DE3326513A1 - RADIATION DEVICE FOR PHOTOBIOLOGICAL AND PHOTOCHEMICAL PURPOSES - Google Patents

Abstract

Irradiation apparatus, particularly for dermatological applications, wherein are provided a plurality of filters (6, 7, 8, 9) assembled in sets of filters, the filters of each set of filters being connected in order to be simultaneously operated and which may be alternatingly inserted in the path of the beams. It is thus possible, by choosing appropriate filters, to execute different therapeutic treatments and diagnoses with the same apparatus.

Description

Irradiation device for photobiological and

photochemical purposes The invention relates to an irradiation device (according to the preamble of claim 1) for photobiological and photochemical Purposes, especially for dermatological purposes.

For dermatological purposes there are several, using ultraviolet radiation working diagnostic and therapeutic procedures known.

In the so-called SUP therapy (selective UV therapy), dermatoses, especially psoriasis, through UV radiation in the wavelength range between 290 and 335 nm, in particular between 300 and 320 nm, treated, in general begins with irradiation times that do not yet cause erythema.

While the SAE therapy works without medication, the PUVA therapy (for the treatment of dermatoses, especially psoriasis) a photosensitizing The drug is administered orally or applied to the skin, followed by radiation with UV-A in the wavelength range between 310 and 440 nm. The photosensitizing one The drug is used to make the skin more sensitive to long-wave UV-A radiation close.

The SUN diagnosis becomes a photo test (polymorphic light dermatoses) as well used for the photo patch test. The SUN therapy is used to compensate for a radiation deficit. SUN diagnosis and therapy are carried out in the UV wavelength range between 300 and 440 nm. It is essential that no DNA damage from radiation between 440 and 460 nm be evoked.

The UVA diagnosis works with UV radiation in the wavelength range between 320 and 440 nm.

It enables a photo patch test without carcinogenic radiation. Here, too, DNA damage caused by radiation between 440 and 460 nm is avoided.

UVA therapy (in the same wavelength range mentioned above between 320 and 440 nm) is used for photoprotection (pigmentation, protection against polymorphic photodermatoses, skin cancer and premature skin aging) as well as for photoreactivation (Monomerization of the pyrimidine dimers in DNA).

For these various UV therapy and diagnostic procedures are available so far separate equipment is required, which is a considerable expense for doctor and clinic represents and also an undesirably large amount of space in the treatment rooms caused.

The invention is therefore based on the object of an irradiation device the prerequisite in the preamble of claim 1 type so that it is without special operating effort can be used for various purposes.

According to the invention, this object is achieved by the characterizing features of claim 1 solved.

By using n. M filters, which are combined into n filter groups are, the in filters of each filter group connected for common actuation and, alternatively, can be inserted into the beam path, a large number of Manufacture filter combinations.

For example, if four filters are provided, two in pairs Filter groups are combined, so four filter combinations can be made by inserting a filter from both filter groups into the beam path will.

With three filter groups with three filters each, there are already 27 filter combinations possible.

This opens up the possibility for doctors and clinics to use help a single irradiation device that contains only four filters, the pairs The four common filter groups mentioned at the beginning are combined to form two filter groups Carry out diagnostic and therapeutic procedures.

To switch from one to the other mode of operation is included no more required than the individual filters in the beam path slide in or swivel in. This not only results in an essential one Reduction of the investment costs, but also a considerable reduction in space requirements and - due to the better utilization of the device - a reduction in ongoing operating costs.

Appropriate refinements of the invention are the subject of the subclaims and are illustrated in connection with the description of one in the drawing Embodiment explained in more detail.

In the drawing, FIG. 1 shows a schematic vertical section through an irradiation device according to the invention, FIG. 2 is a longitudinal horizontal section the line II-II of Fig.1, Fig.3 a diagram showing the spectral transmittance of the four filters used is illustrated, FIG. 4 is a diagram showing the spectral Shows the transmittance of the four filter combinations a one diagram the spectral irradiance distribution of the UV radiation source, Fig. 6, 7, 8 and 9 diagrams of the spectral irradiance distribution for the 4 filter combinations.

The irradiation device illustrated schematically in FIGS for dermatological purposes contains some UV radiation sources in a housing 1 2, 3, 4, which are formed by high-pressure mercury vapor emitters with metal halides, are preferably doped with iron iodide.

The UV radiation sources 2, 3 and 4 are surrounded by a reflector 5, which allows the radiation to pass through a window of the housing 1, before there is a filter assembly.

This filter arrangement contains in the illustrated embodiment four filters 6, 7, 8 and 9, which are paired to two filter groups (6 and 7 as well as 8 and 9) are combined.

The two filter groups 6, 7 and 8, 9 are within a fixed one Frame 10 on rollers 11 in the horizontal direction so that each two filters of the two filter groups lie one behind the other in the beam path (at The filters 7 are in the position of the filters illustrated in FIG and 8 in the beam path of the UV radiation sources).

To move the filters are suitable, not shown in the drawing illustrated operations are provided. Provide markings and position indicators the user an unmistakable indication of which filter combination is currently switched on.

The UV radiation sources 2, 3 and 4 are cooled by a Air flow from a fan 12 in the direction of arrows 13 through the reflector 5 provided openings into the interior space enclosed by the reflector 5 from below enters, leaves this interior space in the upper region of the reflector 5 and from the rear area 15 of the housing 1 through openings not shown to the outside flows off.

Another fan 16 generates a flow of cooling air that flows into the Space 17 occurs between adjacent filters (e.g. 7,8) of the two filter groups, flows through this space in the direction of arrows 18 from bottom to top, and then out to exit the upper region 19 of the housing 1 to the outside. That way will a good cooling of each filter switched on in the beam path is guaranteed.

The necessary ballasts are in the base 20 of the housing 1 housed.

3 illustrates the spectral transmittance of the filters 6 to 9 for the following practical design: Filter 6: Plexiglas No. 2058 (Röhm) 6 mm thick filter 7: Uvacryl-Clear (Fa. Mutzhas) 6 mm thick filter 8: Tempax (Fa. Schott) 3.5 mm thick filter 9: Uvisol (Desag) 3 mm thick The spectral transmittance # as a function of the wavelength λ is in Fig. 3 for the filters 6 to 9 through the corresponding curves 6 to 9 are reproduced.

By different combinations of these four filters you can use it the following dermatological treatments are carried out: Filters 6 + 8: SUP (selective UV phototherapy) Filter 6 + 9: SUN (solar UV and near infrared radiation) filter 7 + 8: PUVA (photochemotherapy with UV-A radiation) Filter 7 + 9: UVA (radiation with UV-A) Fig. 4 illustrates the resulting spectral transmittance, which is connected in series by superimposing the transmission curves of the two Filter results. The corresponding curves in FIG. 4 are identical to that from the preceding Listed treatment method.

5 also shows the spectral distribution of the relative spectral Irradiance E (rel) of the high-pressure mercury vapor lamps used (with Iron iodide doping).

FIGS. 6 to 9 show the four filter combinations explained the spectral distribution of the relative spectral irradiance. She surrenders by superimposing the curves according to FIGS. 4 and 5.

6 SUP, 7 SUN, 8 PUVA, and 9 UVA - Blank page -

Claims (6)

Claims: Irradiation device for photobiological and photochemical Purposes, preferably for dermatological purposes, containing at least one ultraviolet radiation source as well as filters arranged in the beam path, characterized by the following features: a) n m filters (6, 7, 8, 9) are provided, which are combined into n filter groups are; b) the in filters of each filter group are connected for common actuation and alternatively insertable into the beam path; c) the n filter groups are in the beam path arranged one behind the other and operable independently of one another. 2. Irradiation device according to claim 1, characterized in that four filters (6, 7, 8, 9) are provided, which in pairs form two filter groups (6, 7 and 8, 9) are combined. 3. Irradiation device according to claims 1 and 2, characterized by the following filters: a) in the first filter group a1) a filter (6) with a spectral Transmittance according to Figure 3 (curve 6), a2) a filter (7) with a spectral Degree of transmittance according to FIG. 4 (curve 7), b) in the second filter group b) a Filter (8) with a spectral transmittance according to FIG. 3 (curve 8), b2 a Filter (9) with a spectral transmittance according to Figure 3 (curve 9). 4. Irradiation device according to claim 1, characterized in that the filters of each filter group can be pushed or swiveled alternatively into the beam path are. 5. Irradiation device according to claim 1, characterized in that the radiation source by at least one with metal halides, preferably is formed with iron iodide, doped high pressure mercury vapor lamps. 6. Irradiation device according to claim 1, containing at least one Fan for air cooling of the radiation source and the filter, characterized in, that the space (17) between adjacent filter groups is a flow space for the Forms cooling air.