RU56195U1 - DEVICE FOR INTERNAL FREQUENCY BLOOD IRRADIATION - Google Patents

Abstract

The utility model relates to medicine, namely to methods of intravenous irradiation of blood and can be used in the complex treatment of various diseases. The technical result is an increase in the effectiveness of laser exposure in the treatment of diseases such as diseases of the cardiovascular system, musculoskeletal system, inflammatory and degenerative diseases of the nervous system, circulatory disorders in various organs and tissues, stimulation of the immune system, etc. To this end, a device for intravenous frequency blood irradiation contains a block of emitters with infrared to ultraviolet radiation wavelengths, an optical fiber for intravenous administration connected to the emitters, and a control unit that enables the simultaneous inclusion of a set of at least four emitters with different wave dynamics radiation and different frequencies, changing sets of emitters, adjusting the duration of exposure by a set of emitters, adjusting the duration of exposure of each of the emitters , regulation of the frequency of exposure of each of the emitters from 0.001 to 10000 Hz, their power and control the total output power of the emitters, while pulsed lasers or laser diodes are used as emitters. The control unit also provides a change in the parameters of the radiation power density for each wavelength.

Description

The utility model relates to medicine, namely to devices for intravenous irradiation of blood and can be used in the complex treatment of various diseases.

A known method for the treatment of viral diseases by laser irradiation, which is carried out using a device that contains a hydraulic conduit, implanted sequentially in a cut blood vessel and containing a tube transparent to laser radiation, which is irradiated by a laser using a fiber, the end of which is attached to a tube (RU 2044551, 1995 )

A known method of laser irradiation of portal blood in the postoperative period, which consists in the fact that during surgery on the organs of the abdominal cavity, a device consisting of a PVC tube equipped at the end with a quartz hemisphere and containing a quartz fiber is connected to the portal vein in the area of the Vinslov hole, the distal end of which is bent at an angle of 90 °. The proximal end of the fiber is led to the anterior abdominal wall. In the postoperative period, portal blood is exposed to low-intensity laser radiation in the red spectral region at an output power density of 8-10 mW / cm ² for 25030 min (RU 2088280, 1997).

A known method of laser blood irradiation to restore functional renal reserve, in which endovascular blood irradiation is performed with helium-neon laser light with a power of 2.0-3.0 mW at the end of the intravenous fiber, the duration of the irradiation session is 30 minutes, the course is 8-10 sessions (RU 2084248, 1997).

A known method of intravenous irradiation of blood with a laser for the treatment of chronic and chronic recurrent pancreatitis using a device including a fiber connected to a laser training source. Irradiation is carried out using an apparatus for laser irradiation of blood ALOK-1 (RU 2080895, 1997).

A disadvantage of the known methods and devices is their low efficiency.

The technical result achieved by the utility model is to increase the efficiency of laser exposure in the treatment of diseases such as diseases of the cardiovascular system, musculoskeletal system, inflammatory and degenerative diseases of the nervous system, circulatory disorders in various organs and tissues, stimulation of the immune system, etc. d.

The essence of the invention is to achieve the technical result in a device for intravenous irradiation of blood, which contains a block of emitters with radiation wavelengths from infrared to ultraviolet, connected to the emitters, an optical fiber for intravenous administration, and a control unit that enables the simultaneous inclusion of at least , of four emitters with different dynamics of radiation waves and different frequencies, change of sets of emitters, regulation of exposure duration by a set of etter, regulation of the duration of exposure of each of the emitters frequency regulation effects of each of the radiators, their power and control the total output power of emitters, the emitters are used as pulsed lasers or laser diodes.

In addition, the control unit is configured to change during exposure to the radiation power density for each wavelength.

The control unit is configured to increase the radiation power density from 0.000001 to 0.5 W / cm ² , and also to reduce it from 0.5 to 0.000001 W / cm ² and change the radiation frequency from 0.001 to 10000 Hz .

The device is illustrated in the drawing, which schematically shows a device for intravenous irradiation of blood.

The device comprises a control unit 1, associated emitters 2, 3, 4, ... N and an optical fiber 2 connected to the emitters for intravenous administration. The control unit is associated with each of the emitters and is configured to provide simultaneous inclusion in the work of a set of at least four emitters with different dynamics of radiation waves and different frequencies, change of sets of emitters, regulation of the duration of exposure by a set of emitters, regulation of the duration of exposure of each of the emitters exposure frequency control

each of the emitters, their power and control the total output power of the emitters, while pulsed lasers or laser diodes are used as emitters. The control unit provides a change in the process of exposure of the radiation power density for each wavelength, as well as increasing the radiation power density from 0.000001 to 0.5 W / cm ² , reducing it from 0.5 to 0.000001 W / cm ² and changing radiation frequencies from 0.001 to 10000 Hz.

The device operates as follows.

A diagnostic examination of the patient is carried out, the range of wavelengths used is selected, and the required exposure modes are set using the control unit. When choosing exposure parameters are guided by the following:

Depending on the functional state of the organism, a set of emissions of four or more wavelengths is used in various combinations and sequences, with different exposure parameters (power, total duration). Use the irradiation time for each of the wavelengths from 0.1 ms to 30 min, a frequency of from 0, 001 to 10,000 Hz with an absorbed dose of 0.01-10 J / cm ²

The use of low-frequency radiation (up to 80-100 Hz) with a predominance of blue, green and yellow and infrared wavelengths has a calming effect and has a beneficial effect on the nervous system. The combination with the predominance of the ultraviolet, yellow, red and infrared wavelengths in the combination of continuous radiation and frequencies up to 1000-1500 Hz has a tonic effect. A stimulating effect for relieving stressful situations and preventing disease is used in combination with the predominance of the ultraviolet, blue, red and infrared wavelengths in the frequency range from 1500 to 10000 Hz.

In the process of intravenous irradiation, sets of influencing wavelengths and their parameters are successively changed, which depend on the initial state of the patient and the duration of the course of exposure.

A fiber for intravenous administration is introduced into the cubital vein and irradiation of the venous blood flowing inside the vessel is performed.

The operation of the device is illustrated by the following examples.

Example 1. Patient R., 34 years old. She complained of irritability, fatigue, poor sleep. Over the past 2 years, she has had big problems in family life, 3 months. back the family broke up. On their own for 1.5-2 months. took sedatives and sleeping pills, the effect of the therapy was not received. She made an appointment with a neuropsychiatrist, where she was diagnosed with chronic fatigue syndrome, situational neurosis. Within 1 month I took antidepressants, anxiolytics, tranquilizers in combination with vitamin therapy (B1, B6, B12). Then an additional course of psychotherapy and hypnotherapy was carried out. The treatment carried out partially gave effect, irritability decreased, sleep normalized. But the patient felt inhibited, drowsy. Two weeks later, symptoms of irritability and tearfulness began to appear again. The patient was prescribed a course of intravenous blood irradiation with the following parameters: blue, green and yellow and infrared wavelength range. Blue, green - pulse mode, power density drop from 5 mW to 0.001, pulse duration - 10 sec, the interval between pulses - 3 sec. Yellow, - pulse mode with parameters: pulse duration 1 sec, changing the configuration of the power density from 0.24 Wt / cm ² to 0.001 for 10 minutes. The total exposure time is 10 minutes.

Similarly, 10 irradiation sessions were performed (daily).

After the 3rd session, the patient noted normalization of sleep, a decrease in irritability, and by the 5th session, working capacity increased. After the end of the course of exposure, the patient felt satisfactory, did not present any complaints.

Example 2. Patient B., 18 years old. Over the past 3 years, she suffered from herpes and pustular skin lesions. The use of various antiviral and anti-inflammatory ointments did not bring any effect. A set of acting wavelengths was applied: the ultraviolet, yellow, red, and infrared wavelength ranges were used. The ultraviolet range was used with a frequency of 100 Hz., A pulse power of 1 W., for 1 min., The yellow range was formed similar to the previously described. Red range - laser, power 5 mW, pulse mode - 10 Hz., Irradiation time - 2 min, power density 0.48 Wt / cm ² . Infrared

the range was formed using pulsed laser radiation with a frequency of 10,000 Hz, a power of 5 W / pulse, and a pulse duration of 100 nsec. Fifteen treatment sessions were conducted, after which herpetic eruptions completely disappeared and the skin cleared of pustules. The effect of the treatment lasted 3 months.

Example 3. Patient M., 39 years old. He was admitted with complaints of persistent colds, suffered from respiratory viral infections for 6-10 times a year, and suffers from chronic tonsillitis for 5 years. In 2001, he suffered left-sided pneumonia. The patient is prescribed a course of intravenous blood irradiation using radiation of 5 wavelengths with a predominance of ultraviolet, red, infrared wavelength ranges in the frequency range from 1500 to 10000 Hz. The course of exposure was 12 sessions. The irradiation was carried out in a pulsed mode with blue wavelengths (power 0.00005 W for 10 minutes) and a green range with a power density of 0.12-0.14 J / cm ² . The infrared range (diode laser 890 nm) was used with a frequency of 1500 Hz, for 1-2 minutes for 5 sessions, the pulse duration of 100 nsec. The red range (630 nm) is the pulse power of 4 W for 30 seconds. The ultraviolet range was used with a frequency of 100 Hz., A pulse power of 1 W., for 1 min.,

After completing the course of treatment, the patient felt satisfactory for the entire observation period.

The method according to the invention was used to treat 40 patients with various diseases and the state of the immune system. The treatment results confirmed the effectiveness of this method.

Claims (4)

1. Device for intravenous frequency irradiation of blood, characterized in that it contains a block of emitters with wavelengths of radiation from infrared to ultraviolet, connected to the emitters, an optical fiber for intravenous administration, and a control unit that provides for the simultaneous inclusion in the work of a set of at least four emitters with different dynamics of radiation waves and different frequencies, change of sets of emitters, regulation of exposure duration by a set of emitters, regulation of exposure duration I each of the emitters, regulation of the frequency of exposure of each of the emitters from 0.001 to 10000 Hz, their power and control the total output power of the emitters, while pulsed lasers or laser diodes are used as emitters. 2. The device according to claim 1, characterized in that the control unit is configured to change during exposure to the radiation power density for each wavelength. 3. The device according to claim 1, characterized in that the control unit is configured to increase the power density of the emitters from 0.000001 to 0.5 W / cm ² . 4. The device according to claim 1, characterized in that the control unit is configured to reduce the power density of the emitters from 0.5 to 0.000001 W / cm ² .