DE2616892A1 - RADIATION DEVICE FOR TREATMENT OF SKIN DISEASES - Google Patents

Description

2G16892

Patent-Treuhand-Gesellschaft for electric light bulbs mbH, Munich Radiation device for the treatment of skin diseases

The invention relates to an irradiation device for the treatment of skin diseases which is particularly suitable for irradiation of those suffering from psoriasis (psoriasis) and parapsoriasis Persons. The device can be composed of several components that contain one or more structural units.

Psoriasis is a widespread, chronic skin disease that from which 2 to 3% of fair-skinned people suffer and so far could only be treated unsatisfactorily. Only in the last few years has a new treatment method been developed, the successes until the disease was cured. It is a photochemotherapy (Z.Hautkr. 50, issue 14 (1975) i 627-6295 The New England Journal of Medicine 291 (1974), 1207-1211) It was found that irradiation of the patient with long-wave UV radiation in connection with the administration of a special photoactive drug that increases the sensitivity of human Skin for long-wave UV radiation increases, which brought about healing success. It is important that the treatment is not necessarily inpatient, but rather outpatient, can be carried out easily and the patient only has relatively short treatment times must undergo.

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The long-wave UV radiation used for the irradiation should, if possible, have its maximum at 365 nm. There are plants for that Radiation of psoriasis known, in which the radiation from many fluorescent lamps, possibly. of lamps with violet glass bulbs, is produced. The lamps are placed on a horizontal plate. arranged in a tunnel shape or preferably in a cabin that closely surrounds the patient (Arch. Dermatol, Vol. 107, May 1973) The diameter of such booths must be kept small, otherwise, because of the radiant intensity of the fluorescent lamps, they are effective Treatment required dose only after undesirably long exposure times is achieved. Even with such a small irradiation distance, the body shape already plays a role, so that a Uniform irradiation of the whole body is no longer guaranteed «metal halide lamps, which have a greater radiation intensity than Fluorescent lights are also already used for therapeutic purposes Purposes have been used. However, they have not been used to treat skin diseases, but rather to treat hyperbilirubinemia in newborns. Although these lamps, which in this case essentially contained titanium iodide in addition to mercury, Although there is a good yield of radiation between 320 and 500 nm according to its filling, it is used for the stated purpose however, only the strong emission in the blue is exploited by the envelope vessel is coated with a blue-emitting phosphor (US Pat. No. 3,821,576K

The present invention is based on the object of an irradiation device to create the radiation composition required for the treatment of psoriasis with high radiation power and uniform irradiation of the object.

The radiation device for the treatment of skin diseases such as psoriasis, which consists of one or more components, each Component contains one or more structural units, is characterized in that one structural unit is located in a reflector Metal halide burner is used as the radiation source, the apart from mercury as an essential component of the filling, iron

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contains halide, and a filter glass which the UV-A range already has its maximum permeability. In this case, the burner is preferably O Ol ₁ to 1 mg / cm metallic iron, an equivalent to the iron (II) halide amount of halogen and O, OO6 to O, 6 mg / cm tin (IV) halide contained. The filter located in or on the reflector in the direction of emission has a permeability "Z" £ Z O, O3 at a wavelength of λ 3IO nm and

T "£ ^{0.65 at X s} 340 nm. This ensures that ultraviolet radiation emitted by the burner outside the UV-A range (38Ο to 315 nm) is largely filtered out.

For special treatment cases in which no medication is to be administered, it is advantageous if the ultraviolet radiation contains, in addition to UV-A, a proportion of UV-B, that is, radiation with a wavelength between 315 and 280 nm. The medically necessary UV-B component can be achieved by optimizing the position of the passage edge of the filter. Depending on the required UV-B component, the filter located in or on the reflector in the direction of emission must have a permeability of T ^ 0.05 for wavelengths of Λ 270 to 315 nm, and V 0.5 for Λ - 295 to 335 nm at A = 315 to 355 nm T 2 0.8, where the steepness of the absorption edge of the filter is given by the value pairs λ = 28O nm T ^ 0.05 and λ - 34θ nm TiO.75 or λ = 310 nm

T * ^ O, O3 and λ «340 nm *?" IO, 65. The filters can use the Halogen-Met Al! steam burner surrounded as an outer tube or as an outer bulb or provided as a cover plate for the reflector.

In the case of a structural unit corresponds to the maximum value in the case of the spectral Radiation distribution «a radiant intensity of 0.01 W / sr per 5 nm per Watt Power consumption of the lamp. The UV-A radiation intensity (315 to 38Ο nm) is approx. 20 mW / sr per watt of power consumption of the lamp.

The reflector consists of a parabolic trough mirror, des-

2 sen course of curvature in the area between the parabolas y lOOx

and y «7Ox -30. The gutter mirror is opposite the

Verticals by ö (»20 inclined, reflective side panels

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and «it ventilation openings which are arranged in such a way that no unfiltered radiation can escape, as well as the reflector opening final mesh as protection against filter breakage. The metal halide burner is in the Focal line of the reflector arranged

Appropriately, building units are based on the modular principle or components assembled to form an irradiation device. It has proven advantageous to combine three structural units into one component and two components inclined at about 30 to the vertical parallel to each other for partial body irradiation to an irradiation device summarize or to use four components in the manner mentioned for whole-body irradiation. The components can be mobile or stationary and rotatable in all planes, so that the patients can stand, lying or sitting individually or several people can be irradiated at the same time. As a therapeutically necessary radiation dose in the UV-A range (Irradiance χ irradiation time) are given as 1.4 to 4.8 J / cm. This dose can be adjusted with the irradiation equipment according to Invention because of the high radiation intensity of the high pressure burner containing iron halide in the effective UV-A range despite the large Irradiation distance can be realized within short irradiation times.

In the figures 1 to 7 embodiments of the irradiation device according to the invention are shown.

In FIG. 1 there is one structural unit, in FIG. 3 one of three structural units existing component shown.

Figure 2a and b shows the trough mirror of the unit.

FIG. 4 shows the spectral transmittance of the filter glass or glasses again.

The spectral distribution of the radiation intensity is from FIGS. 5 and 6 the individual structural units of the device with different filters can be seen.

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A device consisting of four components is shown in FIG. each component containing three structural units.

The structural unit shown in FIG. 1 consists of the metal halide burner 1, the trough mirror 2 and the filter glass 3, which can be seen in FIG cm and is filled with about 30 mg of mercury, 0.5 mg of metallic iron and an amount of iodine equivalent to the iron (II) halide, 1 mg of tin (IV) iodide and 20 Torr of argon as ignition gas. The burner is operated with 3 »5 A at 125 V and a power consumption of 400 V. The burner is arranged in the focal line of the trough mirror 2. FIG. 2a shows the gutter mirror 2 in side view, FIG. 2b in section along the line AB. The trough mirror is designed in such a way that a uniform irradiance is achieved on the irradiation site at a distance of 0.5 to 2 m from the structural unit. For this purpose, the reflective side parts 4 of the trough mirror are inclined to the vertical at an angle oC, for example eC »20. The course of the curvature of the polished aluminum anodized, hammered trough mirror, shown in section along the line AB, lies

2 2

in the area between the parabolas y «100x and y = 70x -30. Of the The gutter mirror can be manufactured using a deep-drawing or casting process. To attach the burner 1, there are sockets on the gutter mirror 5 provided. The openings 6 ensure the necessary ventilation of the gutter mirror. The aperture 7 should possibly be on the side Cover the radiation emerging through the ventilation slot 6. A wire mesh (not shown) with a mesh size of 10 χ 10 mm and a wire thickness of 0.5 mm below the filter 3.

As di »- Figure 3 shows, depending on the partial or full body irradiation several building units used. The structural units are in preferably cuboid metal or plastic housings 8 summarized. Devices with 3 or 4 units are advantageous proven. The distance between the burners is

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preferably 0.34 to 1.3 ^m · With these arrangements, a uniform illumination of the irradiation area is achieved.

FIG. 4 shows the spectral transmittance of the filters. Should the system only emit radiation in the UV-A range (38O - 315 no), a filter glass known under the trade name Sekurit is used (corresponding to curve 1) with a thickness of preferably 4.5 mm (arrangement a). But if a certain amount of UV-B radiation (315 - 280 only) is required, all of them are suitable Filters with a permeability between curve 1 and curve 2. Particularly suitable in this area are those under the Trade name VG 295 (thickness 5 mm) and under the trade name Sanalux (Thickness 3-5 mm) known filter glasses (arrangement b) proved. filter with greater transmittance at 280 nm should be harmful because of the The effect of short-wave radiation below 280 nm (UV-C) can be avoided.

The following table shows the radiation intensities in W / sr of the structural unit according to the invention for a power consumption of the halogen metal ! Steam burner of 400 W and 2OOO V reproduced:

Spotlights 4oo W arrangement
b
<: o, oi
o, 4
8th
12th 2000 ν arrangement
b
<O, l
2.4
48
75 Filter glass
5 ========= sssss3XSs:
UV-C (<28O nra)
UV-B (28O-315 nm)
UV-A (315-380 nra)
Jj " ⁰ *" (315-400 nm) arrangement
a
<0.001
-CO, 02
7th
11 arrangement
a
-CO ₁ OOl
^ 0.1
4O
67

Figure 5 shows the spectral radiation intensity distribution of the arrangement a, FIG. 6 that of the arrangement b, for a 400 W unit. As can be seen from the figures, the spectral radiant intensity is determined by the selection of the filter hardly influenced in the UV-A range and in the blue spectral range. On the other hand, there is a difference between the two distributions in the UV-B region to recognize. According to FIG. 5, there is practically none in the arrangement a

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8 42 / C

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-7-

Arrangement b

UV-B radiation is present, while according to FIG. 6 in the arrangement a proportion of UV-B radiation which is desirable for special cases is emitted. After knowing the radiation intensity in the UV-A range, the UV-A radiation intensity can be calculated at a given distance, for example on a couch, calculate with the help of the known laws of radiation physics.

FIG. 7 shows an advantageous embodiment of the irradiation device evident. The arrangement of four components 91 of each of which contains three structural units, in two mutually inclined planes, there is also an irradiation of the lateral surfaces of the object enables.

- patent claims -

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Claims (12)

Claims 1.) Irradiation device for the treatment of τοπ skin diseases like the Psoriasis, which consists of one or more components, each component containing one or more structural units, thereby characterized in that a metal halide burner located in a reflector is used as a radiation source in a structural unit is used, which contains iron halide as an essential component of the filling in addition to mercury, and a filter glass that already has its maximum permeability in the UV-A range. 2. Irradiation device according to claim 1, characterized in that the burner 0.01 to 1 mg / cm metallic bison, an amount equivalent to the iron (II) halide of halogen and O, OO6 bis Contains 0.6 mg / cm of tin (IV) halide. 3 · Irradiation device according to claim 1 and 2, characterized that that is located in or on the reflector in the direction of emission Filter at a wavelength of λ »310 nm Transmittance of T ^ 0.03 and at λ ■ 340 nm of Ti has 0.65. 4. Irradiation device according to claim 1 and 2, characterized in that that the filter located in or on the reflector in the emission direction at wavelengths of λ ■ 270 to 315 nm Transmittance of T "^ 0.05, at λ» 295 to 335 nm of T - 0.5 and at λ * 315 to 355 nm T 2: 0.8, where the steepness of the absorption edge of the filter is given by the value pairs Λ = 280 nm T ^ 0.05 and Λ = 340 na r ^ O, 75 or λ = 31Ο nm T "4iO, O3 and λ = 340 nm 70914.2 / 0531 ORIGINAL INSPECTED 5 · irradiation apparatus according to claim 1 to 4, characterized in that the assembly emits radiation with a spectral distribution corresponding to the figure 5, wherein the maximum value of a radiant intensity of about O ₁ Ol W / sr per 5 nm per watt lamp power consumption corresponds and the UV-A radiation intensity (315 to 380 nm) is approx. 20 mV / sr per watt of power consumption of the lamp. 6. Irradiation device according to claim 1 to 5, characterized in that that the reflector of a structural unit from a parabolic There is a gutter mirror whose curvature is in the area between 2 2 the parabolas y * 100x and y ■ 70 * -3 ° and the opposite with reflective side parts inclined by O ^ = 20 from the vertical is provided. 7 · Irradiation device according to claim 6, characterized in that the burner is arranged in the focal line of the trough mirror. 8. Irradiation device according to claim 6 and 7i, characterized in that that ventilation openings are provided on the gutter mirror, which are arranged in such a way that no unfiltered radiation can escape. 9. Irradiation device according to claim 6 to 8, characterized in that that the gutter mirror is provided with a mesh grid at its opening. 10. Irradiation device according to claim 1 to 9, characterized in that that the units can be assembled according to the modular principle. 11. Irradiation device according to claim 1 to 10, characterized in that that a component consists of three structural units. 709842/0531 12. Irradiation device according to claim 1 to 11, characterized in that that the device consists of four components, each with three structural units. 13 * irradiation device according to claim 1 to 12, characterized in that that the device is mobile or stationary and rotatable in all planes. Dr.Hz / Wb 709842/0531