RU2617090C1 - Method for photodynamic therapy of malignant tumours - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: for photodynamic therapy of malignant tumors, photosensitizer and an X-ray marker are introduced intravenous under the radionuclide control, alternating with alignment of their maximum concentrations peaks to track their joint accumulation in tissues by means of an intraoperative gamma camera. Using a gamma camera, tumor position, size, presence of metastases are determined. Further, the tumor is exposed to high power laser radiation - 3 W or more at a wavelength corresponding to the photosensitizer absorption peak. At that, the tumor laser exposure on the surface is performed by short intervals of 5 to 100 ms. In case of deep location of the tumor, it is irradiated according to the same procedure using a needle with an integrated optical waveguide. Then, in 3, 10, 30 days after the manipulation diagnostic administration of marker is performed. If its accumulation in the tumor area reduces by more than 30% on the 30-th day, manipulation is considered successful for the purpose of its further repetition.

EFFECT: improved efficiency of photodynamic therapy due to the greater depth of laser effects on the photosensitizer in case of tumors located close to the skin, as well as interstitial tumors, with the ability to track the spread of laser exposure and to obtain information about the tumor cells location at the moment.

2 cl, 1 ex

Description

The present invention relates to medicine, namely to oncology.

Photodynamic therapy (PDT) is a modern method of treating cancer based on exposure to tumor cells containing a previously introduced photosensitizing substance, laser radiation with a wavelength corresponding to the absorption peak of the photosensitizer.

From medical practice it is known: the method of using photosensitizers for tumors, to which free light source can be provided - tumors of the skin, esophagus, rectum, bronchi and exposure to them using fluorescent lamps and low-power lasers, as well as the method of interstitial PDT, in wherein interstitial laser irradiation is carried out through a special cylindrical diffuser having a length of 1-3 cm and a diameter of 1-2 mm. The study of light takes place along the entire length of the diffuser, therefore, the thermal effect on the irradiated tissue is less than when using a bare fiber without a tip. This allows you to set the output power of the laser radiation at the level of 200-400 mW.

The disadvantages of these technologies are the weak penetration of laser / light radiation deep into the tissues, as well as the inability to directly monitor the spread of the photosensitizer.

Closest to the proposed technical solution is a method of photodynamic therapy of cancer, including the introduction of a photosensitizer into the area of tumor tissue. Then, the tumor tissue is exposed to infrared laser radiation simultaneously at two wavelengths. In this case, the temperature in the area of the tumor tissue is increased to 42-43 ° C. The objective of the invention is to increase the concentration of free oxygen by simultaneously heating the tumor tissue during a PDT session, which increases the generation of singlet oxygen, thereby increasing the effectiveness of photodynamic therapy (See RF patent 2312689, IPC A61N 5/067, publ. 20.12.2007 )

The disadvantages of this method are as follows: this method can be used only for the treatment of oncological diseases of the external organs of a person, the duration of therapy is quite long, while it is impossible to directly monitor the spread of the photosensitizer in tumor tissues.

The task of the invention is to remedy the above disadvantages. The technical result of the invention consists in increasing the efficiency of photodynamic therapy due to the increased depth of laser exposure to the photosensitizer, the ability to track its distribution, as well as the ability to have information about the location of tumor cells at a given time, increasing the effectiveness of photodynamic effects in the treatment of tumors located near the skin , as well as in a more effective irradiation of interstitial tumors. An increase in the depth of irradiation of tumors is provided by a high laser power (more than 3 W), and the prevention of thermal damage to surrounding tissues is achieved due to the short exposure period (less than 100 ms).

The claimed technical result is achieved in that the method of PDT of malignant tumors includes the introduction of a photosensitizer into the area of the tumor tissue and exposure to it by laser radiation.

In accordance with the invention, in order to conduct PDT under radionuclide control, along with a photosensitizer, an x-ray marker is also administered intravenously with the combination of the peaks of their maximum concentrations to track their joint accumulation in tissues by an intraoperative gamma camera. Using a gamma camera, the position, size of the tumor, the presence of metastases are determined. Next, the tumor is exposed to radiation from a high-power laser, 3 W or more, with a wavelength corresponding to the absorption peak of the photosensitizer. At the same time, with the surface location of the tumor, laser irradiation is performed at short intervals from 5 to 100 ms, and with a deep location of the tumor, it is irradiated by the same technique using a needle with an integrated optical fiber. Then, on the 3rd, 10th, and 30th day after the manipulation, the diagnostic introduction of the marker is carried out and, if its accumulation in the tumor zone decreases by more than 30% by the 30th day, the manipulation is assessed as successful for the purpose of its further repetition.

In addition, a technetium radiopharmaceutical with a lyophilisate tropic to the corresponding tumor type is used as an X-ray marker.

The method is as follows.

A patient with an established oncological diagnosis is given an intravenous administration of the N-dimethylglucamine chlorin E6 photosensitizer (photoditazine) at a dose of 0.7-1.4 mg per 1 kg of the patient’s body. A Tc99m radiopharmaceutical, prepared with the appropriate lyophilisate tropic to this type of tumor, is also administered intravenously.

The photosensitizer and radiopharmaceutical are introduced in such a way as to combine in time the achievement of the peaks of the maximum concentration in the tumor.

Further, using the intraoperative gamma camera, the position, size of the tumor, the presence of metastases are determined. Further, using data obtained using a gamma camera, a laser with a power of 3 W (WSLB-660-003-N) and a wavelength of 660 nm is targeted at skin areas that are the closest projection of the tumor marker distribution. Further, with the surface location of the tumors (not deeper than 5 cm from the skin surface), laser irradiation of these areas is performed at short intervals from 5 to 100 ms, which alternately cover the entire projection area of the distribution of the radioactive isotope. A session of local irradiation of the tumor is carried out at a dose of 150-600 J / cm ² . With a deep location (more than 5 cm from the surface of the skin), irradiation is performed according to the same method, only with a needle with a built-in light guide.

On the 3rd, 10th, 30th day after the manipulation, a diagnostic introduction of the marker is made and its distribution and accumulation in the tumor zone is evaluated. If the marker accumulation is reduced by more than 30% by the 30th day, the manipulation can be considered successful and repeated manipulation can be performed.

The greatest effect is achieved when the tumor is irradiated through the skin sequentially from several points located as close as possible to the tumor, it is necessary to take into account the anatomical features and avoid combining the line of the laser beam with the projection of vital organs. Also, to reduce the optical density of tissues, by reducing their blood supply, it is advisable to apply cold to the surface of the skin through which irradiation will be carried out, before the procedure and along its course.

The method is illustrated by a clinical example.

Patient K. (57 years old) was admitted to the hospital with a diagnosis of cancer of the right breast (moderately differentiated T3N1M0 adenocarcinoma). According to MRI, the tumor size was 3 × 4 × 5 cm. According to preliminary studies, a preliminary diagnosis was made: adenogenic breast cancer, which refers to tumors with reduced differentiation.

The patient made a session of photodynamic therapy according to the proposed method. 62 mg of Photoditazine and 47 mg of Tc-99m - Depreotide were intravenously administered. With an interval of 40 minutes between the introduction of drugs, to combine the peaks of their maximum concentration. Further, using the sentinela intraoperative gamma camera, the guidance of the WSLB-660-003-H laser unit to the skin areas that are the closest projection of the tumor was adjusted. Laser irradiation was performed with a wavelength of 660 nm and an installation power of 3 W with an exposure time of 50 ms. The dose of local exposure was 200 J / cm ² . To reduce the optical resistance of tissues, by reducing their blood supply, cold was applied to the skin for 5 minutes before the manipulation and then every minute for 10 seconds all the time the therapy was performed.

After 10 days, scintigraphy revealed a 40% decrease in the accumulation of the X-ray marker in the tumor. Signs of apoptosis were noted in the tumor tissue; further cytological monitoring showed signs of a decrease in malignancy.

Conclusion: the treatment according to the proposed methodology allowed us to reduce the malignancy of the tumor and reduce the tumor volume by 30%, which improved the results of the combined treatment.

Claims (2)

1. The method of photodynamic therapy (PDT) of malignant tumors, including the introduction of a photosensitizer into the area of the tumor tissue and exposure to it with laser radiation, characterized in that in order to conduct PDT under radionuclide control, along with the photosensitizer, an x-ray marker is also administered intravenously in combination with peaks of their maximum concentrations to track their joint accumulation in tissues by the intraoperative gamma camera, with which the position, size of the tumor, the presence of metasta are determined ; then the tumor is exposed to the radiation of a high-power laser, 3 W or more, with a wavelength corresponding to the absorption peak of the photosensitizer, while the surface of the tumor is laser irradiated at short intervals from 5 to 100 ms, and when the tumor is deep, it is irradiated according to the the same technique using a needle with a built-in light guide; then, on the 3rd, 10th, and 30th day after the manipulation, the diagnostic introduction of the marker is carried out and, if its accumulation in the tumor zone decreases by more than 30% by the 30th day, the manipulation is assessed as successful with a view to its further repetition. 2. The method according to p. 1, characterized in that as an X-ray marker, a technetium radiopharmaceutical is used with a lyophilisate tropic to the corresponding type of tumor.