DE4201461A1 - Agent for selective hyperthermia and chemotherapy of tumours - consists of ferromagnetic particles encapsulated in matrix which is not phagocyted and is able to couple with antitumour agent - Google Patents

Abstract

A therapeutic agent (I) for selective tumor therapy comprises ferromagnetic particles with a Curie temp. of 42.5-70 deg.C and particle size below 500 nm encapsulated in a polymer or bipolymer matrix which is not phagocyted by the reticuloendothelical system and which has reactive gps which couple with tumor cell targetting active ingredients. The polymer layer is of starch, polyvinyl alcohol, polyacrylanide, dextra, agarose or gelatine. The ferromagnetic particles are themselves encapsulated in liposomes (vesicles) of phospholipids, sphingolipids, glycosphingolipids, ceramids or other substances that make up cell membranes. USE/ADVANTAGE - (I) can be used for selective hyperthermia and chemotherapy in tumor therapy. (I), unlike previous agents is able to generate sufficient heat and is also suitable for the treatment of deep-lying tumors, as the ferromagnetic particles are coupled with the cytostatic active ingredients. As the whole is then encapsulated in the polymer matrix, normal tissue does not come into direct contact with the tox

Description

The present invention relates to ferromagnetic Microparticles with a Curie temperature between 42.5 and 70 ° C and a particle size <500 nm, which is inductively exact up to can be heated to the Curie point and alternatively in combination with tumor toxins simultaneously for selective hyperthermia and Chemotherapy can be used as part of tumor therapy can.

The tumor therapies predominantly practiced today come from consistently from the field of chemotherapy and radiation therapy. Both methods, which can be described as classic, were in the has been the subject of intensive research in recent years with the aim of through improved medication or radiation techniques to achieve more effective and, above all, more selective therapy, to thereby reduce the sometimes blatant side effects of Lessen treatments. Despite various improvements Both methods are relatively radical methods to date hardly allow between healthy and sick Discriminate against tissues. The consequence of this is that the significant side effects such as hair loss, vomiting, Dizziness attacks etc. are still hardly controlled. Because of the enormous drawbacks that these procedures involve bring, they tried early on, alternative To design procedures. In this context they are Developments in the field of oxygen multi-step therapy, Acidification therapy, immunotherapy and hyperthermia too name that also found its way into medical practice to have. These are the main processes Hyperthermia and immunotherapy as promising Approaches turned out to be.

The starting point for hyperthermia is the fact that Cancer cells are more sensitive to heat due to their higher metabolic rate are as healthy cells. In practice, that means that the tumor cell already with artificial heating dies at a temperature above 42.5 ° C, while the normal cells survive under these conditions. This Fact is now used in hyperthermia in that attempts are being made to artificially create tumor tissue at over 42 ° C  to heat up. In practice, hot baths, Treatments with hot waxes, creating artificial ones Fieber and recently microwaves, induction heating and Ultrasound used. The main problem with all hyperthermia Treatments consist of having enough energy before to transmit all underlying tumor areas. Except from the sometimes considerable physical strain that the warming that comes with it becomes the Available heating systems hardly penetration depths of more than 7 cm (JAMA, 252, 3341, 1984), so that the deeper tumor cells do not lie on the threshold value of <42.5 ° C can be brought, d. that is, these cells survive under these conditions and can proliferate. To this To avoid the problem of insufficient heat focusing alternatively you try. Surgical needles in the metal To implant tumor focus (IEEE Trans. Biomed. Eng., 31, 227, 1984), which are heated up by means of a radio transmitter. To However, this procedure has had a breakthrough to date not led. The current trend is rather hyperthermia as an adjuvant procedure in combination with others Therapies, e.g. B. chemotherapy. It seems proven to be chemotherapy drugs in combination with hyperthermia have a higher response rate than Cytostatics alone (Tanaka et al., Cancer J., 4, 193, 1991; Akuta et al., Int. J. Hyperthermy, 7, 231, 1991).

The object of the present invention is a to develop new hyperthermia procedures, on the one hand the previous disadvantages of insufficient heating power eliminated and on the other hand for the treatment of deep Tumors is suitable.

Surprisingly, this object can be achieved by a method which uses ferromagnetic particles (FMP) which have a defined Curie temperature. Means for this are microparticulate FMP with a size of <500 nm, which consist of a certain alloy composition and have a Curie point between 43 and 70 ° C. Alloys of this type are known from DE-OS 35 02 998. These are metal alloys of the ferrite type of the general formula Me₁- _x Zn _x Fe₂O₄, where Me is preferably cobalt or nickel. The Curie point can be set precisely by varying the cobalt or nickel content. Such alloys and processes for their preparation are generally known (J. Smit; HPJ Wÿn, "Ferrites", Wiley, New York, 1959). In addition to these compounds, alloys of the MgCrFeO₄ type which have Curie temperatures around 50 ° C can also be used.

In DE-OS 28 28 941 Fe (III) hydroxide and Fe oxide are Particles with a size of up to 1 µm are described, which, in the Body injected, then inductively heated can. The goal there is with the help of inductively heatable Particles heat so selectively to the tumor cells transferred that a temperature of over 42 ° C is reached, which will eventually kill the tumor cells. The method described has a number of basic ones Defects and is therefore hardly suitable for selective selection of tumor cells to heat up. Firstly, the iron compounds used only very much by means of the applied induction fields heating up uncontrollably - a disadvantage in this physiologically sensitive area is serious - to others are unlikely to be able to get particles of one size by 1 µm, administered intravenously, to the site of the tumor conduct. The impracticability of this procedure is because the blood vessels with a Endothelial cell layer are lined, which diffusion prevent such large particles from entering the body. In addition, the proposed method is the particles to be loaded with toxins or radioisotopes, not suitable, Detect tumor cells specifically, as these are non-specific Fundamentally not between a tumor cell and discriminate against a healthy cell. The same applies also for the tumor antibodies described there. The up Antibodies produced today do not have 100% Tumor specificity (Seiler et al., Angew. Chemie, 97, 141, 1985). In this respect, the method described is not how claimed, generally practicable. The most serious disadvantage However, the procedure cited is that none Measures are listed or described that are suitable  would be the phagocytosis of the injected particles by the bypass reticuloendothelial system (RES). It is known, that phagocytes, especially macrophages, such particles eliminate within minutes and thus render it ineffective. This fundamental problem is also with that in the DE-OS 35 02 998 described methods of selective hyperthermia not solved by FMP. FMP are used here with polymers coated, to be coupled to the tumor AK, which as carrier should act to the location of the tumor. The one there used particle sizes of 0.5-1 microns and the specified Coatings are also not suitable Work around the elimination mechanism of the RES.

Surprisingly, this disadvantage can thereby be eliminated be that one

• a) too fine particles with a size of less than 500 nm, preferably between 10 and 100 nm, and
• b) these particles specifically with such polymers or bioactive substances coated that none Have affinity for the macrophages of the RES, d. i.e. from these are not recognized as foreign.

Another measure to bypass macrophage phagocytosis is by the Use of the Fab or F (ab ') ₂ fragments of the AK instead of the intact molecule, which is achieved by the Fc fragment of the AK mediated phagocytosis is switched off. For this reason, the coatings of the FMP are included tumor-specific AK, as in the cited patents described, unsuitable for circumventing the phagocytosis of the RES.

FMP with a size between 10 and 500 nm can be used with the known wet process by failure of the corresponding Connections are made. Such procedures are u. a. described in DE-OS 35 08 000. A offers further possibility for the production of these particles the plasma spraying technique.

Main concern of the present invention is using FMP a defined Curie temperature in the range between 43 and 70 ° C so to coat with tumor-specific substances (Coating) that the particles after an appropriate injection Enrich at the tumor site and then inductively  by means of a high-frequency alternating field to above 42.5 ° C can be heated. Another goal is when preparing the FMP this with tumor toxins combine that they are applied simultaneously for tumor therapy can be.

It has been shown that the process of phagocytosis surprisingly, by coating the FMP with biocompatible Polymers, inert proteins or polysaccharide Derivatives can be avoided. For coating with There are basically three biocompatible polymers Process proven to be advantageous:

• A) liposome technology,
• B) plasma polymerization and
• C) Phase Separation Suspension Polymerization (PSSP).

The liposome technique has been an alternative for some time Methodology for the application of especially cytotoxic Agents subject to various developments. The main concern is, the toxicity of the medication due to the inclusion in liposomes, which usually consist of a phospholipid bilayer exist to reduce. For those used for this Lipids are predominantly glycerol-3-phosphate Derivatives and N-acetylneuraminic acid-linked phospholipids, likewise sphingosine and ceramide derivatives, the are all constituents of the natural cell membrane. Man has shown in the past (Fendler and Romero, Life Sci., 20, 1109, 1977) that with the help of liposomes not only better controls unwanted side reactions of the toxins , it is also described that by modification the liposome membrane expands their application in many ways can be. The physical state of the membrane such as size, charge and fluidity as well as the composition of the Membranes determine the mechanism of liposome incorporation into the target cell, its "clearance" rate and its distribution in the body after the injection. This is how neutral liposomes become preferably absorbed by the liver, spleen and kidney, while positively charged liposomes are more in the lungs, negatively charged predominantly in the spleen and bone marrow be deposited. With regard to the invention Funds in the form of ferromagnetics can now be shown  that by adding an aqueous suspension of the FMP to the solid lipids after subsequent homogenization, e.g. B. in Ultrasonic bath, the FMP surprisingly formed in the Liposomes are incorporated. Combined inclusion too of toxins and FMP in the liposomes is through simple addition the latter to the aqueous suspension in the case of water-soluble Toxins or a chloroform suspension for that Application of apolar toxins possible. The concentration of Encapsulated pharmaceuticals can, according to experience, be varied of solvent volumes in the liposomes for both apolar as well as for polar toxins can be controlled in such a way that generally with increasing volume also the amount of incorporated toxins is increased. The stability of the Liposomes in relation to the phase transition temperature can by adding co-lipids in the form of charged species and before can all be increased by adding cholesterol. The molar ratio of such a composite membrane is usually 9: 1, 8: 2, 7: 3, for a lipid cholesterol Membrane preferably 9: 1 and preferably 7: 2: 1 im Case of a ternary membrane of charged lipid portions and Cholesterol. The release of the encapsulated in the liposomes Substrates is immediate from their physical State, especially the liquid crystalline phase transition temperature certainly. Below this transition temperature the membrane is in a "fixed" and above in a "fluid" state. This condition determines now the release rate ("releasing rate") of the encapsulated toxins such that near the transition temperature the diffusion of the pharmaceuticals increases. This fact can surprisingly in connection with the agents according to the invention to be used with "drug releasing" To influence the encapsulated FMP directly. By the inductive heating is carried out in parallel when the Curie temperature also the transition temperature from gel to liquid crystalline phase exceeded, causing the toxins be released immediately.

While the liposomes so prepared preferably in the Liver, kidney and spleen transpsorted and therefore in In the event of a tumor of these organs also there for treatment  can be used results from the use of such Lipids that have a sugar function or other activatable Surprisingly, substituents have the possibility targeted cell targeting. Examples of these can be activated Derivatives are glycosphingolipids, sphingosines or Ceramide derivatives. About the hydroxyl or amino functions of Substituents can be activated after appropriate activation the known coupling agents, such as. B. BrCN, hexamethylene diisocyanate or 1,4-butanediol diglycidyl ether (further examples s. Statements in the lower part of this invention), Tumor AK or other active substances by simple incubation couple covalently at room temperature or 4 ° C. In the subsequent Generation of the liposomes is carried out in such a way that the coupled lipids the lipid approaches described above are mixed in such a concentration that per Liposome 1 to 5, preferably 1 to 2 active substance molecules be built into the membrane.

The coating of the FMP by means of plasma polymerization can according to the known methods, as in the literature (Bell, Shen, ed., "Plasma Polymerization", ACS Symp. Ser. 108, American Chem. Soc., Washington, 1979; Yasuda, J. Polym. Sci .: Macromol. rev., 16, 199, 1981), respectively. The plasma can optionally be generated by means of DC and low frequency glow discharge, microwave discharge, Corona discharge or radio frequency or radio Glow discharge can be accomplished. By varying certain Process parameters such as gas flow rate, pressure, Degree of dilution of the monomer with the carrier gas, electrical Power, electrode arrangement can like the plasma parameters Gas particle density, residence time of the plasma, e-density etc., which determine the type of polymer coating, according to the requirements for therapeutic Use to be adjusted. Polymer layers from 5 to 200 nm are generated, with layer thicknesses between 10 and 50 nm are preferable because thinner layers are more organic can be mined as thicker. As substrates for the Such substances or Polymers in question that do not or only little with the  Blood components or the RES interact. Monomers or the polymers formed therefrom which are suitable for this are e.g. B. 2-hydroxyethyl methacrylate, N-vinyl pyrrolidone, 2- Hydroxyethyl acrylate, glycidyl acrylate, glycidyl methacrylate. Particularly good biocompatibilities are surprisingly through the use of monomer mixtures of 2-hydroxyethyl methacrylate with N-vinylpyrrolidone (Kirkpatrick, Müller-Schulte et al., Cells & Mat., 1, 93, 1991).

The coating of the FMP according to the PSSP process (variant C) is preferably with polyvinyl alcohol, starch, gelatin or Acrylamide accomplished. According to a known method (Holzscherer et al., Colloid and Polymer Sci., 265, 1067, 1987) become polyacrylamide microemulsions by suspension an aqueous solution of acrylamide and Na acetate in one Obtain a mixture of paraffin oil and emulsifier. The educated Polymer particles have a size distribution, depending on Test conditions, between 80 and 150 nm. It has Surprisingly shown that by adding 10 to 80 nm large FMP to the suspension these into the polyacrylamide Matrix are encapsulated. This type of coating will practically not recognized by the RES as foreign. In a similar way the FMP can also be encapsulated with polyvinyl alcohol (PVA) be made. For this purpose a mineral acid is used aqueous PVA solution in which the FMP are suspended in a Vegetable oil phase entered and by adding glutaraldehyde networked. By adding z. B. from 0.5 to 1 wt .-% Na Dodecyl sulfate, based on the polymer phase, are PVA coated particles with a diameter of 50 to 500 nm receive. Conventional oils such as Linseed oil, olive oil, sunflower oil, rapeseed oil, soybean oil etc., also paraffin oil and saturated liquid at room temperature and unsaturated fatty acid and mixtures thereof be used. The size of the PA-coated particles becomes besides the specified size of the FMP, by the Stirring speed, the emulsifier concentration and the Viscosity of the PVA phase determined. The viscosity of the polymer Phase, preferably between 1 and 12 centipoise lies directly through the average molecular weight of the PVA as well  its concentration, which is preferably between 1 and 2.5 % By weight, based on the aqueous phase, is adjusted are, the particle size or Coating thickness decreases.

An alternative encapsulation of the FMP with PVA without addition a crosslinker can be prepared by a known method (Müller-Schulte, DE-OS 39 00 945) performed in the manner be that one dissolved in ethylene glycol above 100 ° C. PVA phase FMP are added and this mixture in Vegetable oil is suspended analogously to the above procedure. The The suspension process is preferably carried out in an ultrasonic bath or carried out using a vortex mixer. During the cooling process solidifies the PVA phase to submicroscopic solid pearl-shaped particles, their size depends on the viscosity as well depends on the type of homogenization of the suspension. The concentration of the PVA in the dissolved phase is generally 1 to 10% by weight, preferably 0.5 to 2.5% by weight. The viscosity The PVA phase is determined by the concentration of the dissolved PVA as well as the temperature of the polymer phase. The emulsifier concentration is usually 1 to 5 wt .-%, based on the polymer phase.

Similar to how PVA can encapsulate the FMP starch can also be used. For this, one in FEBS Letters, 102, 112, 1979 modified form used. Starch is first in the heat dissolved in water and mixed intensively with the FMP. These Mixture is in a vegetable oil phase in which 1 to 5% Emulsifier are solved with the help of an ultrasonic bath suspended. When the suspension cools down Pearl-shaped particles are obtained at room temperature, their diameter, depending on the concentration of the starch and the emulsifier, varies between 50 and 300 nm. Following the same procedure gelatin can also be used for the coating. The Particles produced using the PSSP technique offer the advantage that the polymer matrix after accumulation in the tumor enzymatically broken down and easily excreted from the body can be.  

In addition to switching off the RES by the ones described above Coating measures play a role in the agents according to the invention and method the targeted application of FMP one essential role. The cytostatics used to date all cause more or less severe side effects and, as already emphasized, basically cannot distinguish between normal and tumor cells. There are hence, for some years now efforts have been made to get the toxins by using them more specifically, that they are tumor-specific or -associated AK binds covalently so as to to use "carrier" to the location of the tumor. The disadvantage of this The method is that the cytostatics-AK conjugates in must reach the cell nucleus in order to be fully effective there unfold. However, this is often prevented by the fact that after endocytosis, the toxin-AK conjugates into the lysosomes arrive and are broken down enzymatically there. Another Difficulty lies in the corresponding release of the Toxins, d. that is, in the corresponding release of the toxin from Conjugate in the phagosomes. To date, this has hardly been mastered Problems, one reason why this methodology in spite of intensive efforts only very occasionally entrance in has found medical practice.

This disadvantage can now be caused by the method according to the invention and surprisingly bypassed means that the cytostatics are used in combination with the FMP, such that FMP and toxin together in a polymer matrix be encapsulated. This makes both the selective Hyperthermia as well as simultaneous chemotherapy were realized. The above mentioned disadvantages of toxin conjugates are on the one hand through the application of the unbound bypassed free toxin, on the other hand, due to the Encapsulation higher than traditional methods Toxin concentrations are chosen because of normal tissue due to the encapsulation, not directly in with the toxin Contact comes.

After the RES the next step is to bypass the coated FMP with such tumor AK or active substances  loaded that a targeted transport of the particles to the Ensure the location of the tumor. These AK include those which are directed against a number of tumor-associated antigens are. These antigens are enhanced by certain tumors produces and can both on the cell surface as well as in the body fluids. Examples for this are carcinoembryonic antigen (CEA), α- Fetoprotein, choriogonadotropin, β₂-microglobulin and Prostate phosphatase. Because these antigens are not absolutely are tumor-specific, but also occur in normal tissue, until today they were only used for tumor diagnostics used as a marker. The agents and Procedures now make it possible to AK against these tumor markers can also be used for therapy. This will be surprising possible by using the Curie point method the FMP and, accordingly, the cells at exactly one temperature can be heated from 42.5 ° C, d. i.e., yourself normal cells loaded with the FMP-AK conjugates and also be heated, remain in contrast to the heat-sensitive tumor cells intact. The present Process therefore offers two fundamental advantages over previous methods: on the one hand, tumor-associated AK for one therapy is used, the other one becomes essential better discrimination between sick and intact Cells.

In addition to the AKs mentioned above, there are a number of other AKs which turned out to be tumor-specific or tumor-associated have and can accumulate up to 80% in the tumor (UCLA Symposia on Molecular and Cellular Biology, A. Liss, Ed., New York, Vol. 27, 1985). These include e.g. B. AK against Fibrin, colorectal antigen (CA 19-9) (Koprowski et al., Science, 212, 53, 1981), Ca 125 determinants in epithelium Ovarian carcinoma, melanoma-associated antigens such as chondroitin Sulfate proteoglycan and disialoganglioside (GD2, GD3) or human T cells 3A1 antigen.

In vivo studies show (UCLA Symposium on Molecular and Cellular Biology, vol. 27, pp 523) that reactivity the AK against various tumors varies greatly. A 2-139-AK responds e.g. B. strong against colon and prostate carcinomas,  while essential against tumors of the lungs and pancreas has lower reactivities. The present proceedings can therefore be successful especially with such tumors against which a high reactivity can be expected is.

When the AK is linked to the FMP, as already mentioned, preferably the Fab or F (ab ') ₂ fragments of the AK used by known methods by enzymatic Cleavage with papain or pepsin are available. The usage of these fragments compared to the complete molecule the advantage mediated by the Fc fragment of the AK Reactions such as phagocytosis, complement activation or Turn off platelet activation. In addition, you can the two fragments much better than the complete one Molecule penetrate into the tissue, resulting in an improved and faster targetin results.

An alternative way of coupling the tumor AK to the FMP surprisingly results using the intact molecule by coupling via the sugar ligands of the Fc fragment. For this, the first step is through oxidation with periodate in acidic solution aldehyde functions in the Sugar ligands introduced. To these groups in the second Step FMP, which carry a hydrazide group, covalently bound will. The Fc region of the AK is therefore automatic blocked and can no longer by the receptors of the macrophages be recognized. The oxidation of the hydroxyl groups Oligosaccharide substituents are done by simple incubation of the AK into a 1 to 15 mM, preferably 4 to 10 mM Na acetate buffer solution containing Na periodate, pH 5-6 a period of 30 to 60 minutes at 4 ° C. The hydrazide functions are, for example, by reaction of adipic acid dihydrazide with the epoxy groups of the z. B. with glycidyl methacrylate coated FMP by simply incubating Room temperature introduced.

An interesting variant for cell targeting and Tumor therapy opens up through the use of heterobispecific AK. These have been used for quite some time Artificial hybrid antibodies are made of two different ones Immunoglobulins built up and can simultaneously against the  Epitopes of two different antigens can be directed. The Production of this species has been described in recent years (Nature, 314, 628, 1985; Clin. Exp. Immunol., 79, 315). With the help of these hybrid antibodies the FMP also deals with a number of other therapy procedures combine. By coupling the bifunctional AK with specificities against both tumor cells and e.g. B. against Radionuclides, toxins, cytotoxic cells or CD3-, CD16- Effector cells, streptavidin, avidin, biotin can be the Efficiency of the FMP through the additionally conveyed Surprisingly, cell destruction increased significantly will. For the binding of the heterobifunctional AK to the polymer-coated FMP basically come the same Coupling procedures as for the conventional AK or AK- Fragments in question (for more details see below). Preferably 2 to 5 bifunctional AKs are coupled per FMP.

In recent years, more and more has emerged that malignant transformations with structural changes of glycoproteins and lectins on the Cell membrane go hand in hand. It is even discussed that the Interactions of glycoconjugates with the modified lectin receptors an essential role in biological information, cell growth regulation and differentiation (e.g. of metastasis formation). This realization opens up new approaches also for tumor cell targeting. Through commitment of proteins such as B. Human serum albumin, which according to known Process with a sugar ligand such. B. lactose, Asialofetuin, melibiosis, mannan, fucose, mannose, glucose, Rhamnose, sialic acid, mannose-6-phosphate, xylose, N-acetyl- D-glucosamine or galactose can be coupled to tumor cells be specifically marked. This technique was used in the Past to differentiate tumor cells, u. a. the Lungs, colon, murine lymphomas or testicles, used. With the help of these so-called neoglycoprotein Technology surprisingly allows a similar cell target to be found realize like with the tumor AK.

The ligands specific for the respective tumors are initially in vitro using cell affinity chromatography  determined. For this purpose, sugar ligands first to a polymer matrix, as is common today is used in column chromatography. Then the tumor cell suspension in question with the Affinity resin incubated. There is now a high affinity between the ligand and the sugar-binding structure, ie the lectin of the tumor cell, so there is a firm bond between solid phase and tumor cell. Become normal cells are not bound and can be eluted. The determined Ligands can be used directly for tumor cell targeting FMP can be used either as described above, via an inert protein (e.g. human serum albumin) or via a spacer molecule, as in the conventional Affinity chromatography is common on the polymer-coated FMP be coupled.

In addition to AK and neoglycoproteins, the use of Blood pressure agent angiotensin II an additional option opened for tumor targeting. In vivo studies (Goldberg et al., Brit. J. Cancer, 64, 114, 1991) have shown that colorectals Tumors metastases due to angiotensin application II injected microparticles absorbed much better by the tumor are considered to be without angiotensin. This fact can surprisingly be used to create an improved To achieve cell targeting of the FMP in that the Octapeptide angiotensin II directly covalently coupled to the FMP becomes. Here, too, the usual immobilization Methods, as will be explained in more detail, are used.

A significant improvement in cell targeting for FMP surprisingly results from the use of the Biotin / streptavidin or avidin reaction. For quite some time is the high binding affinity between biotin and the protein Streptavidin (or avidin) in molecular biology Separation of nucleic acids and proteins used. These System can now be excellently used for cell targeting use. For tumors, especially mama carcinoma, was an increased formation of receptors for the epidermal Growth factor (EGF) detected. This fact can be used for tumor cell targeting as follows: The  first possibility is to use biotin according to the known Methods (Guigni et al., J. Cell Biology, 104, 1291, 1987) to couple to the EGF via the N-biotinyl-N-hydroxysuccinimide, preferably one immobilized biotin molecule per EGF becomes. After injection of the biotinylated EGF this is firmly bound by the EGF receptor of the tumor cell. in the The next step is to bind the applied streptavidin coupled FMP to the biotin-EGF-EGF receptor conjugate. Another way to use streptavidin-biotin Using the principle results from the well-known tumor AK. First of all, a known method (e.g. Schechter et al., Int. J. Cancer, 48, 167, 1991) biotinylated Tumor AK applied. After the biotin AK on The location of the tumor is enriched, the FMP to which previously Streptavidin was covalently bound, injected. It results finally a tight bond between biotinylated AK and streptavidin-FMP.

The coupling of the bioactive described, the tumor cell targeting mediating substances such as tumor AK, sugar ligands, Oligosaccharides, glycoproteins, lectins, streptavidin, Avidin or biotin to the polymer coated FMP happens according to the known methods of immobilization from biomolecules to polymeric supports (Methods in Enzymology, Mosbach ed., Vol. 135, 3-170, 1987). As coupling media in principle, such agents come into question that have proven the preparation of affinity resins. For this count z. B. cyanogen bromide, hexamethylene diisocyanate, tosyl chloride, Tresyl chloride, 2-fluoro-1-methyl-pyridinium-toluene-4-sulfonate, Epichlorohydrin, N-hydroxysuccinimide, chlorocarbonate, isonitrile, Hydrazides, glutaraldehyde, 1,1'-carbonyldiimidazole or 1,4-butanediol diglycidyl ether.

It has proven to be advantageous for the application of the FMP alone proven one or two per FMP for steric reasons Tumor AK, AK fragments or other targetin mediating To couple proteins. For the low molecular weight sugar ligands there are no restrictions.  

Because tumor cells are stronger due to the increased metabolism tend to endocytosis than normal cells, is due solely to this mechanism has given the opportunity to alternatively the methods described so far, the FMP without any polymer coating and without coupling a tumor To selectively bring carriers to the tumor cell. How Generally known, foreign substances after they got into the body very quickly - within Minutes - phagocytized by the RES. This process can surprisingly for the agents and methods according to the invention be used in that the uncoated FMP injected intravenously. The phagocytosis triggered by this Mechanism causes that the FMP predominantly in the liver, the Kidney and spleen are deposited. In the case of a tumor of these organs, the FMP will accumulate there after the injection and predominantly due to the increased endocytosis rate store in the tumor cells of these organs.

In addition to using heterobispecific, partially against Tumor effectors directed AK to strengthen the anti Tumor effect of FMP, contributes an additional procedure, which enables hyperthermia mediated by FMP to combine with the therapeutic principle of immunotoxins so that surprisingly an integral therapy process is realized. Both methods in practice by combining two separate therapies today can be applied simultaneously with the help of FMP technology be carried out in one therapy step. To do this, the toxins used today generally in tumor therapy or Cytostatics such as B. ricin, diphtheria toxin, methotrexate, Daunomycin, cis-platinum, doxorubicin, adriamycin, abrin etc., during the phase separation suspension polymerization together added with the FMP. Surprisingly not only the FMP but also the toxins in the Polymer matrix embedded. As a polymer matrix for this preferably PVA, gelatin or starch used. Also by means of the liposome according to the invention described above Technology can accomplish a combined encapsulation will. For this purpose, a toxin or cytostatics,  Aqueous suspension containing FMP, phospholipids and tumor AK homogenized in an ultrasonic bath so that particle sizes between 200 and 500 nm arise. The concentration the added phospholipids, toxins and FMP will be so set that one FMP and 5 to 10 low molecular weight per liposome Toxin molecules and a maximum of 5 protein toxin molecules (e.g. ricin, abrin, diphtheria toxin). After accumulation of the FMP toxin particles in the tumor can become by applying an external high-frequency alternating field both the hyperthermic as well as the cytotoxic principle unfold at the same time. By varying the porosity of the Polymer matrix (e.g. PVA), both with the help of encapsulation used polymer concentration as well the concentration of the added crosslinker is precisely adjusted can be, the diffusion of the toxins into the Targeted tumor cells in the sense of long-term or short-term therapy Taxes. High polymer concentrations as well as low ones Molecular weights in connection with high crosslinker concentration usually lead to low porosity and thus lower diffusion rate. From a high molecular weight (<150,000) and a low crosslinker concentration however, increased diffusion rates result. Combinations of the different test parameters are also possible and depend on the respective requirements practice.

The main problem with current immunotoxins is in that, due to the fragile link between Toxin and tumor-AK conjugate an enzymatic breakdown subject both outside and inside the cell is. As a result, toxin targeting is significant impaired and ultimately the necessary for cell death lethal toxin dose at the site of action no longer realized is. This disadvantage is surprisingly caused by the Avoided the use of the FMP toxin colloids in that the isolated toxin immediately and not after the necessary Binding cleavage of the AK toxin conjugate can be effective. This allows the concentration of toxin to be compared  significantly increase previous therapy procedures. In the As a rule, 5 to 10 toxin molecules per cell are sufficient to kill them.

The application of the FMP or the FMP-toxin combination colloids can vary depending on medical needs and Conditions using subcutaneous, intravenous, intraarterial, intraperitoneal, intralymphatic or more direct Injection into the tumor focus. The amount injected Experience has shown that particles depend on each Tumor volume.

The geometry and performance of the induction device depends according to the needs of the areas of the body to be treated. In the case of deep-seated tumors, an induction coil is preferred used from 40 to 70 cm in diameter the patient's body can be pushed in. The Coil is connected to a conventional high frequency generator, whose power is in the range of 0.1 to 1 kW. The adjustable frequency is in the range from 0.5 to 10 MHz, in practice preferably 0.5 up to 2 MHz is used. At these frequencies the transfer all energy to the FMP. Healthy tissue will in contrast to the techniques currently used within hyperthermia such as microwave, ultrasound or induction heating, not recorded. The strength of the magnetic field applied is usually between 400 and 800 A / m.

The required treatment times depend on the respective therapeutic requirements and are usually between a few minutes to several Hours. Interval treatment over a longer period Period is possible, with a precise "monitoring" the FMP is displayed in the body.

The invention is illustrated below using a few examples described in more detail.  

Example 1

0.1 g of a Ni _0.2 Zn _0.8 Fe ₂ O ₄ compound with a Curie temperature of 43 ° C. and an average particle size of 50 nm are mixed with 7.5 ml of an aqueous PVA solution (Mw = 150 000), 100 mg of sodium dodecyl sulfate, 0.5 ml of 1N HCl and 0.1 ml of 25% glutaraldehyde are added, suspended in 25 ml of linseed oil and sonicated in an ultrasonic bath (100 W) for 5 minutes. The suspension is then left at 2000 rpm for 15 minutes at room temperature. stirred further using a conventional stirrer. The suspension is then extracted several times with in each case 30 ml of n-hexane until the aqueous phase is oil-free. this is followed by a further extraction with diethyl ether. By centrifuging for 15 minutes (4000 × g) and dialysis against water for 24 hours, the product is freed of polymer, crosslinking agent and foreign ions that are still dissolved. This is followed by vacuum drying over phosphorus pentoxide for 12 hours. The dried product is then mixed with 3 ml of absolute dimethyl sulfoxide (DMSO) in which 0.5 ml of hexamethylene diisocyanate and 20 μl of tin octoate are dissolved and reacted with shaking at 40 ° C. for 30 minutes. The converted product is removed from the reaction solution by means of a magnet and purified by repeated alternating suspensions in 20 ml of dimethylformamide and 20 ml of acetone and subsequent decanting using the magnet in each case. The product is then dried in vacuo (1300 Pa) over KOH for 5 hours.

0.1 mg of a monoclonal AK dissolved in PBS buffer, pH 7.0, which is directed against the EGF receptor (Schlechter et al., Int. J. Cancer, 48, 167, 1991), is incubated for 6 hours at room temperature to the activated FMP covalently coupled. the immobilized product is 20 min. at 4000 × g centrifuged and the supernatant then lyophilized. The product obtained is dissolved in 3 ml of physiological NaCl Suspended solution and sterile filtered. The suspension can so used for direct application and after enrichment in the tumor in question by applying a 2 MHz Alternating field heated to the specified Curie temperature will.  

Example 2

Isocyanate-activated FMP tumor agents according to Example 1 with 50 mg mannose dissolved in 3 ml absolute DMSO, added and reacted at 30 ° C for 6 hours. The product will then dialyzed against water for 24 hours and then lyophilized. The further preparation is carried out according to example 1.

Example 3

PVA-coated ferrite powder according to Example 1 is according to the Drying in vacuo over KOH with 3 ml of absolute DMSO, in which 3mM 4-dimethylaminopyridine and 2.5mM 2-fluoro-1-methylpyridinium toluene-4-sulfonate (FPTS) are dissolved, added and activated with shaking at room temperature for 45 min. The converted product is then as described above alternating with acetone and dimethylformamide using of a magnet and then in vacuum over KOH dried. The product obtained in this way can be used directly with AK or other tumor targeting mediating substances through simple Incubation can be coupled at room temperature.

Example 4

1.5 nM sugar-free human serum albumin are mixed with 50 ml 0.1M Phosphate buffer, pH 5.0, in which 0.01M N-cyclohexyl-N ′ - [β- (N-methylmorpholine) ethyl] carbodiimide p-toluenesulfonate dissolved are added and reacted for 2 hours at room temperature. The product is then centrifuged at 4000 × g for 30 min. then dialyzed against PBS, pH 7.0 for 24 hours and finally lyophilized. The dry product will in 1.5 ml 0.1M K-phosphate buffer, pH 6.4, and with 1.5 ml of the same buffer in which 95 nM N-acetyl-D- Galactosamine are dissolved, added. The coupling happens with shaking at 4 ° C for 18 hours. This is followed by centrifugation, dialysis and lyophilization.  The solid product obtained is dissolved in 2 ml of PBS buffer, pH 7.2. solved and then with the PVA-coated and FPTS- activated FMP according to Example 3 for 15 hours at room temperature incubated. Processing and preparation follow according to example 1. The substance is thus ready for use.

Example 5

5 ml of a 10% aqueous starch solution are at 95 ° C with 0.1 g ferrite powder with a Curie temperature of 45 ° C and an average particle size of 80 nm briefly with stirring mixed and then in the heat in 45 ml at 80 ° C preheated olive oil, dissolved in 1 ml Pluronic® PE 3100 is stirred in and homogenized using a vortex stirrer. The suspension is then cooled in an ice bath. Solid pearl-shaped particles with a medium size fall Particle size of 100 nm, which is characterized by alternating Suspend in 20 ml ice water and 20 ml acetone and then Decant using a magnet getting cleaned. This procedure is repeated 10 times. The the dried product is then dissolved in 50 mg of BrCN in 2 ml 0.1M carbonate bicarbonate buffer, pH 11, at 5 hours Room temperature implemented. The activated product is repeated several times mixed with water and in the usual way with the help of a magnet. Drying and subsequent lyophilization is done as indicated above. By 12 hours Incubation of 0.1M NaHCO₃- containing 3 nM anti-CEA-IgG Solution, pH 8.5, at 4 ° C anti-tumor agents are obtained after the usual preparation steps according to Example 1 for the therapy of such tumors are suitable, the high CEA values exhibit.

Example 6

Ferrite powder coated with starch according to Example 5 is used in Vacuum dried over KOH for several hours. 20 mg tosyl chloride and 0.4 ml ethanolamine, dissolved in 1 ml absolute  Acetone are added and the mixture at 25 ° C for 20 min shaken. Then it is repeated several times with acetone in the usual way Way washed. The product is then mixed with 30 ml 0.1M Carbonate-bicarbonate buffer, pH 9.0, washed and with 1 ml this buffer, in which 0.5M NaCl and 0.1 mg angiotensin II are resolved. The coupling takes place within 12 Hours at 4 ° C. Analogously after dialysis and further preparation Example 1 is the product ready for use.

Example 7

Coated and activated with BrCN FMP according to Example 5 are with 3 ml of a 0.1M NaHCO₃ / 0.5M NaCl solution, pH 8.5, in which 10 µg EGF are dissolved, incubated and over a period of time of 10 hours at 4 ° C implemented. Cleaning and Preparation is carried out analogously to the examples above.

Example 8

0.1 g ferrite powder with a Curie point of 45 ° C and one average particle diameters of 20 nm with a PVA Solution analogous to Example 1, which additionally contains 0.1 mg ricin, homogenized in an ultrasonic bath for 10 minutes. After the usual cleaning and refurbishment steps are FMP Toxin colloids with an average particle size of 80 nm won. The product is after the usual vacuum drying activated with FPTS / 4-dimethylaminopyridine according to Example 3. After the usual cleaning steps, in PBS buffer, pH 7.0, dissolved tumor AK or cell targeting substances the product obtained by incubation according to the above examples be coupled at room temperature.

Example 9

0.1 g ferrite powder of the formula CO _0.2 Zn _0.8 Fe ₂ O ₄ with a Curie point of 45 ° C. and an average particle diameter of 80 nm are placed on a 4 × 4 cm glass slide, which can be 2 cm above the inner electrode of a conventional glow discharge device. Ultrapure nitrogen is passed through a wash bottle containing a mixture consisting of 70% (V / V) glycidyl methacrylate and 30% (V / V) N-vinylpyrrolidone. the wash bottle is kept constant at a temperature of 45 ° C in order to increase the monomer partial pressure accordingly. Before the experiment, the plasma chamber with the sample is flushed with the reaction gas for 10 minutes. During the test run with 300 W electrode power, the gas pressure is constantly adjusted to 300 Pa over the 10-minute test period. This test cycle is repeated twice in order to achieve an even coating of the FMP. After the experiment, the coated FMPs are evacuated for 3 hours in an oil pump vacuum to remove residual monomer. Then the material is alternately mixed with acetone and water several times and the solution is decanted after the magnet has been applied. This is followed by drying in vacuo (1300 Pa) over KOH. The preparation obtained is then washed with 30 ml of a solution consisting of 50 parts by volume 0.1M borate-NaOH buffer, pH 9.5, and freshly distilled dimethylformamide. 2 ml of this solution, in which 1 mg of N-acetyl-neuraminic acid are dissolved, are then incubated for 20 hours at room temperature. Residual epoxy groups are saturated by subsequent incubation for 20 hours with 0.2M mercaptoethanol solution. After 24 hours of dialysis against PBS, pH 7.0, and the usual purification and preparation steps according to Example 1, the substance can be used for the therapy.

Example 10

Ferrite powder according to Example 1 is the plasma coating Procedures as in Example 9 subjected. The Nitrogen flow is through a 50% (v / v) glycidyl methacrylate and 50% hydroxyethyl acrylate solution passed. The Feed pressure is 500 Pa.  

Cleaning and working up are carried out analogously to Example 9. 10 mg Glucose, dissolved in 3 ml 0.1M borate buffer, pH 9.5, becomes 20 Incubated for hours at room temperature. Glucose-immobilized Tumor agents received, according to the appropriate Incubation in 0.2M mercaptoethanol according to the above example, in 3 ml of physiological saline are suspended and after subsequent sterile filtration analogous to the above examples are ready to use.

Example 11

Ferrite powder according to Example 1 is mixed with a plasma which, in Modification of the test conditions from example 9, with a Monomer composition consisting of 80% hydroxyethyl methacrylate and 20% N-vinyl pyrrolidone Pressure of 150 Pa treated for 10 min. The trial cycle is repeated twice. Refurbishment and cleaning take place according to the examples above. The hydroxyl groups Matrix is then made using the Hexamethylene system diisocyanate / DMSO activated analogously to Example 1. After the usual cleaning and refurbishment steps is a Colloid obtained, to which sugar ligands in a borate Buffer, pH 9-10, or proteins in a 0.5-1M potassium Phosphate buffer, pH 7-8, coupled by simple incubation can be.

Example 12

0.1 g ferrite powder with a Curie point of 45 ° C and one average particle diameter of 85 nm are in a Water-oil suspension consisting of 14.5% recrystallized twice Acrylamide, 0.6% N, N'-methylene-bis-acrylamide, 3.5% Na acetate, 41% linseed oil, 0.2% (all W / W) azo-bis- isobutyronitrile, given and in an ultrasonic bath (100 W) homogenized. The reaction is carried out using a conventional High pressure mercury lamp initiated and is after 10 min. completed. Then the product is at 4000 × g for 10 min  centrifuged and then against water for 24 hours dialyzed. The product obtained is repeatedly in water suspended and decanted after applying a magnet. The Solid phase obtained is used according to Example 1 for the application prepared and is for the treatment of liver and kidney tumors usable.

Example 13

0.1 g ferrite powder according to Example 12 are Coating with 3 ml of a 5% aqueous glutaraldehyde Solution added. The activation takes place at Room temperature over a period of 2 hours. The Material is then centrifuged at 3000 × g for 30 min and using several times with water in the usual way of a magnet. 1 ml PBS buffer, pH 6.9, in which 0.1 mg Anti-CEA-IgG1 and 0.5 mM NaBH₃CN are dissolved, 10th Incubated at 4 ° C for hours. Centrifugation and preparation follow according to Example 1. The preparation obtained in this way can can be used directly for therapy.

Example 14

The procedure of Example 12 is used to create an FMP Manufacture toxin combination preparation. For this the Water-oil suspension additionally 0.05 mg ricin added. It This creates colloids that are suitable for long-term therapy are.

Example 15

Acrylamide-coated particles are according to Example 12 under Use of 0.1% (w / w) N, N'-methylene-bis-acrylamide produced. Further preparation is carried out according to Example 12. It This creates a therapeutic agent for short-term therapy suitable is.  

Example 16

40 µM L-dipalmitoyl-α-lecithin and 8.2 µM cholesterol dissolved in 5 ml chloroform in a 50 ml round bottom flask and then concentrated to dryness in vacuo. After 10 hours Drying in a high vacuum is 3 ml physiological Saline solution in which 0.1 g ferrite powder according to Example 1 and 0.012 mg of ricin are added, and the Mixture homogenized at 45 ° C. for 30 minutes under a nitrogen supply. The suspension is then cooled in an ice bath and stored at 4 ° C for 6 hours under nitrogen. The The product is then several times in physiological saline suspended and with the help of the magnet decanted. To completely not incorporate ricin remove the suspension over a with physiological Saline solution equilibrated Sephadex G-50 column (1 × 25 cm, Flow 0.5 ml / hour). Liposomes with one fall Particle size of approximately 450 nm, which is used to treat Liver, kidney and spleen carcinomas are suitable.

Example 17

The method of Example 16 is used to make FMP liposomes with negative charge. For this, in Modification of the above formulation 35 µM L-dipalmitoyl-α-lecithin, 10.2 µM cholesterol and 4.8 µM L-dipalmitoyl-α-phosphatide disodium salt used to prepare the liposomes. The further procedures proceed analogously to the example above.

Example 18

0.5 mg streptavidin, dissolved in 1 ml PBS buffer, pH 7.2 by incubating at room temperature for 12 hours according to the Example 1 coated with PVA and activated with isocyanate Coupled ferrite powder. The product obtained is then by repeated suspension in physiological saline and decanting using magnetic field separation  cleaned. An anti-EGF receptor IgG is modified in one known protocol (Int. J. Cancer, 48, 167, 1991) biotinylated. For this, 1 mg AK in 1 ml 0.1M Na acetate buffer, pH 5.5, which contains 12.5 mM NaJO₄, at 4 ° C for one hour Light termination oxidized. after dialysis against the same Buffers are 30 mg of biotin hydrazide and 0.05 mg of NaHB₃CN admitted. The link is at after another hour 4 ° C completed. Then the biotinylated AK against PBS Buffer, pH 7.0, dialyzed for 24 hours; then follows Lyophilization. The solid product obtained is in 2 ml physiological saline solution can be added after the Sterile filtration can be used directly for injection. After saturation of the EGF receptors with the biotinylated IgG, the streptavidin-laden FMP can be injected which then conjugate with the biotin IgG.

The corresponding induction field follows.

Claims (16)

1. Therapeutic agent for selective tumor therapy, characterized in that ferromagnetic particles with a Curie temperature between 42.5 and 70 ° C and a particle size of <500 nm are encapsulated in a polymer or biopolymer matrix that are not from the reticulo endothelial system (RES) are phagocytosed and have the reactive substances which couple with tumor cell targeting-active substances. 2. Therapeutic agents according to Example 1, thereby characterized in that the polymer layer is made of starch, Polyvinyl alcohol, polyacrylamide, dextran, agarose or Gelatin exists. 3. Therapeutic agent according to Example 1, characterized in that that the ferromagnetic particles in liposomes (Vesicles) from phospholipids, sphingolipids, glycosphingolipids, Ceramides as well as others, the cell membrane constituent substances or mixtures thereof are encapsulated. 4. Therapeutic agent according to Example 3, characterized in that the liposomes contain activated lipids which with active substances that mediate tumor cell targeting have coupling, reactive groups.   5. Therapeutic agents according to Examples 1 to 4, thereby characterized in that the mediating the tumor cell targeting Active substances tumor antibodies, tumor-associated antibodies, Antibody fragments, heterobispecific antibodies, Glycoproteins, saccharides, oligosaccharides, neoglycoproteins, Angiotensin II, streptavidin, avidin, biotin or Are epidermal growth factor. 6. Therapeutic agents according to Example 1, thereby characterized in that the ferromagnetic particles with Polymers in a plasma from vinyl monomers or a Vinyl monomer mixture are formed, are coated. 7. Therapeutic agents according to Examples 1 to 5, thereby characterized in that the ferromagnetic particles together with a tumor toxin or a cytotoxic substance in the polymer matrix is encapsulated. 8. Process for the preparation of selective agents Tumor therapy, characterized in that ferromagnetic Particles with a Curie temperature between 42.5 and 70 ° C and a particle size of <500 nm in a polymer or Biopolymer matrix are encapsulated that are not covered by the RES is phagocytized and reactive groups on its surface are generated, to the tumor targeting mediating active substances be covalently coupled. 9. The method according to claim 8, characterized in that the ferromagnetic particles by means of the phase separation Suspension polymerization with starch, polyvinyl alcohol, Encapsulated in polyacrylamide, dextran, agarose or gelatin will. 10. The method according to Example 8, characterized in that the ferromagnetic particles through from phospholipids, Sphingolipids, glycosphingolipids, ceramides and others, substances or mixtures constituting the cell membrane the same liposomes (vesicles) formed are encapsulated.   11. The method according to Examples 8 and 10, characterized in that encapsulate in the ferromagnetic particles Such lipids are incorporated into the liposomes mediating tumor cell targeting via activatable groups Active substances are bound covalently. 12. The method according to Example 8, characterized in that the ferromagnetic particles by one of monomers or a monomer mixture of existing plasma, which is either by High frequency or radio frequency glow discharge, direct current and low frequency glow discharge, microwave discharge or Corona discharge is generated, coated. 13. Process according to Examples 8, 9, 11 and 12 thereby characterized in that the recative groups containing Polymers or biopolymers with which the ferromagnetic Particles are coated, mediating tumor targeting Active substances are covalently coupled according to Example 5. 14. The method according to Examples 8 to 11 and 13, thereby characterized in that the ferromagnetic particles together with tumor toxins or cytotoxic substances in the Polymer or biopolymer matrix are encapsulated. 15. Use of ferromagnetic particles with a Curie temperature between 42.5 and 70 ° C and a particle size of <500 nm, either alone or together with Tumor toxins or cytotoxic substances in one Polymer matrix are encapsulated that are not covered by the RES is phagocytosed and mediating to the tumor targetin Active substances are coupled for selective tumor therapy through inductively generated hyperthermia. 16. Use of ferromagnetic particles with a Curie temperature between 42.5 and 70 ° C as well as one Particle size of <500 nm without polymer coating for  selective therapy of the liver or kidney by induction generated hyperthermia.