RU2430757C1 - Method for elimination of pathogenic and opportunistic microorganisms - Google Patents

Abstract

FIELD: medicine. ^ SUBSTANCE: invention refers to medicine, namely to - physiotherapy. A method involves simultaneous processing of an area containing microorganisms by a photosensitiser and photocatalyst composition. Thereafter they are kept for a period of time required for effective binding of the composition and microorganism cells. Then this area is exposed to optical radiation at wave length related to a maximal photosensitiser and photocatalyst absorption and power density required for composition activation. The photosensitiser is indocyanine green. The photocatalyst is titanium dioxide nanoparticles. ^ EFFECT: method provides more effective inactivation of pathogenic and opportunistic microorganisms ensured by higher microorganism radiosensitivity. ^ 8 cl, 5 dwg

Description

The invention relates to medicine, namely to dermatology, dentistry and physiotherapy, in particular to the use of photodynamic therapy for the selective destruction of pathogenic and conditionally pathogenic microorganisms (bacteria and fungal organisms).

Numerous clinical trials convincingly indicate that infrared low-intensity laser radiation (IR LLLT) can be effectively used for the prevention and treatment of traumatic injuries, vascular disorders, systemic and functional disorders, as well as degenerative-dystrophic diseases (Avruckii M.Ya., Katkovsky D .G., Musikhin L.V., Guseinov T.Yu. Effect of low-intensity laser radiation on the basic biological processes and homeostasis of patients. // Anesthesiology and intensive care. - 1991. - No. 5. - P. 7. 4-79; Smooth SP., Alekseev Yu.V., Istomin SP Trigger molecular mechanisms for the formation of biological effects in low-energy laser therapy. // Use of lasers for the diagnosis and treatment of diseases. - M.: LAS Publishing House, 1996 . - S.7-11).

The use of IR LILI is effective in the treatment of various acute and chronic infectious diseases, as well as in purulent-septic and purulent-inflammatory complications (Zakrevsky G.I., Vasilevich N.M. Laser therapy for purulent-inflammatory diseases in children. // Clin. Surgery . - 1980. - No. 6. - P.61-62; Karu T. Photobiological fundamentals of low-power laser therapy. // Laser Health: abstr. Of the 1-st international congress. - Limawssol, 1997. - P. 207-210).

The therapeutic effect of IR LILI is associated with its photoactivating and normalizing (in therapeutic doses) effect on the activity of the most important enzymes of metabolism, biosynthesis of proteins, DNA, RNA, cell proliferation, tissue regeneration, the activity of the immune system and the blood and lymph microcirculation system (Hawkins DH, Abrahamse H The role of laser influence in cell viability, proliferation, and membrane integrity of wounded human skin fibroblasts following helium-neon laser irradiation. // Lasers in Surgery and Medicine. - 2006. - V.38, No. 1. - P.74 -83.).

For laser therapy, infrared (λ = 800-1200 nm) laser radiation, generated in continuous or pulsed modes, is most often used, and a particularly pronounced therapeutic effect is observed when using wavelengths of 800-890 nm.

The photobiological processes caused by IR LLLT are quite diverse and specific. They are based on the photophysical and photochemical reactions that occur in the body when exposed to laser light. Photophysical reactions are mainly due to the heating of the object to various degrees and the spread of heat in biological tissues. The temperature difference is more pronounced on biological membranes, which leads to the outflow of Na ⁺ and K ⁺ ions, the opening of protein channels and an increase in the transport of molecules and ions. Photochemical reactions are caused by the excitation of electrons in the atoms of a light-absorbing substance. At the molecular level, this is expressed in the form of photoionization of a substance, its reduction or photooxidation, photodissociation of molecules, and in their rearrangement - photoisomerization. In this state, biomolecular complexes acquire high reactivity, which allows them to actively participate in various processes of cellular metabolism (Karu T.Y. Primary and secondary cellular mechanisms of laser therapy. // Low-intensity laser therapy. / Ed. By S.V. Moskvin and V.A.Buylina. - M .: Technika Firm LLP, 2000. - P.71-94; G. Bril. Molecular aspects of the biological effect of low-intensity laser radiation. Actual problems of pathology. Saratov, from Saratov University, 2001 .-- S.124-136).

In RF patent No. 2376045, IPC A61N 5/067, a method is described when a multiple session transcutaneous effect of low-intensity infrared laser radiation of gallium arsenide with a frequency of 600 Hz is performed on the chest in the area of the inflammatory infiltrate with constant movement of the emitter along the intercostal spaces within the zone.

This method does not take into account the features of the inflammatory process, sensitivity to the effects of infectious agents that caused inflammation. These shortcomings significantly reduce the effectiveness of the treatment of pneumonia.

RF patent No. 2124447, IPC A61N 5/06 discloses a method for postoperative treatment of common forms of purulent infection of the abdominal cavity, including infrared laser therapy in therapeutic doses in combination with irradiation of blood and the anterior abdominal wall from six fields. Magnetic laser irradiation with a magnetic induction of 35 mT is performed, while the anterior abdominal wall is irradiated daily for 2 minutes per field, blood irradiation is performed transdermally over the femoral vessels at an exposure of 15 minutes and alternated every other day with irradiation of the thymus projection zone at a frequency of 10 Hz and exposure 5 minutes with a total course duration of 5-7 days.

The disadvantage of this method is that it is impossible to adjust the exposure parameters depending on the bacterial nature of purulent-inflammatory disease. Since the implementation of the method is carried out by irradiating the skin, there is a high risk of negative effects on the normal microflora of the patient's body.

RF patent No. 2294223, IPC A61N 5/067 describes a method of photoprocessing a biological tissue, which consists in irradiating a biological tissue with light radiation with a wavelength from 500 nm to 2500 nm with an energy density sufficient to induce apoptosis of cells of a portion of a biological tissue containing a chromophore. The method allows for photo-processing for the purpose of inhibiting the growth of unwanted hair, removing vascular defects and age spots of the skin, remodeling the skin, reducing the sebaceous glands in acne, removing neoplasms, reducing, including removal of hypertrophic and keloid scars with the induction of light-induced apoptosis of cells of these parts of the biological tissue.

The method has the disadvantages described above: the reaction of the action of pathological and normal microflora is not taken into account.

Chemical dyes are widely used as one of the types of optical indicators in the diagnosis of diseases in medical practice. One of these dyes is indocyanin green. Indocyanin green is actively used in various fields of medicine: oncology, ophthalmology, cardiology, surgery, dermatology, liver function testing, and cosmetology.

For example, in the patent of the Russian Federation No. 2245123, IPC A61F 9/007, a method for treating neovascular glaucoma by surgical intervention is described. After sedation, anesthesia and akinesia, corneal paracentesis is performed, through which indocyanin green is introduced to stain the newly formed basement membrane, after staining, the membrane is removed from the surface of the iris and from the surface of the trabecula using capsule forceps, the front chamber is washed with saline solution until the green indocyanine residues are completely washed out . Important is also the very low toxicity and rapid elimination of this dye from the body (green indocyanine is excreted from plasma almost exclusively by parenchymal liver cells and is excreted completely in bile). Indocyanin green is a promising dye for use in photodynamic therapy, since its absorption maximum is in the range from 780 to 850 nm, which corresponds to the maximum emission of infrared lasers.

Photocatalytic materials are semiconductors in which, under the influence of light, an electron-hole pair appears, and free radicals with high reactivity are formed on the surface of the material. Titanium dioxide is just such a semiconductor. It is known that titanium dioxide can be used to remove natural or industrial pollutants in air and water under UV irradiation, while air oxygen is reduced, and the impurity is oxidized to form a harmless final product (mineralized). In addition, the surface of titanium dioxide due to the absorption of UV light becomes superhydrophilic. The protective effect of a thin film of titanium dioxide on mirrors or window panes is based on this.

An important feature of titanium dioxide is its ability to absorb light both in the blue (405–420 nm) and infrared (950–1000 nm) spectral regions, i.e. these nanoparticles can be used in combination with a variety of radiation sources: broadband lamps, single-wave LEDs or lasers (Balluzek F.V., Kurkaev A.S., Sentle L. Nanotechnology in medicine. - St. Petersburg: "Sesame", 2007. - 103 from.).

The antimicrobial effect of photodynamic therapy with the simultaneous use of both a photocatalyst and a photosensitizer in combination with radiation of the corresponding spectral composition is ensured by the multiple toxic effects of the generated active radicals (hydroxide radical, superoxide anion, hydrogen peroxide, siglet oxygen).

The use of infrared laser radiation can provide not only the photodynamic effect due to the generation of active radicals, but also photothermal processes. Local supply of thermal energy is widely used in oncology and can be used in the treatment of microbial diseases. The photothermal properties of titanium dioxide nanotubes using infrared (808 nm) laser radiation (GKMor, S.Kim, M. Paulose, OKVarghese et all. Visible to Near-Infrared Light Harvesting in TiO ₂ Nanotube Array-RZNT Based Heterojunction Solar Cells. / / Nano Lett., 2009. - Vol. 9, No. 12. - P. 4250-4257).

Indocyanine green can also be used for a selective local photothermal effect (W. Baumler, C. Abels, S. Karrer, et al. Photo-oxidative killing of human colonic cancer cells using indocyanine green and infrared light. // British J. Cancer, 1999. - Vol.80, No. 3/4. - P.360-363; C. Abels, S. Fickweiler, P. Weiderer, W. Baumler, et al., Indocyanine green (ICG) and laser irradiation induce photooxidation. // Arch. Dermatol. Res., 2000. - Vol. 292. - P.404-411). In this case, local heating will occur only in the area treated with indocyanin green, and will minimize thermal damage to surrounding unpainted tissues.

Closest to the proposed method is the method described in RF patent No. 2318511, IPC A61K 31/409, A61P 27/02, for photodynamic therapy of choroid melanoma. For this, a chlorine-type photosensitizer is administered intravenously at a dose of 0.8-1 mg / kg body weight, then the neoplasm is irradiated with a laser transpupillary with a wavelength corresponding to the maximum absorption of the photosensitizer, 2 to 4 sessions of intravenous administration of FS and laser irradiation of the tumor surface are performed until complete her resorption. A similar method can be used to treat inflammatory diseases of the skin and mucous membranes, the causative agents of which are various microorganisms.

However, for the photodynamic effects of infrared laser radiation, indocyanine green rather than chlorine sensitizers is more advantageous as a photosensitizer. This dye is an approved drug and has a maximum absorption in the infrared region of the spectrum. The disadvantage of the method proposed in the prototype is the need for several sessions, whereas in the proposed method, the antimicrobial effect can be achieved after a single photodynamic exposure.

The objective of the present invention is to develop a method for the effective and selective inactivation of pathogenic and opportunistic microorganisms of pathogens of infectious diseases of humans and animals.

The technical result is an effective means of antimicrobial therapy, unable to adversely affect the normal microbial composition of the skin, oral cavity and other cavities of the patient's body.

The problem is solved in that in the method of destroying pathogenic and conditionally pathogenic microorganisms, the region containing the microorganisms is simultaneously treated with the composition of the photosensitizer and photocatalyst, and they are kept for the period of time necessary for the effective binding of the composition to the cells of the microorganisms; then they act on the indicated area with optical radiation with wavelengths corresponding to the maximum absorption of the photosensitizer and photocatalyst and the power density to activate the composition, while indocyanine green is used as the photosensitizer, and titanium dioxide nanoparticles are used as the photocatalyst.

The invention is illustrated by drawings, where in Fig.1. 2 and 3 show the effect of laser infrared radiation (805 nm) on microorganisms: figure 1 - P. acnes; figure 2 - S.aureus; figure 3 - S. Epidermidis; figure 4 and 5 shows the effect of laser infrared radiation (810 nm) on the colony forming ability of microorganisms: figure 4 - H.ectinomycetemcomitans: figure 5 - Str. Salivarius.

The present invention relates to a method for killing pathogenic and opportunistic microorganisms using a composition comprising titanium dioxide and indocyanine green nanoparticles in combination with infrared laser radiation.

It is assumed that with the simultaneous introduction of a photocatalyst and a photosensitizer into a region containing microorganisms, the effectiveness of the photodynamic-photocatalytic effect will increase due to the synergistic interaction of these photochemically active substances. Titanium dioxide nanoparticles have a porous branched surface capable of sorbing photodynamic dye molecules, thereby increasing the efficiency of electronic excitation when exposed to light and trapping additional electrons to increase the efficiency of the photocatalytic effect. When such a particle-dye system is irradiated, the amount of generated radicals increases. The presence of the particle-dye system in the microenvironment of the bacterial cell or on the surface of the cell wall will ensure its destruction as a result of active oxidative processes.

In a preferred method, a composition comprising titanium dioxide nanoparticles (concentration from 0.1 to 0.01%) and indocyanine green (concentration from 0.1 to 0.01%) is introduced into the region containing pathogenic or conditionally pathogenic microorganisms. A sufficient amount of time is expected (10-20 min) for the composition of substances to contact the cells of microorganisms, then the indicated area is irradiated with laser infrared radiation with a wavelength of 800-1000 nm, a power density of 40 to 50 mW / cm ² for 1- 30 minutes.

The method is carried out according to the following scheme. To create aseptic conditions, an immunological polystyrene 96-well plate is placed in a glass or plastic case. The radiation source is located above the cells of the tablet. When setting the experiments using the daily culture of the studied strain. From the dilution of microorganisms, 10,000 MK / ml 0.1 ml of suspension is added to 0.9 ml of a photosensitizer solution, incubated for 10-20 minutes without access of light. From the final dilution, as well as from the photosensitizer solution, a bacterial suspension in a volume of 0.2 ml is introduced into the cells of the tablet. The exposure to radiation is carried out on bacterial cells in suspension located in the respective cells, sequentially increasing the exposure time. After exposure, bacterial suspensions are transferred to Petri dishes with a dense nutrient medium and evenly distributed over the surface with a sterile spatula. Analysis of the results is carried out by counting the number of colony forming units (CFU) 24-72 hours after anaerobic incubation at 37 ° C. Suspensions of bacteria, not treated with a sensitizer and not exposed to radiation, serve as a control.

Example 1. Determination of the sensitivity of microorganisms to various concentrations of the photosensitizer and photocatalyst after irradiation.

Pathogenic (Propionibacterium acnes) and opportunistic (Staphylococcus aureus, S.epidermidis) microorganisms are used as an object of study. As a photosensitizer use an aqueous solution of green indocyanin with concentrations of 0.1; 0.05; 0.01% Suspensions of titanium dioxide (TiO ₂ ) nanoparticles in a concentration of 0.1 serve as photocatalysts; 0.02; 0.01% When using a laser diode with a maximum emission spectrum λ = 805 ± 15 nm, the radiation power density of 50 mW / cm ² . Irradiation of bacterial suspensions is carried out for 15 minutes

The used concentrations of green indocyanine and titanium dioxide increase the sensitivity of microorganisms to the action of LED radiation.

Example 2. Photodynamic effect on microorganisms, pathogens of acne, sensitized with green indocyanin and titanium dioxide nanoparticles.

Model pathogens are the species Propionibacterium acnes and Staphylococcus aureus, which are the causative agents of skin purulent-inflammatory diseases in humans, in particular acne. P. acnes microorganisms are grown under anaerobic conditions in a special container with a gas mixture of CO ₂ : N ₂ = 9: 1 at a temperature of 37 ° C on a thioglycolic medium. As a representative of opportunistic flora associated with acne, the species Staphylococcus epidermidis is used. Staphylococci are grown on meat-peptone agar at a temperature of 37 ° C.

When using a laser diode with a maximum emission spectrum λ = 805 ± 15 nm, a radiation power density of 50 mW / cm ² . Irradiation of bacterial suspensions is carried out for 5, 10, 15, 30 minutes.

As a photosensitizer, a 0.01% aqueous solution of green indocyanine is used. The photocatalyst is a suspension of titanium dioxide (TiO ₂ ) nanoparticles at a concentration of 0.02%.

The results of the experiments are shown in figures 1-3.

The photodynamic effect using a combination of methylene blue and titanium dioxide nanoparticles demonstrates a pronounced inhibitory effect on the growth of bacterial cells.

Example 3. The effect of laser infrared (810 nm) radiation on the microorganisms that make up the normal microflora of the human oral cavity, sensitized with green indocyanin.

The object of the study is the bacteria of the species Haemophilus actionomycetemcomitans and Streptococcus salivarius - representatives of the normal microflora of the human oral cavity.

When using a laser diode with a maximum emission spectrum λ = 810 ± 15 nm, a radiation power density of 45 mW / cm ² . Irradiation of bacterial suspensions is carried out for 1, 5, 10, 15 minutes. A 0.1% aqueous solution of green indocyanin is used as a photosensitizer. The results of the experiments are presented in figure 4-5.

Claims (8)

1. A method of suppressing pathogenic and opportunistic microorganisms, characterized in that the area containing the microorganisms is simultaneously treated with a composition of a photosensitizer and a photocatalyst, maintained for a period of time necessary for effective binding of the composition to the cells of the microorganisms; then they act on the indicated area with optical radiation with wavelengths corresponding to the maximum absorption of the photosensitizer and photocatalyst and the power density to activate the composition, while indocyanine green is used as the photosensitizer, and titanium dioxide nanoparticles are used as the photocatalyst. 2. The method according to claim 1, characterized in that they are affected by laser infrared radiation. 3. The method according to claim 1, characterized in that the radiation wavelengths are selected in the range from 800 to 10,000 nm. 4. The method according to claim 1, characterized in that the radiation power density is selected in the range from 40 to 50 mW / cm ² . 5. The method according to claim 1, characterized in that the exposure time is from 1 to 30 minutes 6. The method according to claim 1, characterized in that the concentration of green indocyanin is from 0.01 to 0.1%. 7. The method according to claim 1, characterized in that the concentration of titanium dioxide nanoparticles is from 0.1 to 0.01%. 8. The method according to claim 1, characterized in that the period of time is from 10 to 20 minutes

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