DE4228106A1 - Tumour diagnosis and treatment in organs, esp. urinary system - comprises admin. of gamma-amino-levulinic acid as photosensitiser, detection, and treatment by irradiation with neodymium-yttrium-aluminium-garnet laser - Google Patents

Abstract

Integral diagnosis and/or therapy or tumours in hollow organs comprises topical admin. of gamma-aminolevulinic acid (ALA). Detection is effected by irradiation with light of wavelength 390-430 nm, pref. 410 nm, which causes tumours to fluoresce. A krypton ion laser is pref. used for this purpose. Therapy is by irradiation with light of wavelength 600-650 nm, pref. 630 nm, esp. using a neodymium-yttrium-aluminium-garnet (Nd:Yag) laser. Admin. is e.g. by inhalation into the bronchial system, topically to the cervix, instillation into the peritoneal cavity and topically or by instillation in the case of the bladder. USE/ADVANTAGE - Used esp. to detect and treat tumours (including cancerous and precancerous lesions) of the respiratory tract, peritoneal cavity, gastrointestinal tract, female genital tract and partic. urinary tract. The method enables the detection of early cancerous conditions which cannot be detected by endoscopy, thus reducing relapse and progression rates. Further, the method is more effective than procedures involving the i.v. admin. of porphyrin photosensitisers. In partic., because ALA has higher tumour selectivity (tumour to healthy tissue uptake = 20:1 compared with 2-5:1 for porphyrins), results can be evaluated visually rather than by computer-generated imaging and phototoxic side effects do not occur.

Description

The invention relates to the use of δ-aminolevulinic acid (ALA) for the manufacture of a topical drug for integra len diagnosis and / or therapy of tumors in hollow organs.

Malignant tumor diseases in hollow organs, such as Urinary and respiratory tract, peritoneal cavity, gastrointestinal tract and female genital tract, are characterized by high relapse and Progression rates. These are already in sync existing precancerous and cancerous changes (Frühkar zinome), which cannot be diagnosed endoscopically and therefore in cannot be treated at an early stage.

For example, in early bladder cancer Relapse and progression rates up to 90%. A potential Degeneration in the area of the entire bladder mucosa is therefore too postulate. The precancerous and cancerous changes, such as for example severe urothelial dysplasia, carcinoma in situ and multifocal micropapillary tumors, can not endcopically or are very difficult to recognize.  

A prerequisite for curative treatment is to comprehensively recognize all tumor areas, on the other hand there is one complete and integral treatment of the entire bladder mucous membrane required.

None of the diagnostic methods known to date is in the It is able to completely and specifically target tumor areas even in the early stages detect. So far for the therapy of the bladder mucosa Drugs (cytostatics, BCG) instilled in the bladder. Though the recurrence intervals can be extended in this way, a final cure is within the scope of those known so far Therapy methods, however, not possible (J. Urol. 1987, 138, 1363- 1368).

As an alternative to conservative diagnostic and therapeutic methods photodynamics is used. It is based on light absorption by a chemical compound, the so-called Photosensitizer, leading to fluorescence emission leads, which can be used for diagnosis and on the other hand produces a cytotoxic response that is necessary for the therapy of Benefit is.

In the context of photodynamics, photosensitivity is currently used porphyrin mixtures of different compositions used, which must be administered intravenously.

The intravenous application of such photosensitizers has two major disadvantages.

On the one hand, it leads to an enrichment of the porphyry mixtures in the entire skin and thus triggers a light exposure phototoxic reaction, which takes the form of redness, Swelling and erosion of the skin and pain. The Patients are therefore forced to stay for several weeks before protect from strong light; practically means one  such diagnosis or therapy for the person concerned months of stay in darkened rooms!

On the other hand, the low tumor-selective enrichment of the Porphyry mixtures the efficiency of a fluorescence detection crucial one. This difference in fluorescence has so far only been possible with complex computer-aided image analysis systems because it is not visible to the naked eye.

Furthermore, the therapeutic benefit is administered intravenously Photosensitizers also due to the low tumor selectivity tivity limited, and there were local side effects conditions such as shrink blistering.

It is accordingly an object of the invention to provide connections to the Her to provide a medicinal product that a integral diagnosis and / or therapy of tumors in hollow organs, preferably in the bladder, allow the disadvantageous Properties of the substances previously used, however, are not exhibit.

To solve the problem, the use of δ-aminolevulinic acid re (ALA) for the manufacture of a topical drug for integral diagnosis and / or therapy of tumors in hollow organs suggested.

ALA is a precursor to protoporphyrin IX in the formation of the Blood pigment (heme biosynthesis) generally known. The previous clinical use of ALA was limited to certain Metabolic diseases (porphyrias), where, however, it turns out to be proved unsuccessful. For example, Okuda et al. (Hepatology 1991, 14, 1153-1160) from the treatment of patients with Gilbert syndrome (Behcet's disease) and healthy subjects.

ALA is harmless as a substance. With intravenous administration of No toxic reactions were observed at 0.23 mg ALA (Okuda  et al., Hepatology 1991, 14, 1153-1160, cf. also Kennedy et al., J. Photochem. Photobiol. B., 1990, 6, 143-148). After Berlin et al. (Biochem. J. 1956, 64, 80-90 and 90-100) were found in healthy Subjects at higher doses phototoxic reactions observed only for 1 to 2 days. As part of various Animal toxicity studies (Lima et al., Can. J. Neur. Sci. 1981, 8, 105-114; Arnold et al., Food Cosmet. Toxicol. 1975, 13, 63-68; Kennedy et al., Ibid 1976, 14, 45-48) could not negative symptoms regarding direct toxicity, photosensiti vity, theratogenicity or subacute toxicity are observed.

The recent topical use of ALA in the treatment of superficial skin tumors (especially basaliomas), see. Kennedy et al., (J. Photochem. Photobiol. B., 1990, 6, 143- 148), only affects the visually recognizable tumors, which are locally brought into contact with the substance.

The effect of ALA is based on the stimulation of the body's own Porphyrin formation. The use according to the invention is the surprising finding that ALA is topically integral Application to the mucous membranes of hollow organs selectively from Tumor-diseased tissue is absorbed and enriched and only there to an increased porphyrin formation and concentration leads while the healthy tissue is essentially unaffected remains. It has been shown that according to the invention the enrichment ration factor compared to healthy tissue is up to 20: 1 the result that the fluorescence of the tumor or pretumor islets can be seen even with the naked eye. On the previously necessary elaborate image processing systems can be dispensed with become.

Unlike the previously known applications, ALA according to the invention not specifically targeted at those to be treated detected tumors, but it becomes the whole thing Hollow organ lining mucous membrane homogeneously wetted. Through the tumor-selective storage of ALA fluoresce in successors  the integral radiation of the urinary bladder is only tumorous Lesions (diagnosis) or are destroyed (therapy).

Compared to the previously known methods for diagnosing tumors in hollow organs that are visual in advanced stages limited visible tumors, has the invention Using ALA key benefits. The one at instillation of ALA in hollow organs, such as B. the bladder taking place selective accumulation in the tumor tissue is expressed in comparison to previous therapy approaches in a much higher difference factor gates against healthy tissue. While with the so far described intravenous applications of porphyrin derivatives, which were used as undefined mixtures for diagnostics, Difference factors from 2 to 5: 1 between tumor and healthy Tissues were observed, the difference factor is in Compared to healthy tissue in the integral treatment of Urinary bladder, for example, 20: 1. By using it when irradiated The strong fluorescence associated with tumorous tissue is successful for the first time the diagnosis of precancerous lesions that have been endoscopic so far were not recognizable.

The side effects of photosensitization in intravenous So far, application of photosensitizers has been practical a patient's stay in darkened for months Made rooms necessary, occur in the invention Do not use ALA for integral treatment of the bladder on. Furthermore, complicated image processing systems can be used No diagnostics due to the improved differential factor become.

By stimulating the body's porphyrin formation as a result the tumor-selective absorption when used according to the invention ALA can not only detect early bladder cancer be (integral fluorescent label), but it can be through subsequent integral radiation to the bladder selectively tumorous lesions are destroyed (integral therapy). In order to  stands for the first time a therapy for precancerous and cancerous Lesions are available due to the lack of Possibility of diagnosis in the early stages of the disease were not treated. So far for z. B. Bladder tumors observed recurrence and progression rates can be Use of ALA according to the invention for diagnosis and / or Decrease therapy significantly.

The use of ALA according to the invention is for diagnosis and / or therapy of hollow organs such as urinary bladder (urinary tract), Respiratory tract, peritoneal cavity, gastrointestinal tract or female Genital tract suitable, with the urinary bladder being preferred is coming.

The application to the bladder can either topically in done travesical or in a preferred embodiment by instillation of a pH neutral, i.e. H. the physiological pH of about 7 corresponding ALA solution, which with sodium bi carbonate is buffered.

The hollow organ is diagnosed with light of wavelength 390 to 430 nm, preferably 410 nm, irradiated integrally, so that tumorous Lesions fluoresce. In a preferred embodiment a krypton ion laser for integral diagnostic radiation used.

In order to destroy the tumorous lesions, the use of ALA according to the invention integrally with the hollow organ Light of the wavelength 600 to 650 nm, preferably 630 nm, integrally irradiated. Preferably comes with the therapeutic local irradiation using a Nd: Yag laser (neodymium: yttrium aluminum Garnet laser).

The invention is explained below using examples.

example 1

The use of ALA for the manufacture of a topical drug means for the integral diagnosis and / or therapy of tumors in Hollow organs were extracted from a chemically induced rat urinary Tumor model checked. The following results were obtained:

• 1. When a 3% pH-neutral solution buffered with sodium bicarbonate is instilled, the protoporphyrin synthesized by ALA can be clearly detected on the opened rat urinary bladder ( FIG. 1).
• 2. The ratio of the fluorescence intensity between tumor and normal tissue is 20: 1 ( Fig. 1).
• 3. The fluorescence is detectable at a depth of several mm based on the evaluation of frozen sections ( FIG. 2).
• 4. Necrosis can be generated after irradiation with light of wavelength 630 nm. This requires at least a 10% concentration ( Fig. 3).

These results were in both diagnostics and therapy can be achieved with an exposure time of only 2 to 4 hours. in the In contrast, the necessary incubation time is at systemic intravenous photosensitizers at least 48 hours.

Example 2

In 20 patients, ALA was administered in the form of a 3% pH-neutral, with sodium bicarbonate buffered solution into the bladder instil liert. The cytoscopy (blisters reflection) under violet light (krypton ion laser with the Wavelength 410 nm). Everyone showed in the purple excitation light  tumorous lesions a strong, problem-free with the naked eye recognizable red fluorescence. Reinforcing computerized Image analysis systems were not necessary.

Trial biopsies (40 biopsies in total) were performed in all patients. from fluorescence-positive and fluorescence-negative areas taken. For the evaluations available in 16 patients the fluorescence was corrected with the histological evaluation and no false negative result could be found become. The process is characterized by a 100% Sensitivity, no tumor was overlooked.

The clinical studies showed that an orientation in the bubble with permanent homogeneous violet lighting in the same Extent as possible under normal white light lighting. In addition, the vessels are displayed in higher contrast, due to the high absorption of violet light in the Blood pigment.

Example 3

In a 55 year old patient, the first in 1990 Diagnosis of a bladder tumor was made in brief Intervals repeated recurrence tumors. The patient came with that fifth relapse for treatment. With the photodynamic Diagnostics found numerous micropapillary tumors that normal cytoscopy with white light was not recognizable, so that the previous relapses are inadequate and not full treatment had to be blamed. The fluo Resence-labeled tumors were now clear and full constantly verified by the red fluorescence and were in same session with the Nd: YAG laser (Nd: yttrium aluminum Garnet laser) thermocoagulated and completely destroyed.  

Example 4

A 68 year old patient has had recurrences since 1988 en Bladder tumors detected. Due to cytological sub the patient suspected that there would be another Bladder tumor recurrence. Three urinary bladders performed so far reflections had shown no tumor evidence. In the performed photodynamic diagnostics under fiction According to the use of ALA, a micropapillary was easy Verify the carcinoma in the area of the bladder roof. This was also thermocoagulated with the Nd: YAG laser.

Example 5

A 72-year-old patient was diagnosed with recurrent carcinoma in situ of the bladder. The tumor lesions could not be recognized endoscopically in the inconspicuous bladder mucosa, but showed a high fluorescence contrast when using photodynamic diagnostics using ALA. This was documented with an image intensifier camera ( Fig. 4).

Example 6

A 67-year-old patient was diagnosed with recurrent bladder carcinoma with carcinoma in situ. The patient also had a small papillary tumor. For therapeutic purposes, after instillation of a 10% pH-neutral ALA solution buffered with sodium bicarbonate in the urinary bladder, integral radiation with laser light of wavelength 630 nm was carried out. The total dose was 15 J / cm ² . In the control cystoscopy after 10 days, no papillary tumor was detectable. With regard to carcinoma in situ, no statement could yet be made since the required follow-up period of at least three months had not yet been reached in this patient.

Claims (4)

1. Use of δ-aminolevulinic acid for the preparation of a topical drug for integral diagnosis and / or Therapy of tumors in hollow organs. 2. Use according to claim 1, characterized in that the Hollow organ from the group consisting of urinary tract, respiratory tract, Peritoneal cavity, gastrointestinal tract or female geni taltrakt is selected. 3. Use according to claims 1 and 2, characterized records that the drug as the δ-aminolevulinic acid Contains solution with a physiological pH of about 7. 4. Use according to claims 1 and 2, characterized records that the drug for instillation formu is.