RU2641068C1 - Device for treatment of early infection and dermatological diseases - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: device contains an irradiator with a pulse gas-discharge lamp installed in the reflector and a power and control unit connected to the irradiator. The power and control unit include a pulse transformer, ignition pulse generator connected to the primary winding of the pulse transformer, storage capacitor, battery charger, connected to the storage capacitor and secondary winding of the pulse transformer and a control circuit connected to the charger. The pulse gas discharge lamp, storage capacitor and the secondary winding of the pulse transformer are electrically interconnected thus forming a discharge circuit. The irradiator additionally contains a diffuser installed in the middle zone of the reflector, one position sensor, and an electronic key is installed in the power and control unit, with input connected to one of the outputs of the control circuit, output connected to the ignition pulse generator input, and its control input connected with the irradiator position sensor.

EFFECT: increased stability and predictability of the resulting therapeutic effect.

3 cl, 2 dwg

Description

The invention relates to medical equipment used in dermatology and surgery for the treatment and prevention of skin diseases, wound and burn surfaces with high bacterial contamination. It can also be used for non-invasive irradiation of blood with ultraviolet (UV) radiation.

A device for treating wounds is known (patent RU No.2008042, IPC A61N 5/06, published 02.28.1994), comprising an irradiator with a source of ultraviolet radiation in the form of a pulsed gas discharge lamp, a reflector and a light filter, a power and control unit connected to the irradiator. The power and control unit contains a constant voltage source, a storage capacitor connected to a constant voltage source, and an ignition pulse generator. In this case, the pulsed discharge lamp and the storage capacitor are electrically connected to each other so that they form a discharge circuit connected to the ignition pulse generator by means of a pulse transformer.

This device allows you to reduce the time of the treatment procedure and eliminate negative side effects during irradiation. These results are achieved through the use of high-intensity pulsed UV radiation of a continuous spectrum.

The closest device selected as a prototype for the claimed technical solution is a device for the treatment and prevention of dermatological diseases and burn wounds (patent RU No. 2088286, IPC A61N 5/06, published on 08.27.1997). The device comprises an irradiator with a pulsed gas discharge lamp installed in the reflector, a light filter and a power and control unit connected to the irradiator. The power and control unit includes a pulse transformer, an ignition pulse generator connected to the primary winding of the pulse transformer, a storage capacitor, a charger in the form of a high-voltage DC source connected to the storage capacitor and the secondary winding of the pulse transformer, and a control circuit connected to the charging device and to the ignition pulse generator. In this case, the pulsed discharge lamp, the storage capacitor and the secondary winding of the pulse transformer are electrically connected to each other so that they form a discharge circuit.

The technical problem solved by the creation of this invention is the instability and uncertainty of the resulting therapeutic effect when using known devices, especially in the case of extensive affected surfaces.

The following causes of this problem can be noted.

Firstly, when using the reflected and direct radiation of a pulsed gas-discharge lamp to treat the affected wound surfaces, the irradiation field is characterized by a very noticeable heterogeneity: directly under the lamp, the irradiation density is much higher than the irradiation density at the edge of the irradiation field. This is because the direct radiation of the lamp creates irradiation on the treated surface in accordance with the well-known law:

where E is the irradiation of the considered field point;

I _o - radiation power of a pulsed discharge lamp;

L is the slant range to the considered point of the irradiation field;

α is the angle of incidence of the rays on the irradiated (treated) surface.

This shows that when the analyzed point is moved in the transverse direction relative to the axis of the lamp, the irradiation created by direct radiation of the lamp decreases both due to an increase in the slant range and due to an increase in the angle of incidence of the rays on the treated surface.

Thus, the direct radiation of a pulsed discharge lamp introduces a strong inhomogeneity of the irradiation field.

Secondly, the irradiation both in the center and at the edge of the irradiation zone depends on the distance of the irradiator from the treated surface. It is difficult for medical personnel carrying out the treatment procedure for treating affected surfaces with radiation to maintain the optimal distance of the irradiator from the treated surface specified by the technical documentation of medical medical equipment, since in the general case we are talking about extensive affected surfaces of the human body of complex shape (the use of various fixing stands is not considered because of the obviousness and the limitations of such a decision).

The simultaneous influence of these two factors leads to significant uncertainty in the amount of radiation dose received by the wound surface being treated and, therefore, to the uncertainty and instability of the resulting therapeutic effect.

The technical result of the claimed invention is aimed at improving the stability and predictability of the resulting therapeutic effect.

The technical result of the claimed invention is achieved in that the device for the treatment of wound infections and dermatological diseases contains an irradiator with a pulsed gas discharge lamp installed in the reflector, and a power and control unit connected to the irradiator. The power and control unit includes a pulse transformer, an ignition pulse generator connected to the primary winding of the pulse transformer, a storage capacitor, a charger connected to the storage capacitor and the secondary winding of the pulse transformer, and a control circuit connected to the charging device. A pulsed discharge lamp, a storage capacitor, and a secondary winding of a pulsed transformer are electrically interconnected to form a discharge circuit. In addition, the irradiator additionally contains a diffuser installed in the middle zone of the reflector, and at least one position sensor, and an electronic key is installed in the power and control unit, the input of which is connected to one of the outputs of the control circuit, the output is connected to the input of the ignition pulse generator, and its control input is connected to an irradiator position sensor.

In embodiments, the diffuser can be made of quartz glass, as well as in the form of an optical raster.

The invention is illustrated by graphic materials on which are presented:

FIG. 1 is a block diagram of a device for treating wound infections and dermatological diseases together with a scheme for irradiating the affected surface in cross section relative to the axis of a pulsed discharge lamp;

FIG. 2 is a functional diagram of a power supply and control unit with a pulsed gas discharge lamp of an irradiator connected to it and a sensor of its position.

A device for treating wound infections and dermatological diseases comprises an irradiator (Obl) 1, in which a flash gas discharge lamp (IGL) 2, a reflector (OTR) 3, a diffuser (Rass) 4 and at least one position sensor (DP) 5 are placed, and also a power supply and control unit (BPU) 6 connected to the irradiator 1.

IGL 2 is a cylindrical quartz flask with electrodes hermetically welded into its ends. In this case, the interelectrode space is filled with an inert gas, for example xenon.

The reflector 3 is made in the form of a plate with a reflective surface curved in an arc to form a part of the cylinder with a parabolic generatrix. In this case, the needle 2 is placed in the focus (or near the focus) of the reflector 3.

The diffuser 4 is installed in the middle zone of the reflector 3. The diffuser 4 is placed in such a way as to prevent the direct radiation of the IGL 2 from passing to the central region of the radiation field and not to impede the passage of the rays reflected from the reflector 3. The diffuser 4 can be made of quartz glass with frosted surfaces, which will ensure the scattering of incident rays. The use of quartz glass as the material of the diffuser 4 provides the widest spectral range of irradiation (for example, quartz glass of the KU-1 brand is transparent in the wavelength range of 190 ... 2500 nm). In another embodiment, the diffuser 4 may be made in the form of an optical raster of many microlenses.

DP 5 of the irradiator 1 may be, for example, ultrasonic or optical. In any case, the implementation of DP 5 generates an enabling control output signal when the irradiator 1 is removed from the work surface (OD) 7 by a distance h within optimal values, for example, with h = 50 ± 10 mm. When the value of h is outside the specified range, an enabling output signal is not generated.

If it is necessary to isolate a spectral range of radiation in the irradiator 1, an appropriate filter (not shown in the diagrams) can be installed.

BPU 6 contains a control circuit (SU) 8, a charger (charger) 9, a storage capacitor (NK) 10, an electronic key (EC) 11, an ignition pulse generator (ISU) 12 and a boost pulse transformer (IT) 13.

One of the outputs of the SU 8 is connected to the input of the EC 11, the output of which is connected to the input of the ISU 12. Thus, the EC 11 is connected between the SU 8 and the ISU 12 connected to the primary winding of IT 13, while the DP 5 of the irradiator 1 is connected to the control input of the EC 11 SU 8 is also connected to the memory 9, which, in turn, is connected to the NK 10 and the secondary winding of IT 13.

The IGL 2 of the irradiator 1 is connected through the secondary winding of IT 13 to the NK 10 and to the charger 9. In this case, the electrical connection between the NK 10, the secondary winding of IT 13 and the IGL 2 forms a discharge circuit.

SU 8 is made on the basis of a microprocessor and it contains functionally memory cells, a pulse counter, and comparators of the charging voltage. The memory 9 is made in the form of an AC / DC converter and is functionally a high-voltage current source. EC 11 included between the SU 8 and the ISU 12 can be performed, for example, based on a transistor or thyristor. ISU 12 is a relatively low-current discharge circuit based on a capacitor and thyristor, generating voltage pulses of 600 ... 800 V and a duration of 1 ... 10 μs. IT 13 is made on a ferrite ring, the primary winding of which contains 1 ... 2 turns, and the secondary - 20 ... 30 turns.

The proposed device for the treatment of wound infections and dermatological diseases works as follows.

The operator-doctor, depending on the nature of the disease and the degree of tissue damage, sets the required radiation dose by entering the appropriate number of pulses into the memory cell SU 8 using the controls. Then the operator-operator sets or holds the irradiator 1 over the affected area of the patient’s body surface within the optimal range values (in the example, h = 50 ± 10 mm) and turns on the device. To treat extensive wound surfaces, for example, caused by a burn, the operator must move the irradiator 1 over the affected surface during the irradiation procedure, while maintaining optimal removal of the irradiator 1 from the treated surface 7.

SU 8 starts the charger 9 and monitors the voltage on the NK 10. Upon reaching the required value of the charging voltage (1.2 ... 1.5 kV) SU 8 generates a control signal, which through a closed EC 11 is supplied to the ISU 12. At the same time, the ISU 12 generates a pulse ignition in the form of a voltage surge, which, in turn, causes the appearance of a current pulse in the primary winding of IT 13. On the secondary winding of IT 13, a pulse of amplitude 15 ... 20 kV is punched, which breaks through the electrode gap of the IGL 2. Further along the xenon formed in the atmosphere primary wire present channel starts to be discharged NC 10. The NC 10 during the discharge is generated powerful impulse discharge current, which causes intense heating and ionization of xenon. The resulting xenon plasma is intensely emitted in a wide spectral region, including ultraviolet (UV), visible and infrared (IR) radiation. This radiation is reflected from the reflector 3 and falls on the treated surface 7, providing a therapeutic effect.

As the discharge of the NK 10 ends, the inert gas plasma in the IGL 2 cools, the gas goes into the atomic state, the radiation ceases. The device returns to its original state. SU 8, using the comparator included in it, determines the discharge of the NK 10 and fixes the irradiation pulse in the pulse counter. Then the process is cyclically repeated. This ensures that the required dose of exposure to the affected surface of the patient’s body is ensured until the pulse counter readings are equal to the required number of radiation pulses entered into the memory cell SU 8.

Moreover, if during the procedure, for some reason, the location of the irradiator 1 relative to the treated surface 7 changes and the distance h leaves the optimal value zone, the generation of radiation pulses will stop - DP 5 of the irradiator 1 will remove the control signal from EC 11, which in turn closes, as a result of which the ISU 12 will cease to generate ignition pulses. The generation of radiation pulses will resume after restoration of the desired relative position of the irradiator 1 and the treated surface 7. Thus, the radiation dose set by the doctor-operator will be provided regardless of the temporal fluctuations in the removal of the irradiator 1 from the treated surface 7.

The irradiation field generated by the irradiator 1 on the treated surface 7 is determined by the joint operation of the IGL 2, reflector 3 and diffuser 4.

So, only the diffuser 4 illuminates the middle of the irradiation zone and initially the strongest direct radiation from the IGL 2 is scattered and distributed over the treated surface 7, as a result, an excess irradiation level is removed in the middle of the irradiation zone.

The edge of the irradiation zone is illuminated (Fig. 1):

a) 3 rays reflected from the reflector,

b) weakened due to the increased oblique range and angle of incidence "penumbra" direct radiation of the IGL 2;

c) the edge lobes of the scattering indicatrix of the diffuser 4.

As a result of such combined illumination, the irradiation intensity of the edge zone of the irradiation field increases, and along with this, the uniformity of the entire irradiation field increases.

Thus, the proposed device provides for the irradiation of affected, including extensive, body surfaces of the patient with a high degree of uniformity and stability of the dose, which allows to achieve high stability, repeatability and predictability of the therapeutic effect in the treatment of wound infections and dermatological diseases.

Claims (3)

1. A device for the treatment of wound infections and dermatological diseases, comprising an irradiator with a pulsed gas discharge lamp installed in the reflector, and a power and control unit connected to the irradiator, the power and control unit includes a pulse transformer, an ignition pulse generator connected to the primary winding a pulse transformer, a storage capacitor, a charger connected to a storage capacitor and a secondary winding of a pulse transformer, and a control circuit, under connected to the charger, the pulsed discharge lamp, the storage capacitor and the secondary winding of the pulsed transformer are electrically connected to each other so as to form a discharge circuit, characterized in that the irradiator further comprises a diffuser installed in the middle zone of the reflector, and at least one sensor position, and in the power and control unit an electronic key is installed, the input of which is connected to one of the outputs of the control circuit, the output is connected to the input of the pulse generator under firing, and its control input is connected to the position sensor of the irradiator. 2. The device according to claim 1, characterized in that the diffuser is made of quartz glass. 3. The device according to claim 1, characterized in that the diffuser is made in the form of an optical raster.

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