RU2692936C1 - Skin tattoo removal method - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to medicine, namely to cosmetology and dermatology, and can be used for tattoo removal on skin. Fractured action is performed on skin surface with tattoo of Nd:YAG Q-switch laser with energy density of 5.5 J/cm², generation frequency of laser flashes of 1 Hz with laser beam spot diameter of 4–5 mm. Laser exposure to the skin is staggered in two stages: at the first stage, with mandatory observance of the distance between the laser beam exposure areas equal to the treated regions diameter, then, at second stage, laser sections in the same mode are exposed to tattoos untreated at the first session in 48 hours. Repeated treatment of tattoo is repeated not earlier than two months later.

EFFECT: method provides prevention of skin burns, reduced time of tattoo removal due to skin exposure to laser with high energy density on skin areas in staggered order.

1 cl, 2 dwg, 2 ex

Description

The invention relates to laser medicine, namely to cosmetology and dermatology and can be used when removing tattoos.

For cosmetic or various other reasons, people often want to remove a tattoo from their skin. However, since the pigment is an integral part of the cells in the dermis layer, the removal of pigmentation is a difficult task and can only be effectively carried out by destroying and replacing the cells containing the pigments. Known tattoo removal methods include:

- dermabrasion, in which the skin is “cleaned with an abrasive material” (i.e., polished) to remove skin layers containing pigmentation,

- cryosurgery, in which the pigmented area is frozen before it is removed,

- Excision, in which the dermatologist surgeon removes the pigmented skin with a scalpel and covers the wound, stitching. In some cases, it may be necessary to transplant skin from another part of the body to treat large areas of the skin.

Modern methods of getting rid of tattoos are quite traumatic and painful, besides many of the existing methods today have significant side effects, such as incomplete excretion, hyperpigmentation, severe scarring, keloidosis, intolerance to painkillers, the addition of infection and others [Shafranov V .V., Denisov Yu.I., Doctors A.A. et al. Patterns of damage to biological tissues during hardware cryodestruction. Pediatric Surgery 2003; 3: 24-25.].

In other methods of tattoo removal, lasers are used. The use of lasers offers a more accurate and generally less traumatic alternative to the above methods. Each procedure is performed as a single treatment or a sequence of treatments. In the known methods, laser radiation affects not only the colored and affected areas of the skin, but also the surrounding tissues. Wound healing after such an operation lasts for seven weeks, and scars remain on the skin [International J.LLLT and Photobioactivation 1991, vol. 3 N 1, p. 97.].

Today, the most optimal method is the laser destruction of tattoos that selectively fragment dye particles, which are then removed by the body's immune system, followed by their elimination through phagocytosis [Mordon S. On the development of aesthetic laser medicine / KOSMETIK international. 2013. №1. - p. 50-55.]. The main lasers used to remove tattoos are neodymium, neodymium with double frequency, alexandrite and ruby, operating in the Q-switched mode - with a Q-switched modulator [Laser and Light Therapy / ed. David J. Goldberg / Trans. from English Ed. V.A. Vissarionov. M .: Reed Elsiver, 2010. T. 1. 187 p.].

The most common of them received, the "workhorse" of laser tattoo removal, Nd: YAG Q-switched KTP or solid-state neodymium laser with a Q-switch. As the active medium in this laser, yttrium-aluminum garnet (“YAG”, Y3Al5O12) doped with neodymium ions (Nd) is used. The crystal emits a laser beam at a wavelength of 1064 nm. The KTP attachment is a nonlinear optical system made of a potassium titanyl phosphate crystal (KTiOPO4, KTP). In it, the initial radiation frequency is doubled and the output beam has a wavelength of 532 nm, which corresponds to the green color of the visible emission spectrum.

In addition, there are side effects associated with laser procedures, including an accidental burn, scarring, hyperpigmentation (darkening of the skin color at the treatment site) and insufficient pigmentation (lack of normal skin color at the treatment site). Since Nd: YAG Q-switch lasers have only wavelengths of 1064 nm and 532 nm, that is, there is a limitation on working with certain colors of pigments. A wavelength of 1064 nm works perfectly with black, and 532 nm with red. Green, blue, yellow colors very weakly absorb these wavelengths and are not destroyed by Nd: YAG Q-switch lasers. To work with these colors, it is necessary to use alternative wavelengths of alexandrite Q-switch laser or special nozzles on dyes that generate additional wavelengths with a neodymium laser 585 nm, 595 nm, 650 nm. Nozzles on dyes require high-power equipment, have a small resource of work (8000-12000 flashes) and a rather high cost at the moment.

There is a method of therapeutic effects on pigment tumors and tattoos by applying pulsed laser radiation to biological tissues, characterized in that the radiation is supplied as a packet of successive giant laser pulses with energies of 1 1000 mJ and a pulse duration of 1100 ns, and the duration of the supplied packet is not more than 300 MS, and a packet of giant laser pulses form at least two consecutive pulses (RF patent №2096052, 11.20.1997).

As a disadvantage of this method, it is possible to indicate the absence in Russia of certified laser devices with similar characteristics, the very high cost of such equipment is also obvious.

There is a method of selective photocavitation, which consists in heating the pigment granules only in the area affected by the laser beam without disturbing the skin. Selective photocavitation can be carried out by light with a wavelength of 600-1100 nm. This radiation penetrates deep enough into the skin and is well absorbed by pigment particles with weak absorption by hemoglobin and water. Therefore, light with such a wavelength can perform selective heating and photothermolysis of pigment particles. The most common light sources operating in this range are ruby (694 nm), alexandrite (755 nm), diode (800-940 nm) and Nd: YAG (1064 nm) lasers (Ferguson JE, Andrew SM, Jones CJ, August PJ: The Qswitched Nd: YAG lasers and tattoos: Amicroscopic analysis of laser tattoo interactions. J Dermatol. 137: 405-410 (1997)).

The disadvantages of this technical solution are that the operator during the procedure of tattoo removal does not examine the physical characteristics of the pigment, and the technical conditions of the laser are chosen empirically. In this regard, the effectiveness of the procedure can be assessed and adjusted technical conditions of removal only after 40-50 days, more and more sessions are required. The effectiveness of the procedure is extremely low.

There is a method of removing skin defects in the form of tattoos and scars, which consists in burning out the defective parts of the epidermal layer by exposing them to a source of highly concentrated energy, characterized in that the effects are performed by an alternating electric field with the occurrence of RF discharges between the epidermal layer and the needle electrode , wherein the epidermal layer is carried burning portions, not larger than 2 cm ^2, distributed over the defect area without exposing treated skin IU dy remote sites, burn after healing is repeated in this manner the remaining portions of the defect, these steps are repeated until complete burnout of the defect on the entire area (patent RF№2366469, 10.09.2009).

Its disadvantages: without the formation of scars in this way you can only remove the superficial pigment. In the event that the pigment is implanted in the germ zone of the epithelium, the result is very little different from dermatobraion and chemical peeling and is significantly inferior to laser tattoo removal methods.

A known method of removing tattoos on the skin, including exposure to the surgical area of the skin with a laser, characterized in that they preliminarily take samples of skin biopsy tissue with particles of an implanted tattoo pigment, which determine the depth of the tattoo pigment in the skin tissue and establish the most effective wavelength of laser irradiation by processing samples of skin tissue with a laser with different wavelengths, after which the samples are stained and identify those that have occurred the most severe destruction of the tattoo pigment, and when establishing the depth of the tattoo pigment not higher than 0.7 mm, proceed to laser removal of the tattoo pigment, and when establishing the depth of the tattoo pigment from 0.7 mm to 2.0 mm, first carry out surface destruction, then produce laser removal of the tattoo pigment, while removing the exercise the most effective wavelength of the laser, installed on samples of biopsy tissue (RF patent №2550012, 05.05.2015).

Its disadvantages: the complexity and the need for complex additional research. After all, according to the method, before the procedure of tattoo removal, samples of biopsy tissue with particles of implanted tattoo pigment are taken. These samples determine the color, type of paint, the depth of the tattoo pigment in the skin tissue.

In our opinion, the closest to the claimed technical solution is a method of laser tattooing by laser nanoperforation, which is implemented by the impact of an Er: YAG laser with a wavelength of 2936 nm, which has a specialized nozzle, which creates a special ablation profile - spatial-modulated ablation (SMA - Space Modulated Ablation). It is a construction of lenses and designed to redistribute the energy of the laser beam in space.

The disadvantages of this technical solution are: continuous monitoring of the relevant parameters on the laser equipment.

This requires a laser of a certain wavelength and irradiation regime. Deviation from the specified parameters will not allow to carry out the stated result, in particular, to remove the tattoo in the shortest possible time. In addition, as a disadvantage of this removal method, you can specify a very high cost of equipment used in a particular removal method.

The present invention is to expand the Arsenal of methods for removing tattoos with a reduced likelihood of destruction of adjacent biological tissues and with a reduced duration of treatment.

This problem is solved due to the fact that we have developed a method for removing tattoos on the skin, including laser exposure to the surgical site, characterized in that they carry out a fractional impact on the skin surface with a Nd: YAGQ-switch laser with an energy density of 5.5 J / cm ^2, the oscillation frequency of 1 Hz laser flashes in two stages: first, the laser beam spot diameter in the range of 4 to 5 mm with obligatory observance of the distance between the areas of impact of the laser beam on the skin equal to the diameter of the treated astey, ie from 4 to 5 mm, then in the second stage, after 48 hours, the laser is applied with a spot diameter of the laser beam ranging from 4 to 5 mm to the tattoo areas that were not processed in the first session.

Thus, the entire tattoo is treated with separate flashes of the laser without re-overlapping the treatment areas, i.e. staggered. In this case, tattooing with a laser is performed in stages, with a break after the first stage of treatment - 48 hours, and in the second session (after 48 hours), the tattoo areas not processed in the first session are affected. The following procedure for tattoo removal on the skin should be no earlier than 2 months. In this case, laser tattoo processing is also performed in stages, with a break after the first stage of treatment - 48 hours, and in the second session (after 48 hours), the effects on the tattoo sites that were not processed during the first session.

The technical result of the claimed invention is to increase the efficiency of tattoo removal, by eliminating unnecessary thermal effects on the patient's skin, reducing the likelihood of destruction of surrounding tissues and reducing the total duration of treatment.

The removal of permanent make-up and tattoos of Nd: YAG Q-switch lasers today is the recognized “gold standard” [Sardana K., 2014].

The first principle that explains the action of a laser is the theory of selective photothermolysis, published in the journal Science, 1983 [R.R. Anderson, and J.A. Parrish, 1983]. The concept of selective photothermolysis formed the basis of virtually all optical devices used in cosmetology at the moment, such as photoepilation, laser hair removal, laser removal of blood vessels and, in particular, laser removal of permanent makeup and tattoos Nd: YAG Q-switch lasers.

The essence of the theory is that the effect of radiation exposure to energy of a certain wavelength will be only on those chromophores that absorb this wavelength, i.e. for each chromophore (granules of artificial pigment, red blood cells, hair follicles) there is an optimal wavelength, which it absorbs as much as possible and, therefore, the effect will be most pronounced. This explains that with the correct tattoo removal procedure, the side effects are minimal and only the artificial pigment in the skin is destroyed.

After the appearance of photoepilators, there were attempts to use them to remove tattoos and permanent makeup, it would seem that the skin pigment had to absorb the flash and collapse, but as a result it did not occur, and after exposure, burns and scars appeared on the skin, and the artificial pigment of the tattoo did not disappear . This result was caused by a cause that was not taken into account, and this is the second principle of the concept of selective photothermolysis, which is used in laser depigmentation of the dermis at the moment [Karsai S, Raulin S, 2011]. The concept of thermal relaxation time (Thermalrelaxationtime, TRT) explained the problem of burns when trying to remove a tattoo with photoepilators and lasers with a long-pulse mode of operation. It is necessary to take into account the linear size of the particles that are exposed to the light pulse and the duration of this flash (duration of exposure). Thermal relaxation time is the time that an object needs to give half of the energy it absorbs as heat to the environment or tissues, and time is proportional to the square of the particle size. Those. the smaller the linear dimensions of the particle, the faster it gives thermal energy to the surrounding tissues and the peak temperature is not reached to destroy the pigment particles, and overheating and thermal injury of the surrounding tissues occurs. Only after the laser flash duration was reduced to nanoseconds (1 × 10 ^-9 or billions of a second), was it possible to safely and effectively remove tattoo pigments from the skin. Such short flashes of 3-5 nanoseconds became possible after the creation of a Q-switch Q-switch in 1992, which allows generating ultrashort pulses. In order to imagine how short this flash can be, use such a comparison: if 1 nanosecond is taken in 1 second, then 1 second will become equal to 32 years.

Nd: YAG Q-switch lasers operate using ultrashort nanosecond flares, and this achieves an enormous peak radiation power. This flash energy is selectively absorbed by the tattoo pigment granules in the skin and, due to the fact that the thermal relaxation time of the pigment granules is much longer than the flash duration, the temperature of the pigment granules increases to several thousand degrees and turns into a shock “blast” wave [But DD, London R., 2002]. Shock "explosive" wave propagates in the dermis and causes damage to the pigment granules into small fragments, and also leads to damage to cellular structures and rupture of cell membranes. The rapid heating of melanosomes (organelles containing natural granules of the skin pigment) transforms the intercellular and intracellular fluid into steam and leads to the formation of intracytoplasmic vacuoles (bubbles with vapor inside the cells). It is through these mechanisms that a sudden change in skin color occurs at the site of laser exposure — skin whitening or “frost” is the instantaneous vacuolization reaction, which is explained by the formation of a “gas-collagen shield”. The gases dissolved in the tissues under the action of the colossal splash of energy form vacuoles inside the cells and in the extracellular space. The formation of such vacuoles in a large number and volume is a reflection of excess exposure and leads to visible macro changes of the skin surface - an increase in skin volume by 5-10 minutes. Such deformation can lead to additional damage to the skin by overpressure. Next, tissue macrophages absorb the crushed fragments of artificial pigment and remove them from the skin through the lymphatic pathways.

The size of the working spot of the laser - the energy released by Nd: YAG Q-switch lasers per flash is limited, as with all lasers. The area of the laser's working spot on the skin determines the clinical significance of the impact. Nd: YAG Q-switched lasers do not have a fixed size of the working spot, which can be from tenths of a millimeter to 7-10 mm in diameter (that is, can differ by more than 100 times) and depends on the focal length of the lens from the skin surface [Bernstein EF, Civiok JM., 2014]. Exposure to a large working spot diameter will not allow excessive injury and will be more effective in penetrating tissue with sufficient laser power, so we developed a technique using a 3-4 mm spot size and high energy density. In the first session, we use the diameter of the working spot of the skin 4-5 mm and an energy density of 5.5 J / cm ² . In the second treatment, after 48 hours on the remaining part of the tattoo, which was not processed in the first session, we use the same parameters, namely: 4-5 mm diameter of the working spot of the tattoo and energy density 5.5 J / cm ² .

An important point of our technique is that the laser beam is applied at intervals between the exposure areas corresponding to the diameter of the treated areas, so that the entire tattoo is treated with separate laser flashes without re-overlapping the treatment areas, while the laser tattoo processing is performed in 2 stages with a break between in stages of 48 hours, and in the second session the effects on the areas of the tattoo not treated in the first session are carried out. If necessary, after another 48 hours, the tattoo areas not treated in the first and second sessions are exposed. This technique reduced the overall duration of the course of laser therapy by reducing the required number of procedures and the interval between them, preventing the problem of "frozen" tattoos and facilitating the removal of the dye in tattoos complicated by cicatricial deformation [Laser selective destruction of the dye in combination with spatial-modulated ablation to remove tattoos laser nanoperforation method. Kalashnikova N.G., Zakharov D.Yu. // Bulletin of Aesthetic Medicine Volume: 12 Number: 3 Year: 2013 S .: 62-71].

This mode of delivery of laser radiation allows you to combine the effectiveness of the procedure with its safety for the patient [Khomchenko V.V. The use of high-energy lasers in cosmetology // Bulletin aesthetic. medicine. - 2010. V. 9, №2. Pp. 6-11.]

Thus, there is a limited impact in one session of no more than 50% of the tattoo area by partial treatment with separate spots corresponding to the radius of the laser beam with intervals of untreated skin with a tattoo between the treated areas. The distance between the treatment spots correspond to the radius of the treatment spots.

According to our observations, this method avoids the complications associated with the use of high energy density by the standard treatment technique with full processing in one session and overlapping laser spots on the skin surface with passes of 15-30%. In this case, several positive results are achieved at once:

1. In case of mechanical damage from an accidental external impact, only 1-3 small holes are damaged, and not the entire area, if the tattoos are removed in large sections.

2. In the event of infection during postoperative care, one or several remote small areas are driven, and not the entire area of one site as if removed by large areas.

3. The areas of untreated skin between the distant areas give elasticity to the whole structure, while removing large tattoos may result in the formation of one continuous skin, which can burst the patient’s subcutaneous muscles under tension, a feeling of contraction that is extremely uncomfortable for the patient is observed skin, limitation of mobility in the place of removal.

4. The healing processes of small remote areas go much faster than when removing skin with a tattoo with a single large area.

5. The "side" heat released in the tissues, the accompanying destruction of the pigment is successfully distributed to the tissues that have not been processed and as a result of the measures for cooling the tissues by contact method (cold packs) and airflow during the procedure (Zimmer Crio 6 cryotherapy unit, Germany Zimmer MedizinSysteme Gmbh) with an air flow of 1000 l / min with a temperature of -20 ° C), it allows to avoid burn complications.

6. The advantages of using higher energy densities are obvious - they allow for a single exposure to destroy a larger volume of particles of artificial tattoo pigment compared to the standard recommended energy density parameters and do it with greater safety, which can reduce the total time required to remove tattoos and tattoo 30-50% compared to traditional methods and at the same time preserve the safety of the procedure and the absence of injury as mechanical at the time of the procedure, k and thermal as a result of overheating of tissues.

Detailed description of the method and examples of its specific implementation

The tattoo removal procedure is carried out using the Nd: YAG Q-switch laser: the Magic One Odin compact compact laser complex (complete set 2.6, manufactured by OOO MeLSiTek, Russia).

The patient is pre-cooled by the cryotherapy unit Zimmer Crio 6, Germany Zimmer MedizinSysteme Gmbh) with an air flow of 1000 l / min with a temperature of -20 ° C) after treatment of the surgical field with an antiseptic solution.

In the mode of single flashes with a frequency of 1 Hz in the first session we use the working spot diameter of the skin 4-5 mm and the energy density 5.5 J / cm ² with the condition of the mandatory distance between the areas of the laser beam on the skin from 4 to 5 mm. Thus, the entire tattoo is treated with separate flashes of the laser without re-overlapping the treatment areas - the laser effect on the skin occurs in a checkerboard pattern. In this case, laser tattoo treatment is performed in stages, with a break after the first stage of treatment - 48 hours, and in the second session (after 48 hours), the tattoo areas not processed in the first session are affected, we also use the working spot diameter of the skin 4-5 mm and energy density of 5.5 J / cm ² with the condition of the mandatory distance between the areas of exposure of the laser beam on the skin, from 4 to 5 mm.

The following procedure for tattoo removal on the skin in the same way should be no earlier than 2 months. In this case, laser tattoo processing is also performed in stages, with a break after the first stage of treatment - 48 hours, and in the second session (after 48 hours), the effects on the tattoo sites that were not processed during the first session.

The efficiency of the proposed method is confirmed by the following clinical examples:

Example. 1. Patient S., 32 years old. Fragment tattoo size 2 cm ² , with the words made 7 years ago in an artisanal way. Earlier attempts to remove the tattoo was not. The exposure area was cooled with a Cryotherapeutic Zimmer Crio 6 apparatus manufactured by Germany (Zimmer MedizinSysteme Gmbh) with an air flow of 1000 l / min with a temperature of -20 ° C) after treating the surgical field with an antiseptic solution.

The patient underwent two procedures for removing a fragment of the claimed method. After the first treatment, after 48 hours, another procedure immediately took about 50% of the fragment color, then two months after the first procedure, the second procedure was performed, and 4 months after the first procedure, the third procedure was performed, the tattoo disappeared by 90%. Tattoo removal by the described method was not accompanied by side effects in the patient (scars, pigment changes, etc.). An example is illustrated in FIG. 1, where A - before tattoo removal, B - after removal.

Example 2. Patient And-ova, 34 years. The shoulder tattoo was made over 10 years ago by professional dyes in a tattoo parlor. Obviously, the removal of the tattoo by the standard method is not advisable. The exposure area was cooled with a Cryotherapeutic Zimmer Crio 6 apparatus manufactured by Germany (Zimmer MedizinSysteme Gmbh) with an air flow of 1000 l / min with a temperature of -20 ° C) after treating the surgical field with an antiseptic solution.

The patient underwent two procedures for removing a fragment of the claimed method. After the first treatment, after 48 hours, another procedure was performed immediately; approximately 50% of the fragment color was taken away. Later, two months after the first procedure, the second procedure was performed, and another 2 months after the second procedure, the third procedure was carried out, the pigment was destroyed by 92%. Removal of the tattoo was not accompanied by side effects (scars, pigment changes, etc.). An example is illustrated in FIG. 2, where A is before tattoo removal, B is after laser treatment. In the photo of FIG. 2-B shows that the tattoo was divided into two parts for a split test, one part was processed in the conventional way (marked with number 2 in the photo), the second part was processed with the claimed method (marked with number 1 in the photo).

We have conducted 48 experiments to remove patients tattoos of varying age and complexity. In 92% of cases, extremely cosmetic results were obtained - the tattoo disappeared completely. In 8% of cases there was a slight discoloration of the treated tattoo.

Thus, these examples convincingly demonstrate that the use of the proposed method allows to achieve effective removal of tattoos of various nature without damaging the underlying or near-lying tissues and reduce the total duration of treatment.

Claims (1)

The method of removing tattoos on the skin, including laser exposure to the surgical site of the skin, characterized in that they carry out a fractional effect on the skin surface with a Nd: YAG laser tattoo. Q-switch energy density 5.5 J / cm ² , the frequency of generation of laser flashes 1 Hz with the spot diameter of the laser beam is 4-5 mm, while the laser exposure to the skin is carried out in a staggered manner in two stages: in the first stage, the distance between the areas of laser beam exposure on the skin is always equal to the diameter of otannyh areas, then the second step is carried out after 48 hours of exposure to the laser in the same mode at the tattoo portions not processed on the first session, reprocess tattoo repeated no sooner than two months.

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