DE10107575A1 - Non-invasive reduction of adipose tissue, useful for therapeutic or cosmetic application, uses the photodynamic effect to kill fat cells - Google Patents

Abstract

Non-invasive method for reduction of adipose tissue, or the proportion of fat in other tissue, of humans or animals, comprises illuminating photosensitizer molecules (I) in, or near, the cells to be destroyed to produce a photodynamic effect that (in)directly kills the cells. ACTIVITY : Anorectic. Samples of cultured white adipose tissue from rabbits were incubated with 5 MicroM pheophorbide a for 24 hours at 37 [deg]C, then irradiated with ultra-violet A (UVA) light for 20 minutes. All cells were dead when examined 24 hours later; compare 90 % survival of cells treated with pheophorbide only and 78 % survival for cells treated with light only. MECHANISM OF ACTION : None given.

Description

Fat cells are created in the human organism at the embryonic stage and are very difficult to dismantle. Each diet only empties the Storage vacuoles of the existing cells, but not for the cell death. If a larger amount of nutrients is added to the organism later, then the cells quickly grow to their original size (yo-yo effect).

A permanent reduction in the number of fat cells was previously only possible surgical intervention possible. However, this is associated with considerable risks afflicted. The strong and very fast loss of substance puts a strain on the Whole organism.

Furthermore, the surrounding tissue must undergo very large changes in shape in a short time compensate for what can lead to significant side effects (holes, etc.). Not finally, a large wound is inflicted on the organism, the one drawn-out healing process.

In addition, surgical procedures can only be used locally and do not allow any general reduction of the body's own fat tissue or the percentage of fat in other Tissue.

Photodynamic therapy (PDT) is a non-invasive method of Photomedicine, previously used to treat tumors, skin diseases and viral or bacterial infections.

Numerous photosensitizers have been tested for their phototoxicity in the past examined and some have already been used successfully. This mainly occurs two mechanisms of action on: 1) destruction of the cell membrane with cell death and the resulting immune response of the organism. 2) release of Cytochrome C from different cell organelles (depending on the accumulation site of the Dye) and the resulting apoptosis without an immune response from the organism. The main interest of the previous PDT was the first mechanism to get the Immune defense of the body with the destruction and elimination of cancer cells included.

A high selectivity of the active ingredient is to reduce the side effects desirable. To achieve this, various have been used in the past Opportunities for tumor therapy suggested: 1. substitution of marginalized groups, in order to obtain a higher affinity for the target tissue, 2. embedding in / coupling on molecular transport systems (e.g. micelles, liposomes, LDL, MAK etc.).  

The object of the invention is a tolerable, non-invasive reduction in fat cells effect that uses natural processes in the body and therefore the Organism less stressed. The slow, continuous and above all homogeneous The effect of photosensitization in the destruction of fat cells makes it possible surrounding tissue to adapt perfectly and an optimal treatment result to achieve.

Cell- or tissue-specific recognition sites or special molecules in the tissue matrix (e.g. leptin in the case of white adipose tissue) or one of the remaining tissue deviating pharmacokinetics for the accumulation of Photosensitizers with or without a carrier system can be used in adipose tissue. On Advantage in treating adipose tissue is that most of the for the organism dispensable fatty tissue lies directly under the skin and is therefore a Exposure is relatively easy (e.g. with laser light). Areas where no Should take effect, can be glued or coated with protective emulsions. Since the exposure is generally made from the surface of the skin mainly fat tissue near the surface destroyed and then by the organism self-disposed. The proposed method mainly involves apoptosis favored (but the cell cannot die off for other reasons), because apart from the nature-identical death of the cell, no other essential indirect Response to treatment is expected.

The actual physical destruction of the fat cells should be (similar to that of a Liposuction) lead to sustainable fat reduction without the risks of one surgical intervention. Because the active ingredient can diffuse through the tissue, a fluid spatial approach to treatment is always ensured.

In addition, with a lower dosage over a longer period of time Self-healing of the organism can be given more time.

Of course, this treatment is also an accompanying measure to surgical Interventions or diets make sense.

Another area of application is the reduction of damage caused by excessive ingrowth of adipose tissue in other types of tissue occurs (e.g. Cellulitis). To our knowledge, this has not been possible to date.

Depending on the type of adipose tissue to be treated, different forms of application are possible:

• - intravenous injection  
• - oral application
• - subcutaneous injection
• - topical application

The first two forms are possible and require a global impact highly selective active ingredients (e.g. through the use of antibodies / fragments) prevent sensitization of other tissues (after the clearing time, d. H. Elimination of non-coupled active substances). A local effect is here to achieve targeted exposure.

The latter two forms come for so-called local use Problem areas in question. In these cases, the requirements for the selectivity of the Sensitizers much lower, since the distribution of the dye is decisive by diffusion.

The effectiveness of the proposed method is to be demonstrated with the following example of the feasibility:
White adipose tissue from rabbits was taken as a plucked preparation for transport in PBS [1], then isolated with collagenase type II (Sigma) according to [2] and cultured according to [3]. 500 µl penicillin (0.5 M IU / 5 ml PBS) on 500 ml medium, 250 µl streptomycin (1,253 g / 5 ml PBS) on 500 ml medium, as antiobiotics and 125 µl of the antimycotic nystatin (0.5 M IU / 5 ml PBS) added.

The batch obtained is divided into four identical samples, with sample 1 as a reference remains, sample 2 is only exposed and sample 3 is only incubated with dye and finally sample 4 is incubated and exposed.

The exposure takes place after the cells have been stored for 24 hours with pheophorbide a (Pheo) [4] at a concentration of 5.10 ^-6 in the medium at 37 ° C.

The sample was then washed twice and, according to [1], with vital staining Trypan blue colored.

The radiation experiments were carried out with UVA (20 minutes) in a 24-well plate. The cells were counted before and after radiation (A) and 24 hours later (B) (Fuchs-Rosenthal counting chamber).

The survival rate of the individual samples was shown in the following overview

The standard deviation is approx. 12%.

It can thus be demonstrated that application has a toxic effect on the cells the PDT is present and that this toxicity is largely due to photosensitization and the singlet oxygen generated with it is caused.

A non-covalent embedding or a covalent one comes as carrier systems Coupling into larger molecules or systems in question.

Suitable liposomes can e.g. B. loaded according to [5]. The use of Liposomes as carriers for the dye resulted in the fat cells examined here comparable results to pure Pheo.

Coupling to biological carrier substances (e.g. antibodies, dendrimers) easily possible if the dye has a carboxyl group. This can be in Dioxane with N-hydroxy-succinimide (succ) in the presence of dihexylcarbodiimide (DCC) can be easily activated. The dye, succ and DCC in the Molar ratio 1: 2: 3 stirred for one day at room temperature, and then with Washed water. The implementation is almost quantitative.

This activated carboxyl group reacts in suitable solvents (depending on what both reactants can tolerate (dendrimers e.g. dichloromethane) within 48 h at room temperature in the presence of small amounts of triethylamine as a catalyst with NH ₂ or SH groups (NH ₂ in the case of DAB-Am dendrimers (Aldrich)) The dye is used in an excess of about 10%. The subsequent separation is due to the changed solubilities (in the case of Pheo and DAM-Am dendrimers, for example in methanol. The coupled pheo fails.) or due to the changed geometric size with the help of dialysis.

literature

[1] Fried, SK; Moustaid-Moussa, N. In: Adipose Tissue Protocols-Methodes in Moleculat Biology. Vol. 155, Chap. 17 Culture of Adipose Tissue and Islated Adipocytes, pp. 197-212, Humana Press: Totowa, New Jersey, 2001.
[2] Rodbell, M. The metabolism of isolated fat cells. I. Effects of hormones on glucose metabolism and lipolysis. J. Biol. Chem. 239: 375-380, 1964. Marshall, S .; Garvey, WT; Geiler, M. Primary culture of isolated adipocytes: a new model of study insulin receptor regulation and insulin action. J Biol. Chem. 259: 6376-6384, 1984. Birguet-Laugier, V .; Quignard-Boulange, A .; Dugail, I; Argeson, AC; LeLiepvre, X; Lavau, M. White adipocytes from young obese Zucker rates maintin excessive lipogenic enzyme activity in long term culture, in Obesitv in Europe 91 (Ailhaud, G .; Gyu-Grand, B .; Lafontan, M. Ricquier, D., eds. ) Libbey, London, pp. 95-99.
[3] Halleux, CM; Dervais, I; Reul, BA; Detry, R .; Brichard, SM Multihormolal control of ob gene expression and leptin secretion from cultured human viscerval adipose tissue: increased responsiveness to glucocorticoides in obesity. J. Clin. Endocrinol. Metab. 83: 902-910, 1998.
[4] Willstätter A., Stoll R .: Studies on chlorophyll, Springer, Berlin, 1913
[5] Kremer, MH; vd Esker, MWJ; Pathmamanohrama, C. Wiersema, PH Vesicles of variable diameter prepared by a modified injections method, Biochem. 16: 3932-3935, 1977.

Claims (23)

1. A method for the non-invasive reduction of adipose tissue or the fat content in other tissues in the human or animal organism, characterized in that the photodynamic effect upon exposure of photosensitizer molecules in, on or in the vicinity of the cells to be destroyed directly or indirectly to their death leads. 2. The method according to claim 1, characterized in that as Photosensitizer molecule tetrapyrrole can be used. 3. The method according to claim 2, characterized in that as tetrapyrrole Chlorophyll and its derivatives are used. 4. The method according to claim 2, characterized in that as tetrapyrrole Pheophorbide and its derivatives can be used. 5. The method according to claim 2, characterized in that as tetrapyrrole Porphyrins, chlorines and bacteriochlorins can be used. 6. The method according to claim 2, characterized in that as tetrapyrrole Porphycene, Texaphyrene or Sapphyrine can be used. 7. The method according to claim 2, characterized in that as tetrapyrrole Phthalocyanines or naphthalocyanines can be used. 8. The method according to claim 1-7, characterized in that the application is mainly medically indicated. 9. The method according to claim 1-7, characterized in that the application mainly used for cosmetic purposes. 10. The method according to claim 1-9, characterized in that for the better Accumulation in the target tissue substituted the photosensitizer molecules become. 11. The method according to claim 1-10, characterized in that for better Accumulation in target tissue carrier systems can be used. 12. The method according to claim 1-11, characterized in that for the better Accumulation in the target tissue Antibodies or fragments can be coupled. 13. The method according to claim 11 and 12, characterized in that for the higher Loading Carrier Molecules Multiplier (molecules that represent the number of am Multiply carrier molecule available coupling sites) used become.   14. The method according to claim 13, characterized in that as a multiplier star Polymers are used. 15. The method according to claim 13, characterized in that as a multiplier Dendrimers are used. 16. The method according to claim 13, characterized in that as a multiplier Polymers with functionalized side chains (e.g. polyvinyl alcohols, Amino acid sequences) can be used. 17. The method according to claim 1-16, characterized in that as a light source mainly natural light is used. 18. The method according to claim 1-16, characterized in that as a light source mainly artificial light including laser light is used. 19. The method according to claim 1-18, characterized in that the exposure and / or active substance application can be carried out several times and in combination. 20. The method according to claim 1-19, characterized in that different Tetrapyrrole and / or carrier systems can be used. 21. The method according to claim 1-20, characterized in that for the better Efficacy diets are used. 22. The method according to claim 1-21, characterized in that for the better Effectiveness physiotherapy is used. 23. The method according to claim 1-22, characterized in that the treatment is combined with surgical interventions.