RU2118186C1 - Method of light therapy - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method is effected in broad spectral range, particularly in 250-400 nm ultraviolet wave-length range. Surface of patient's body is exposed to pulsed irradiation with pulse duration of at least 10^-3s and not over 10^-2s. Simultaneously, irradiated section is subjected to mechanical effect. Method contains dependence between duration of pulses and their quantity. Blood gets the same therapeutically significant irradiation dose through skin as in case of its continuous irradiation beyond organism. As compared with similar methods, given method ensures higher safety of treatment by irradiation of blood with light radiation directly in vessels, through skin. Method is simple and can be used in clinic and individually under any conditions. EFFECT: enlarged functional capabilities, higher efficiency. 3 cl, 1 dwg

Description

 The method relates to physiotherapy, radiation therapy and can be used in the prevention and treatment of a number of diseases of humans and animals.

 A known method of irradiating blood with ultraviolet (UV) radiation (see Collected works "Mechanisms of the influence of blood irradiated with UV rays on the human and animal body. - L .: Nauka, 1986), in which blood is initially taken from a patient in quartz a cuvette (in a volume of 1 ml per 1 kg of patient weight), then it is irradiated with (quartz) UV radiation for 10-20 minutes, and then sent back to the patient's circulatory system. The disadvantages of this method are the need for blood sampling and irradiation outside the body, the pain and complexity of the procedure, the risk of infection (the associated difficulties of sterilization), low productivity.

 An urgent problem is the provision of the possibility of irradiating blood with light, in particular, UV radiation directly in the human body (in vivo), i.e., without reinfusion of blood and the associated difficulties and dangers. Known methods of irradiation with laser radiation through a light guide inserted into a blood vessel do not solve this problem, because have the same disadvantages: violation of the integrity of the skin and blood vessel, associated with soreness and the risk of infection; complexity - low productivity.

The positive effect of general and local light baths is well known as a way of preventing and treating a number of diseases (see, for example, Physiotherapeutic Handbook. Edited by IN Sosin - Kiev, 1978). However, the radiation does not penetrate the blood, because almost completely absorbed by the skin, a layer of 1-2 mm (see Sokolov M.V. Applied biophotometry.-M .: Nauka, 1982). With an increase in the radiation intensity, there is a danger of burns on the patient's skin, and the resulting erythema increases the absorption of radiation. A known method of light therapy (Bukhman, 1923, Heliotekhnik, N 2, 1980, S. 37-38), in which the patient's body surface is irradiated with concentrated sunlight with a frequency of 2 Hz and a pulse duration of 0.5 s. Salient features of the prototype method: the patient is irradiated with light pulses, concentrated light, solar, spectral wavelength range of more than 400 nm, pulse duration 0.5 s, frequency 2 Hz. The first sign is common with the claimed method. The disadvantages of the prototype method: there is practically no UV component of the spectrum, because terrestrial solar radiation practically does not contain UV radiation with a wavelength shorter than 350 nm, and a Buchman mirror with internal reflection is even shorter than 400 nm, while the most active for irradiation of blood is the range of 250-380 nm (see 1st link) ; the negative effect of the thermal effect of concentrated sunlight is not ruled out (the temperature in the spot can reach 200 ^o C); low therapeutic effect due to insignificant penetration of radiation into the subcutaneous layers: a significant limitation on the thermal effect under these conditions introduces a limitation on the radiation intensity over time, which would be sufficient to create the required dose of blood irradiation. Under these irradiation conditions, erythema occurs on the skin, which even more prevents the penetration of radiation through the skin. The disadvantages of the method can also include the limited application, cumbersome, depending on the weather.

 The purpose of the proposed method is the expansion of functionality, increasing efficiency, efficiency, safety by irradiating the blood with light radiation, in particular ultraviolet, directly in the blood vessels, through the skin.

где
H_H(Δλ) - эталонная экспозиционная доза облучения крови вне организма в диапазоне Δλ, при которой достигается терапевтический эффект;

пропускание среды - интегральный коэффициент пропускания кожи, тканей, стенок сосудов;

облученность, создаваемая импульсным излучателем на поверхности тела в диапазоне Δλ;
t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ длительность импульса излучения (на уровне 0,35 от амплитуды).This goal is achieved in that the irradiation of the surface of the patient’s body is carried out with light pulses, the duration of which is not less than 10 ^-8 s and not more than 10 ^-2 s. In a particular case, irradiation is carried out in the ultraviolet (UV) wavelength range of 250-400 nm, and the number of irradiation pulses is determined by the formula

Where
H _{H (Δλ)} - reference exposure dose of blood irradiation outside the body in the range Δλ, at which the therapeutic effect is achieved;

transmittance of the medium - the integral transmittance of the skin, tissues, vessel walls;

irradiation created by a pulsed emitter on the surface of the body in the range Δλ;
t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ the duration of the radiation pulse (at the level of 0.35 of the amplitude).

In another particular case, simultaneously with the irradiation pulse, a mechanical compressive effect on the irradiated area in the direction of irradiation is carried out with a force of 0.3-0.6 kg / cm ² , terminated at the end of the pulse.

Achieving this goal is due to the fact that pulsed light irradiation under these conditions allows irradiation of deep areas of the body, in particular irradiation of blood directly in the vessels. This is explained by the fact that with the duration of the light pulse t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ less than 10 ^-2 , on the one hand, the reaction of pigmenting molecules in the composition of skin cells, which with continuous irradiation and at t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ more than 10 ^-2 s usually screen radiation due to photochromic reactions. On the other hand, at τ $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ less than 10 ^-2 s there is practically no thermal effect on the skin, due to which it is possible to irradiate with a stream of very high intensity - several orders of magnitude higher than with continuous irradiation. Both of these effects make it possible to increase the penetration depth of light, including UV radiation through the skin and walls of blood vessels. For example, for an IFK-150 flash xenon lamp in the range of 250 - 400 nm on a site of 100 • 100 mm ² with a pulse duration of 10 ^-3 s, the irradiation is 1.55 • 10 ⁴ W / m ² (see A. Doinikov Spectral emission characteristics of tubular xenon flash and arc lamps.-M .: Central Research Institute "Electronics", 1973). The total transmittance of the skin and blood vessel wall of only 0.0002 (i.e., 0.02%) is sufficient to reproduce on the blood the same irradiation in the indicated spectral range as with continuous irradiation (3 W / m ² ) in a facility type "Isolde" -cm. link N 1-, at which the therapeutic effect is achieved with the invasive (continuous) method of radiation. It should be noted that the transmission of light by the skin, as determined in a number of sources (see, for example, Sokolov MV, Applied Biophotometry), was measured for continuous radiation. In this case, radiation when transmitting the skin at a level of 1% is practically impossible to register - the intensity at the exit from the skin is too low, and it is impossible to use a more powerful source of constant UV radiation due to a burn. It follows that it is impossible to unconditionally use the known data on the penetration depth of light, in particular UV radiation, under the skin, because for pulsed radiation at t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ less than 10 ^-2 s, the penetration depth is significantly greater, because, firstly, the transparency of the skin is higher, and, secondly, the permissible levels of irradiation are thousands of times higher (because they are harmless - they do not create erythema). These circumstances (effect) create the conditions for subcutaneous irradiation of blood in the optical (and UV) range in vivo.

The boundary value of the pulse duration of 10 ^-8 s determines the minimum period of time during which the photoreaction in the blood has time to occur with the formation of its active components (i.e., the time during which photoionization of the outer electron shells takes place). Irradiation in the UV range of wavelengths of 250 - 400 nm under these conditions allows hemotherapy with UV radiation directly in the body (in vivo) in the same way as in the cuvette of the Isold installation using the analogous method. This ensures a dose of blood irradiation equal to the dose of UV radiation in the cuvette, which achieves the same therapeutic effect as in the analogue method (see reference N1). For example, at the Isolda-73mD installation, the radiation dose in the UV range of the blood in the cuvette is 32 J / m ² . The exposure dose is generally determined from the formula
H _{H (Δλ)} = E _{H (Δλ)} t, (1)
Where
E _{H (Δλ)} is the irradiation in the spectral range Δλ;
t is the exposure time.

где
t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ - длительность импульса (на уровне 0,35 от амплитуды).In the case of pulsed radiation, the dose is determined from the formula

Where
t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ - pulse duration (at the level of 0.35 of amplitude).

в пределах 10^{-2 o}C 10^-8 с диапазон изменения облученности составит от 3•10^-2 до 10¹² Вт/м², а K_и будет изменяться от 200 до 1. Из литературы (см. Соколов М.В.), а также из эксперимента известно, что пропускание τ_c(Δλ) в спектральном диапазоне 250-450 нм составляет величину в пределах 0,001-0,01. В качестве примера определим K_и для лампы ИФК-150 при длительности импульса t'₄, равном 5•10^-3 с, и облученности и УФ-области 1,55•10⁴Вт/м², полагая τ_c(Δλ) равным 0,005- из (5) получим:
K_и = 32/5•10^-3•1,55•10⁴ •5•10^-3 = 83,
т. е. получения кровью в организме по описанному способу той же терапевтически значимой дозы, что и кровью в кювете на установке "Изольда", необходимо воспроизвести 83 импульса.The total dose for pulsed irradiation is
H $\genfrac{}{}{0ex}{}{\text{∑}}{\text{u (Δλ)}}$ = k _u H _{u (Δλ)} , (3)
or taking into account the transmission of medium τ _{c (Δλ)} (transmission of skin, tissues, blood vessels)
H $\genfrac{}{}{0ex}{}{\text{∑}}{\text{u (Δλ)}}$ = τ _{c (Δλ)} k _u E _{u (Δλ)} t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ , (4)
Equating expressions 1 and 4, we obtain for the number of pulses K _and
k _u = H _{H (Δλ)} / τ _{c (Δλ)} E _{u (Δλ)} t $\genfrac{}{}{0ex}{}{\text{′}}{\text{u}}$ , (5)
One and the same dose can be obtained with various combinations of quantities included in formula 5. Thus, when changing

within 10 ^{-2 o} C with 10 ^-8 range of variation of irradiance will be from 3 • 10 ^-2 to 10 ¹² W / m ^2, and _{K, and} will vary from 200 to 1. From the literature (see. Sokolov MV) and also from the experiment it is known that the transmission τ _{c (Δλ)} in the spectral range of 250-450 nm is in the range of 0.001-0.01. As an example, we define for the lamp _and K-150 in the IFC _4, 5 equal pulse durations t '• 10 ^-3 s, and the irradiation and the UV region 1,55 • 10 ⁴ W / m ^2, assuming τ _{c (Δλ)} equal to 0.005- from (5) we get:
K _and = 32/5 • 10 ^-3 • 1.55 • 10 ⁴ • 5 • 10 ^-3 = 83,
that is, receiving the blood in the body according to the described method of the same therapeutically significant dose as the blood in the cuvette on the Isold apparatus, 83 pulses must be reproduced.

The interval T _and between pulses does not affect the dose size and depends on the inertial properties of the lamp, switching circuit, and operating mode. T _and may be from 0.01 to 20 s. Therefore, the maximum procedure time for the described method is about 30 minutes. The average value of T _and is equal to 6.10, and hence the average treatment time of 8-15 min, which is significantly less than for analog (at the "Isolde" time actually procedure is about 20 minutes), but the time of its preparation is 30-40 min i.e. in the amount of about 1 h, in addition, it takes time to sterilize, rest the patient after the procedure, prepare saline, etc.

The implementation of squeezing the irradiated area of the body simultaneously with the irradiation pulse provides a deeper penetration of light radiation due to the reduction of scattering losses in loose tissues (the same can be obtained on foam rubber). The lower threshold of the effect is 0.3 kg / cm ² , and the restriction for the pressure force is the force at which the blood vessel is clamped - the patient experiences pain - 0.6 kg / cm ² . The use of squeezing allows you to work with lower values of irradiation, lower power of the light source, to increase the localization of radiation. It is advisable to irradiate in places where arteries pass, but usually protected from the sun (unpigmented), such as the inner surface of the shoulder, inguinal region, etc.

The method is illustrated in the figure, where it is indicated: 1 - radiation source, 2 - light filter, 3 - body surface area, 4 - blood vessel, P - external force. In option a, a relatively large portion of the body surface is irradiated, and option b shows the use of a “light syringe” —pulse irradiation with simultaneous pressing with a force P. The method is simple to implement: source 1 is placed at a certain distance from the body surface (or close to the surface) - the distance is determined based on the required irradiation and the size of the irradiated area. Direct source 1 with filters 2 to the irradiated section 3 and turn on the source by pressing a button. After an interval of 0.01 - 20 s, the next button is pressed. The inclusion of the source is repeated K _{and the} times at which a predetermined dose of radiation is provided (from formula 5). The procedure lasts about 10 minutes.

 Experimental studies of the method were carried out on animals (rats, cattle, pigs). Studies have been conducted since 1985, as well as clinical trials over several years (see act, conclusion). An IFK-150 pulsed xenon lamp with a UFS-5 light filter 5 mm thick was used as a radiation source.

The pulse duration was: 5 • 10 ^-3 and 10 ^-3 s. The inner surface of the shoulder was irradiated. The lamp was located at a distance of 0 - 100 mm, the size of the light spot was 100 • 100 mm ² . An analysis of the results showed that at certain doses of radiation it is possible to obtain the same effect on 32 main blood parameters (including immunological parameters) as when irradiating blood in a cuvette (outside the body) with UV radiation (see theses of the report).

 Thus, the achievement of a positive effect is confirmed experimentally. According to the described method, several dozen patients have already been treated at the department of the Kuban Medical Institute - now the Academy (Department of Hospital Surgery). The immunostimulating effect of radiation by the proposed method was proved (the method was first issued in the form of an application in 1985, but was rejected due to the lack of experimental verification).

 The advantages of the proposed method are undeniable: there is no need to extract blood, which is associated with the danger of infection, etc. - the method is sterile, simple, quick, available both in the clinic and individually, the device for its implementation can be either stationary or portable ("pocket-sized" "). Since the effect of UV irradiation of blood is similar to the action of an immune modulator, the spectrum of diseases in which the method can be used is quite extensive - it is adequate to the recommendations given in the book under reference No. 1 (and, as practice shows, is even wider).

Claims (1)

 \ \ \ 1 1. The method of light therapy, which consists in irradiating the patient’s body surface with pulses of light, characterized in that the irradiation is carried out with pulses whose duration is not less than 10 <M ^> - 8 <D> and not more than 10 <M ^> - 2 <D> s \\\ 2 2. The method according to claim 1, characterized in that the irradiation is carried out in the ultraviolet wavelength range of $$$, and the number of irradiation pulses is determined from the formula \\\ 6 $$$ \\\ 1 or approximately from the formula \ \\ 6 $$$ \\\ 1 where $$$ is the "reference" exposure dose of blood irradiation outside the body in the spectral range of $$$, at which the therapeutic effect is achieved; \ \ \ 4 $$$ - transmittance of the medium - the integral transmittance of the skin, tissues, vessel walls; \\\ 4 $$$ irradiation created by pulsed radiation on the surface of the body in the spectral range $$$ \\\ 4 t '<Mv> and <D> - radiation pulse duration (at the level of 0.35 of amplitude). \\\ 2 3. The method according to claim 1, characterized in that simultaneously with the pulsed irradiation, a short-term mechanical compressive effect on the irradiated area in the direction of irradiation is performed with a force of 0.3-0.6 kg / cm <M ^> 2 <D >, terminated at the end of the pulse.