RU2403074C1 - Method of interstitial photodynamic therapy of malignant tumours - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention relates to medicine, oncology, and can be used for interstitial photodynamic therapy of malignant tumors. For this purpose photosensibiliser is introduced intravenously. At least one transparent plastic catheter is installed into tumour. After that light guide is introduced into catheter opening in such way that its end did not protrude beyond catheter limits. Laser irradiation of tumour is carried out through walls of catheter with wavelength, corresponding to peak of photosensibiliser absorption.

EFFECT: method allows to increase outlet power of laser irradiation and prevent thermal changes of irradiated tissues due to absence of direct contact of light guide butt end with tumour tissue, which gives possibility to reduce procedure duration time and apply domestic photosensibilisers, and also allows to increase method efficiency due to possibility of successive irradiation of tumour from deep and surface points moving quartz fibre in catheter opening, periodically take fibre out and evaluate state of its working end.

3 cl, 1 ex

Description

The invention relates to medicine, in particular to oncology, and can be used in the treatment of malignant tumors.

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. With interstitial PDT, the light source is immersed in the thickness of the irradiated tumor. The key problem of interstitial PDT is the thermal changes in the irradiated tissues (coagulation and carbonization), which significantly reduce their permeability to light, and therefore the antitumor effect of the whole procedure.

A known method of interstitial PDT, in which 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 (Moghissi K, Dixon K, Thorpe JA. A method for video-assisted thoracoscopic photodynamic therapy (VAT- PDT)). 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.

One of the disadvantages of this method of interstitial PDT is the need to purchase an expensive cylindrical diffuser, which is also disposable. Since the diameter of this tip is 1-2 mm, it cannot be drawn through the lumen of a standard injection needle and therefore requires the purchase of special devices to immerse it in the thickness of the tumor.

A known method of interstitial PDT, in which interstitial irradiation is carried out using a fiber, the bare end of which is immersed in the thickness of the tumor through the lumen of the injection needle under the control of computed tomography. Large tumors are irradiated from several points of injection. The output power at the end of the fiber is 100 mW, the exposure time is 150-200 seconds. Thus, the total dose of light energy is 15–20 J per exposure point (Lou PJ, Jäger HR, Jones L et al. Interstitial photodynamic therapy as salvage treatment for recurrent head and neck cancer. Br J Cancer. 2004 Aug; 91 ( 3): 441-6.). This mode minimizes the photocoagulation of blood near the end of the fiber, which significantly reduces tissue permeability to light. In this study, the mesotetrahydroxyphenylchlorin (Foscan) drug, which belongs to the second generation photosensitizers, was used as a photosensitizer. Foscan has a maximum absorption at a wavelength of 652 nm, for the development of the photodynamic effect requires a dose of light energy of 15-20 J / cm ² .

Domestic second-generation photosensitizers are represented by Radachlorin, Photoditazine, Photolon. These drugs are activated by light with a wavelength of 662 nm and require for the development of the antitumor effect of the total dose of light energy of 200-300 J / cm ² , which is 10-20 times higher than that when using Foscan. It is obvious that for PDT according to the method described above using domestic photosensitizers, it will be necessary to significantly increase the exposure time. In the treatment of large tumors requiring radiation from several injection sites, the duration of the PDT procedure can increase up to several hours.

Thus, the disadvantage of interstitial exposure using the bare end of the fiber is the long duration of the PDT procedure using domestic photosensitizers, which significantly increases the time of anesthesia. If the laser power is exceeded by more than 100 mW, the risk of thermal damage to the irradiated tumor tissue increases. With the formation of soot at the end of the fiber during irradiation, the efficiency of PDT decreases significantly, so you have to interrupt the procedure for cleaning the fiber, which further lengthens the intervention.

The technical result achieved by the invention is to increase the output power of the laser radiation when using bare optical fiber, as well as to prevent thermal changes in the irradiated tissues.

The claimed technical result is achieved in the method of interstitial PDT of malignant tumors, including intravenous administration of a photosensitizer and subsequent exposure to the tumor by laser radiation with a wavelength corresponding to the absorption peak of the photosensitizer, according to which at least one transparent plastic catheter is first inserted into the tumor, then into the lumen a fiber is inserted into the catheter so that its end does not protrude beyond the catheter and laser irradiation of the tumor is performed through the walls of the catheter.

It is advisable to flush the catheter with 0.5-1 ml of physiological saline before the introduction of the fiber.

The greatest effect is achieved when the tumor is irradiated sequentially from several points, moving the fiber along the catheter.

When the tumor is irradiated through the walls of the catheter, there is no direct contact of the fiber end face with the tumor tissue, which allows using a higher output power without deposit formation at the end of the fiber and reducing the duration of the procedure. This makes it possible to use domestic photosensitizers.

The experiments performed by the authors showed that the proposed method for interstitial irradiation allows the use of laser radiation power from 500 to 1000 mW (depending on the optical properties of the tissue) without the risk of thermal changes in the irradiated tissues.

Washing the catheter with saline is necessary to clean its lumen from the blood received after removal of the needle. Contact of the fiber end with blood, as well as with tumor tissue, is undesirable due to the formation of carbonate.

The placement of the fiber in the catheter provides an opportunity during the procedure to periodically remove the fiber and assess the condition of its working end, and then return it to its previous position.

Since the quartz fiber is movable in the lumen of the catheter, it is possible to sequentially irradiate the tumor from several points, starting from the deepest and ending with the most superficial sections, which increases the efficiency of the method.

The method differs in technical simplicity, and also does not require the use of an expensive cylindrical diffuser and special devices for installing it in the thickness of the tumor.

The method is carried out, for example, as follows.

After a certain period of time, depending on the type of photosensitizer, after intravenous administration of a photosensitizing substance into the thickness of the tumor, one or more (depending on the size of the tumor) transparent plastic catheters for puncture of peripheral veins with an outer diameter of 18g (1.3 mm) are injected into the thickness of the tumor. After removing the needle, the catheter is washed with 0.5-1 ml of physiological saline to prevent contact of blood with the end of the fiber. Then, a quartz fiber with a diameter of 400 μm is placed in the lumen of the catheter so that its end does not protrude beyond the catheter and laser irradiation of the tumor through the walls of the catheter is performed. If necessary, carry out sequential irradiation of the tumor from several points, starting from the deepest and ending with the most superficial departments.

The method is illustrated by a clinical example.

Patient M. (70 years old) was admitted to the hospital with a relapse of squamous cell carcinoma of the larynx after combined treatment (extirpation of the larynx with a postoperative course of TGT). A recurrent tumor was located on the front surface of the neck above and to the right of the tracheostomy, was fused to the skin and underlying tissues. According to the ultrasound of the neck, its dimensions were approximately 30 × 40 mm; no data were obtained for the germination of the main vessels of the neck. Considering that the possibilities of surgical and radiation methods of treatment were exhausted, as well as the patient’s refusal of chemotherapy, a decision was made with the palliative purpose to conduct photodynamic therapy for recurrence of laryngeal cancer. Since the tumor was quite large, preference was given to the interstitial method of irradiation. 1 hour after the iv administration of the “Radachlorin” photosensitizer (at a dose of 1 mg / kg body weight) under conditions of endotracheal anesthesia under ultrasound control, 3 plastic catheters were introduced into the thickness of the tumor at an equal distance from each other. Since a laser divider was connected to a laser source (Lakhta-Milon apparatus), light with a wavelength of 662 nm was supplied simultaneously to 3 fibers (the radiation power at the end of each was 400 mW). Each fiber was placed in the lumen of the respective catheter. Irradiation was carried out at three consecutive positions of the end of the optical fiber inside the catheter (in depth, in the middle part and near the surface of the tumor). Thus, the total number of irradiation points was 9 (3 for each fiber). The duration of irradiation at each point was 500 seconds, the dose of light energy was 200 J. By the end of the irradiation, there was a slight swelling and hyperemia of the soft tissues in the affected area, which disappeared after 2-3 days. During the day after the procedure, the patient complained of slight discomfort in the area of the tumor on the neck, aggravated by swallowing. No increase in body temperature was observed. According to ultrasound, the appearance of a pronounced heterogeneity of the echostructure of the formation was noted, which was a sign of necrotic changes in the tumor. At the control examination after 2 months, the tumor size remained the same (40 × 30 mm).

Thus, as a result of interstitial photodynamic therapy according to the proposed method, an objective antitumor effect was obtained in the form of termination of neoplasm growth (progressive tumor growth was observed before photodynamic therapy).

The method of interstitial photodynamic therapy was used in 3 patients with malignant nodous formations of the neck. In all cases, an objective antitumor effect was obtained: in two cases in the form of termination of tumor growth for 2-3 months, in one - in the form of regression of the tumor mass by 20%. An output power at the end of the fiber of 400 to 600 mW was used. Large tumors were irradiated sequentially from several points by moving the fiber along the catheter from deeper to more superficial sections.

Using the inventive method allows to increase the output power of the laser radiation when using bare optical fiber and to prevent thermal changes in the irradiated tissues.

Claims (3)

1. The method of interstitial photodynamic therapy of malignant tumors, including intravenous administration of a photosensitizer and subsequent exposure to the tumor by laser radiation with a wavelength corresponding to the absorption peak of the photosensitizer, characterized in that at least one transparent plastic catheter is inserted into the tumor, then into the lumen a fiber is inserted into the catheter so that its end does not protrude beyond the catheter and laser irradiation of the tumor through the walls of the catheter. 2. The method according to claim 1, characterized in that before the introduction of the fiber, the catheter is washed with 0.5-1 ml of physiological saline. 3. The method according to claim 1, characterized in that the tumor is irradiated sequentially from several points, moving the fiber along the catheter.