2940 nm | | Water | | Ablative remodeling | | | CO2 | | 10,600 nm | | Water | | Ablative resurfacing, actinic cheilitis | | | | | | | | | |
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| | | | | | | Table 6-25 Lasers for Hair Removal | | | Laser | | Wavelength | | Hair Color | | Skin Type | | Comments | | | Ruby | | 694 nm | | Blond, red white, gray, brown | | I, II | | Significant dose-related side effects (epidermal crusting, vesiculation, dyschromia) due to ↑ melanin absorption
(vs. Nd:Yag) | | | Alexandrite | | 755 nm | | Red, gray, brown | | I, II | | Longer λ so ↑ penetration; slightly ↓ risk of epidermal damage than Ruby | | | Diode | | 800–810 nm | | Brown, black | | I, II, III, IV, V | | ↑ Penetration, ↓ epidermal injury | | | Nd:Yag | | 1064 nm | | Brown, black | | II, IV, V | | Deeply penetrating λ, ↓ melanin absorption requires ↑ influence for melanin injury; not as effective as Ruby with lighter hair; safe for darker skin types | | | IPL | | 515–1200 | | Varies based of cutoff filters | | Varies based on cutoff filters | | Nonlaser, noncoherent, multi-wavelength light; filters placed for more selective treatment (shorter λ for lighter skin, longer λ for darker skin) | | | | | | | | | | | |
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| | | | | | | Table 6-26 Lasers for Tattoo Pigment Removal | | | Laser Type | | Wavelength | | Tattoo-Ink Color Treats | | | Pulsed dye (short wavelength) | | 510nm (green light) | | Yellow, red, orange, purple | | | QS Nd:Yag (frequency doubled) | | 532nm (green light) | | Red, orange, yellow | | | QS Ruby | | 694nm (red light) | | Blue, black, green | | | QS Alexandrite | | 755nm (red light) | | Green, blue, black | | | QS Nd:Yag | | 1064nm | | Blue, black | | | | | | | | | | | | | | | | | | | | | | | | Red pigments reflect red light and maximally absorb green light (therefore, ruby/alex is not effective in removing red tattoos); green pigment reflects green light and maximally absorbs red light (so frequency doubled NdYag is not effective) | | | | | | | | |
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