RU2088285C1 - Oncologic patient treatment method - Google Patents

Abstract

FIELD: medicine, in particular, oncology. SUBSTANCE: method involves exposing tumor to low-intensity laser radiation for three days with energy exposure of 0.1-16 J/sq cm, with exposure time being determined by individual parameters of extreme intensity of blood current in zones exposed to radiation; providing remote gamma-therapy by dynamic dose multifractionation pattern. EFFECT: increased radiosensitivity of radioresistant tumors and improved direct present and future results of treatment. 2 cl

Description

 The invention relates to medicine, namely to the treatment of cancer patients using radiation exposure.

 A known method of treating cancer patients (ed. St. N 1080280. IPC A 61 N 5/00), providing for the introduction of metronidazole to the patient, then conducting remote gamma therapy in conditions of hyperbaric oxygenation.

 A disadvantage of the known treatment method is that metronidazole is toxic to the body and causes dyspeptic disorders and difficulties in the technical implementation of this method due to the lack of pressure chambers in a wide network of healthcare institutions, as well as their low throughput.

 Closest to the proposed one is a method of treating a tumor (see "Actual Issues of Laser Medicine and Surgical Endoscopy". Materials of the Third International Conference May 30, June 1, 1994 Moscow Vidnoye, pp. 379-380), including the combined effect of distance gamma on the tumor therapy and low-intensity laser radiation.

 However, it should be noted that in this method the authors did not use the possibility of using low-intensity laser radiation taking into account changes in the direct individual oxygenation parameters before and during treatment, the laser training was carried out with constant temporary exposure, and remote gamma therapy was used according to the traditional scheme, in comparison with the dynamic multifraction scheme, which is not the most effective from the radiobiological point of view. In addition, the authors judged the effect of enhancing the degree of oxygenation of tumor tissue by morphological data: the presence of hypoxic zones and zones of necrosis in the tumor tissue and a change in the mitotic activity of tumor cells, and not by specific individual indicators of oxygenation of the pathological focus.

 The task posed by the authors is to eliminate these disadvantages, namely: to use in clinical practice for remote gamma therapy of cancer patients the radiosensitizing effect of low-intensity laser radiation, based on direct indicators of tumor tissue oxygenation before and during laser therapy, allowing low-intensity laser irradiation with individual temporary dose in each patient. In addition, a more effective, from a radiobiological point of view, scheme of dynamic dose multifractionation was used, combining summing up aggregated fractions with reduced fractions.

The problem is solved as follows: in a method of treating cancer patients, including exposure to a tumor by remote gamma therapy and low-intensity laser radiation, it is proposed that the laser effect be carried out for at least three days at a light density of 7-220 mW cm ² with energy with an exposure of 0.1 16.0 J / cm ² , the exposure time per procedure should be determined by the individual parameters of the maximum blood flow enhancement in the exposure zone, and remote gamma therapy should be carried out 6-25 minutes after exposure to low-intensity laser radiation.

 In addition, it is proposed that remote gamma therapy be performed according to a dynamic multifraction scheme.

 Carrying out laser irradiation for three days with the indicated physical and technical characteristics makes it possible to increase the supply of oxygen-saturated blood to the tumor, which makes it possible to reduce the number of hypoxic cells in the tumor and, therefore, increase its radiosensitivity.

 Determination of the individual time interval between laser and radiation exposure allows optimal use of the oxygen effect.

 The exposure of the laser exposure is also determined individually, which avoids exceeding the therapeutic dose and adverse effects.

 In addition, the fact that the proposed gamma therapy is carried out after at least 6-25 minutes, allows to increase the sensitivity of the tumor cell to this treatment.

 The method is as follows.

Prior to treatment, the patient determines the initial indicators of tumor oxygenation by the method of laser fluorescence using mixed light, after which the pathological object is trained with low-intensity laser radiation at an illumination of 7-220 mW / cm ² and an energy exposure of 0.1 16.0 J / cm ² and indicators are recorded simultaneously. tumor oxygenation every minute until its maximum level of increase is reached. The illumination parameters were chosen within the indicated limits, taking into account the fact that the penetrating possibility of low-intensity laser radiation of less than 7 mW / cm ^{2 is} insufficient to reproduce the radio-modifying effect, and at parameters above 220 mW / cm ² the onset of thermal exposure is noted.

 The total time of the procedure for each patient is different, it depends on the individual characteristics of the body and is within 1 30 minutes. The laser training course consists of three procedures, as a result, an increase in oxygenation by 15-60% from the initial one is noted, which remains at this level for 25-30 minutes with a subsequent decrease. Immediately upon reaching the peak of oxygenation of the tumor, remote gamma therapy is applied according to various, depending on the location of the tumor, dynamic multifraction schemes, and the combined use of laser exposure and radiation therapy is used in every first 3 days of both halves of a split treatment course. Taking into account the individual characteristics of tumor oxygenation, remote gamma-therapy is carried out in 6 25 min after laser exposure.

 Remote gamma therapy is carried out according to the scheme of dynamic multifraction of the dose when summing up coarse fractions of 3.6 4 Gray immediately after laser exposure. Next, radiation therapy is carried out in the usual way without prior laser exposure with the addition of single focal doses of 1.0 1.2 Gray to daily focal doses of 2.0 2.4 Gray in the irradiation mode 5 times a week to total focal doses of 30.0 - 34, 8 Gray.

 In particular, radiation treatment of cancer of the oropharyngeal zone is carried out according to the scheme of dynamic multifraction of the dose to a total focal dose of 34.8 Gray: in the first 3 days of treatment, remote gamma therapy is used with a single focal dose of 3.6 Gray to a total focal dose of 10.8 Gray, and from the 4th to the 13th day of treatment with a single focal dose of 1.2 Gray 2 times a day with an interval between irradiation sessions of 4-6 hours, in the irradiation mode 5 times a week. After a 10-14 day break, the treatment course is repeated in a similar pattern to the total focal dose, taking into account the previous course, 69.6 Gray, together with the use of low-intensity laser radiation in a similar pattern.

 Radiation therapy of skin cancer is carried out according to the scheme of dynamic multifraction of the dose to a total focal dose of 30 Gray: in the first 3 days, remote gamma therapy is used with a single focal dose of 4 Gray to a total focal dose of 12 Gray, and then from 4 to 12 days of treatment with a single focal dose of 1 Gray 2 times a day with an interval between sessions of 4-6 hours, in the irradiation mode 5 times a week. After a 10-14 day break, the treatment is repeated according to a similar pattern to the total focal dose, taking into account the previous course, 60 Gray, together with the use of low-intensity laser radiation according to a similar pattern.

 Examples of specific performance of the method.

 Example 1

 Patient K., 72 years old, medical history N 1980, was admitted to the clinic with complaints of a tumor on the skin of the right auricle with a transition to the skin behind the ear, measuring 3.5 x 1.8 x 1.2 cm, with ulceration in the center, motionless in relation to the underlying tissues. Diagnosed with basal cell carcinoma of the right auricle of the II st. T2NoMo. Solid adenoid form.

The patient was used low-intensity laser radiation, in order to use its radio-modifying properties, illuminance of 8 mW / cm ² , energy exposure of 2.9 J / cm ² , exposure time of 6 min, which was determined by laser spectrophotometry, registering simultaneous indicators of tumor oxygenation every minute laser exposure to the maximum peak oxygenation. As a result, an increase in oxygenation rates by 60% from the original was recorded. Next, radiation therapy was carried out on the Agat-R gamma therapeutic unit according to the dynamic multifraction scheme in terms of independent radiation treatment according to the radical program with a split course under the following conditions: source skin distance 75 cm, training field 4x6 cm, single focal dose 4 Gray to a depth of 1 cm immediately after 6-10 minutes for 3 days to a total focal dose of 12 Gray. Subsequent gamma-ray therapy is carried out from the 4th to the 12th day of treatment at a single focal dose of 1 Gray 2 times a day with an interval between sessions of 4 hours in the irradiation mode 5 times a week, without prior laser exposure to a total focal dose of 30 Gray.

 As a result of treatment, tumor regression was noted up to 30% of the initial size. The patient in satisfactory condition was discharged for a 2-week planned break for the implementation of the therapeutic effect. After 2 weeks, the patient was admitted to the clinic for the second stage of treatment. At the same time, the tumor shrank by 60% of its original size. Further, laser exposure and remote gamma therapy were carried out according to a similar scheme to a total focal dose of 60 Gray, taking into account the previous course. As a result of laser exposure by laser spectrophotometry, an increase in tumor oxygenation by 60% of the initial values was recorded.

 After the treatment, complete regression of the tumor was noted; on the control examination after a month, there were no signs of tumor growth.

 Example 2

 Patient A. 64, medical history N 16830, was admitted to the hospital with complaints of pain when swallowing and feelings of a foreign body in the oral cavity. Diagnosed with oropharynx cancer III-B art. TzN2Mo. Differentiated squamous keratinized form.

The patient used low-intensity laser radiation with an illumination of 9 mW cm ² , an energy exposure of 8.1 J / cm ² and an exposure time of 15 min, which was determined similarly to the above scheme. As a result, an increase in tumor oxygenation by 47% of the initial values was recorded. Next, radiation therapy was performed on the Luch gamma therapeutic unit according to the dynamic multifraction dose regimen in terms of independent radiation treatment according to a radical split-rate program under the following conditions: source surface distance 75 cm, from 2 opposing temporomandibular fields 6x9 cm at a single focal dose 3.6 Gray, calculated to a depth of 6 cm, immediately after laser exposure after 8-12 minutes for three days to a total focal dose of 10.8 Gray. Subsequent gamma-ray therapy is carried out from the 4th to the 13th day of treatment - with a single focal dose of 1.2 Gray 2 times a day, with intervals between training sessions of 6 hours, in the irradiation mode 5 times a week, without prior laser exposure to the total focal dose 34.8 Gray.

 As a result of treatment, tumor regression was noted up to 30% of the initial size.

 Two weeks after the planned 2-week break, the patient was admitted to the clinic for the second stage of treatment, while the tumor was reduced to 45% of the original size. At the second stage of the split course, laser exposure and remote gamma-therapy were carried out according to a similar scheme to a total focal dose of 69.8 Gray, taking into account the previous stage. As a result of laser exposure by laser spectrophotometry, an increase in tumor oxygenation by 54% of the initial data was recorded.

 After the treatment, the tumor significantly regressed in size, however, the remainder of the tumor was up to 10%. On the follow-up examination after a month there were no signs of tumor growth.

 As a result of the application of this method in clinical practice, it is possible to increase the radiosensitivity of radioresistant tumors, which allows counting on the improvement of both immediate and long-term treatment results.

Claims (2)

1. A method of treating cancer patients, including the combined exposure of the tumor to remote gamma therapy and low-intensity laser radiation, characterized in that the exposure to low-intensity laser radiation is carried out for at least three days at an illumination of 7,220 mW / cm ² with an energy exposure of 0, 1 16 J / cm ² , and the exposure time for the procedure is determined by the individual parameters of the maximum increase in blood flow in the irradiation zone, while remote gamma therapy is carried out in 6 25 minutes after each exposure to low-intensity laser radiation.  2. The method according to claim 1, characterized in that the remote gamma therapy is carried out according to the scheme of dynamic dose multifraction.