Objective monitoring of laser tattoo removal in human volunteers using an innovative optical technique: A proof of principle.

OBJECTIVES: Assess the suitability of the technique for objective monitoring of laser tattoo removal by an extended treatment protocol. MATERIALS AND METHODS: One half of the tattoo in the first volunteer was treated with nanosecond and the other half with picosecond laser pulses at 1064 nm. In the second subject, four test areas were treated repeatedly using different radiant exposures from 1.5 to 6 J/cm2 . Measurements of diffuse reflectance spectra and photothermal radiometric transients were performed 4-20 weeks after each treatment session. Inverse Monte Carlo analysis based on a three-layer model of tattooed skin was applied to assess the tattoo characteristics and analyze their changes. RESULTS: The results clearly indicate a gradual reduction of the ink content and an increase of the subsurface depth of the tattoo layer with all treatments at a radiant exposure of 3 J/cm2 or higher. The observed dependences on laser pulse duration, radiant exposure, and a number of treatments are in excellent agreement with visual fading of the tattoo. CONCLUSIONS: The presented methodology enables noninvasive characterization of tattoos in human skin and objective monitoring of the laser removal treatment.

Comprehensive examination of tattoo removal using a 150 ps Nd:YAG laser in a porcine model.

This study aimed to investigate the efficacy of a Nd:YAG laser with a pulse duration of 150 ps at different laser parameters. The effects on multiple-colored tattoos with such ultrashort pulses has not been previously described in the literature. In vivo experiments were conducted on porcine skin to analyze the fragmentation efficiency of five different tattoo colors using different wavelengths, pulse energies, and spot sizes. The results showed that the optimal tattoo clearance to safety ratio for blue, green, red, and yellow tattoos with a 532 nm wavelength was 0.96-2.39 J/cm2. The laser with a wavelength of 1064 nm demonstrated the highest efficacy in eliminating black tattoos, with positive results observed for green and blue pigments at a fluence of 3.02 J/cm2. The study provides valuable insights into the efficacy of laser treatment with 150 ps for removing tattoos of different colors using different laser parameters. This information can help dermatologists and practitioners perform more efficient and effective tattoo removal with fewer side effects.

Non-laser treatment for tattoo removal.

Tattoos are increasingly gathering attention in the young population, especially in second to fourth decade of life. With such trends, rate of its removal also has been on the rise. Treatment options for tattoo removal besides lasers are surgery, radiofrequency, infrared light, cryotherapy, dermabrasion and salabrasion. Unfortunately, none of these procedures are associated with satisfactory cosmetic results due to adverse effects such as scarring and dyspigmentation. Although laser treatment has become the gold standard for tattoo removal, it is also associated with some limitations. Some tattoo inks are resistant to laser, and multiple sessions and multiple wavelengths may be required for its complete removal. Considering these limitations, other treatment modalities for tattoo removal must be explored. This article highlights the non-laser treatment options for tattoo removal. We reviewed all published literature identified from electronic databases (MEDLINE and PubMed) till August 2021 to highlight the non-laser treatment options for tattoo removal.

A Practical Approach to Cosmetic Tattoo Removal with the Nd:YAG Laser.

The Q-switched neodymium-yttrium aluminium garnet (Nd:YAG) laser remains the gold standard method for tattoo removal including cosmetic tattoos. Modern picosecond lasers are referenced to the Nd:YAG laser and essentially do the same job. Persons with cosmetic tattoos in the face are especially eager to achieve perfect removal or correction and from start are critical to suboptimal results. Customers mostly request complete removal; sometimes the goal is fast treatment and bleaching to prepare for a cover up tattoo. Removal or correction of eyebrows is the largest group, followed by lip tattoos and eyeliners. The article gives a systematic and stepwise introduction to routine cosmetic tattoo removal by laser in an Austrian private medical practice. Rationales and selection of customers who can benefit from treatment, preparation, performance, and aftercare is reviewed. Emphasis is given to qualified power adjustment of the laser equipment and the treatment strategy, e.g. the delicate navigation between efficient removal and the risk of short-term and long-term adverse effects. Treatment relies on a partnership between provider and customer. Over the months of treatment, customers gain more insight into the possibilities of treatment, so that they get an understanding of the realistic results that can be achieved. Therefore, customers are also satisfied even with results that are not always optimal since best treatment was given a fair chance.

High-Frequency (20 MHz) Focused Ultrasound: A Novel Method for Noninvasive Tattoo Removal.

Alternatives or complements to laser tattoo removal are needed. Laser removal requires 8-12 sessions and can easily take longer than a year. Some colors cannot be removed, and scars may appear. Applied to allergic reactions in red tattoos, lasers can boost the allergy. A recently developed 20 MHz high-intensity focused ultrasound (HIFU) is introduced as a complementary method to lasers, but also as a stand-alone treatment for selected groups. 20 MHz HIFU allows for application of high-power ultrasound energy to very small focal targets in the dermis, and thereby precise confinement of thermal lesions in the outer layers of human skin, precisely where tattoo inks are deposited. HIFU treatment is "color blind" and can target any type of colored pigment in the dermis. It produces a controlled thermal lesion (up to 65°C) with superficial necrosis followed by an eschar with embedded tattoo pigment. This eschar, containing the tattoo pigment, is discharged over some weeks, and finally replaced by healed skin. HIFU can efficiently remove tattoos of any color in only 1-3 sessions. It can be applied to tattoos when lasers fail to produce efficient removal. The types of side effects are the same as with lasers. The operator shall be trained and knowledgeable. 20 MHz HIFU can furthermore be used in clinical and esthetic dermatology for various other applications, and a range of applications are open in clinical dermatology.