RU2173458C1 - Method for determining low intensity radiation kinds exerting effective action upon patient organism - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method involves preparing a number of laboratory glass tubes containing the same quantity of patient blood serum and irradiating them with low intensity radiation of various kinds. The tubes are kept during 18-20 h at 5-8 C. A drop of each blood serum sample having volume of 0.01-0.03 ml is placed on microscopic slide surface and dried at 20-30 C. The most marked radial sectors and concretions, when compared to control sample, being detected in a dried drop, the corresponding kind of radiation is considered to be of optimum influence upon the patient organism. EFFECT: simplified method usable in both surgical and therapeutic hospitals. 3 dwg

Description

 The invention relates to medicine, namely to laboratory research.

 It is known that the use of low-intensity laser and EHF radiation in medicine can significantly accelerate the healing of surgical and traumatic wounds by accelerating the repair of body tissues, reducing the effects of inflammatory infiltration, immunomodulating and desensitizing effects (V. Illarionov, “Conceptual basis for physiotherapy in rehabilitation” ., M., 1998, p. 27-74).

 However, to achieve the desired clinical effect when exposed to an external physical factor, an individual selection of optimal energy parameters and the type of low-intensity radiation is necessary.

 A known method for determining individual sensitivity to low-intensity laser exposure, including polarization-optical study of blood plasma (Autosvid. USSR N 1635999 Mints RI et al., "Method for determining individual sensitivity to laser exposure", 1991).

 However, this method allows you to determine the sensitivity of only one type of low-intensity radiation, in particular only laser. At the same time, other types of low-intensity effects on the body are beginning to be widely introduced in medical practice: electromagnetic radiation of extremely high frequency (EHF EHF), the combined use of EHF EHF with laser radiation, magnetic and others.

 The task was to eliminate this drawback and create such a method for determining individual sensitivity, which would make it possible to predict the effectiveness of the type of low-intensity effect that most optimally affects the tissue regeneration processes of this patient.

This is achieved by the fact that in the method for determining the type of low-intensity radiation that effectively affects the patient’s body, including microscopic examination of blood serum, it is proposed to prepare a series of tubes with the same volume of the patient’s blood serum, irradiate them with different types of low-intensity radiation, after 18-20 hours of storage of blood serum at 5-8 ^o C apply a drop of blood serum in a volume of 0.01-0.03 ml on the surface of a glass slide, dry at a temperature of 20-30 ^o C and in the presence of the most pronounced radial sec tori and nodules in a dry drop compared with the control before exposure to determine the type of radiation that optimally affects the body.

 The proposed method in vitro allows us to evaluate the integrated systemic organization of blood serum as an adequate response of the body's homeostasis to exposure to various types of low-intensity radiation. Due to the indicated exposure parameters of blood serum samples after exposure, the possibility of a reliable assessment of the stability of various types of exposure is achieved.

 In FIG. 1 shows a picture of dried drops of blood serum when exposed to an EHF EHF, a low-intensity laser and the combined effect of an EHF EHF + low-intensity laser and a control - without exposure (Example 1), FIG. 2 is the same, example 2, in FIG. 3 - same as example 3.

 The method is as follows.

The patient’s blood serum is divided into a number of identical portions (for example, 1.0 ml each) and the contents of the tubes are irradiated separately, for example, EHM EHF, low-intensity laser radiation and their combination. One serving control. After 18 - 20 hours of standing in the refrigerator at a temperature of 5 - 8 ^o C, dig up blood serum from all test tubes of 0.01 ml onto the surface of a glass slide, dried at a temperature of 20 - 30 ^o C for 18 - 20 hours and evaluate the pattern of structural engineering ( systemic organization) of dried drops in comparison with the control. With the most harmonious picture of the structure of the dried drop, determine the type of low-intensity radiation, which is optimal for exposure to the body of this patient. The presence of the most pronounced radial sectors and nodules in the dry drop compared with the control before exposure indicates the level of harmonization.

Example 1
Patient Sh., 47 years old. Preparation for the planned operation was carried out using low-intensity radiation to prevent possible postoperative complications. Diagnosis at admission: chronic cholecystitis, gallstone disease. A study of blood serum in this way revealed the following patterns of the structure of the dried drop compared to control (a) when exposed to EHF radiation (b), low-intensity laser radiation (c), combined low-intensity radiation "EHF + laser" (d) (see Fig. . 1). The most harmonious structural construction is observed when exposed to combined low-intensity radiation "EHF + laser" on the blood serum - a clear center, radial cracks, radial nodule sectors of the same diameter.

 Conclusion: the optimal type of exposure for this patient is the combined low-intensity radiation "EHF + laser".

 In the subsequent postoperative period passed without complications. Wound healing occurred by primary intention.

Example 2
Patient M., 69 years old, preparing for a planned operation is carried out using low-intensity radiation to prevent possible postoperative complications. Diagnosis at admission: gallstone disease.

 A study of blood serum in this way revealed the following patterns of the structure of the dried drop as compared with control (a) when exposed to EHF radiation (b), low-intensity laser radiation (c), combined low-intensity radiation "EHF + laser" (d) (see Fig. 2). The most harmonious structural construction is observed when low-frequency EHF radiation (extremely high frequency) is exposed to blood serum — a clearer center, the appearance of radial cracks, radial sectors, and nodules of approximately the same size.

 Conclusion: the optimal form of exposure for this patient is low-intensity EHF radiation.

 The postoperative period went smoothly. Wound healing - primary intention.

Example 3
Patient P., 62 years old, preparing for elective surgery was performed using low-intensity radiation to prevent possible postoperative complications. Diagnosis at admission: chronic cholecysto-cholangitis, cholelithiasis.

 A study of blood serum in this way revealed the following patterns of the structure of the dried drop compared to control (a) when exposed to EHF radiation (b), low-intensity laser radiation (c), combined low-intensity radiation "EHF + laser" (d) (see Fig. .3). The most harmonious structural construction is observed when low-intensity laser radiation is exposed to blood serum — a clearer center, numerous radial cracks and radial sectors, nodules of approximately the same diameter.

 Conclusion: the optimal form of exposure for this patient is low-intensity laser radiation.

 In the subsequent postoperative period passed without complications. Healing by first intention.

 The method is technically simple, demonstrative and can be successfully used in the laboratories of medical institutions in both surgical and therapeutic hospitals.

Claims (1)

 A method for determining the type of low-intensity radiation that effectively affects the patient’s body by examining blood serum, characterized in that a number of tubes with the same volume of blood serum of the patient are prepared, irradiated with different types of low-intensity radiation, after 18 to 20 hours of storage of blood serum at 5-8 ° C is applied drop by drop of blood serum in a volume of 0.01 - 0.03 ml to the surface of a glass slide, dried at 20 - 30 ° C and in the presence of the most pronounced radial sectors and nodules in a dry drop compared to role before exposure determine the type of radiation that optimally acts on the body.

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