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Title:
METHOD AND COMPOSITION FOR TREATING TUMORS HAVING HIGH TYROSINASE ACTIVITY
Document Type and Number:
WIPO Patent Application WO/1993/008688
Kind Code:
A1
Abstract:
Tumor cells which have beta-glucuronidase and tyrosinase activity are selectively treated by administration of a conjugate of a cytotoxic compound which is a substrate for tyrosinase and glucuronic acid or a pharmaceutically acceptable salt or ester thereof, particularly the triacetylated form of glucuronic acid. Among the cytotoxic phenolic compounds which are substrates for tyrosinase which can be used are tyrosine, 4-hydroxyanisole, butylated hydroxyanisole, L-3,4-dihydroxyphenylalanine, dopamine (3,4-dihydroxyphenethylamine), terbutylcatechol, hydroquinone, resorcinol, 6-hydroxydopa (3,4,6-trihydeoxyphenylalanine) and methyl gallate.

Inventors:
RUBIN DAVID (US)
SCHWIMMER ADOLPH (US)
Application Number:
PCT/US1992/009473
Publication Date:
May 13, 1993
Filing Date:
November 04, 1992
Export Citation:
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Assignee:
RUBIN DAVID (US)
SCHWIMMER ADOLPH (US)
International Classes:
A61K31/05; A61K31/085; A61K31/165; A61K31/195; A61K31/235; A61K31/70; A61K47/48; (IPC1-7): A01N43/04; A61K31/70
Foreign References:
US4481195A1984-11-06
Other References:
See also references of EP 0619704A4
Download PDF:
Claims:
WHAT IS CLAIMED IS:
1. A method for selectively treating tumor cells which have both glucuronidase and tyrosinase activity comprising administering to a patient suffering from said tumor cells an effective amount of a conjugate made by conjugating glucuronic acid or a pharmaceutically acceptable ester or salt thereof to a cytotoxic phenolic compound which is also a substrate for tyrosinase.
2. The method according to claim 1 wherein the conjugate is formed from the triacetylated form of glucuronic acid.
3. The method according to claim 2 wherein the conjugate is administered orally.
4. The method according to claim 1 wherein the cytotoxic compound is selected from the group consisting of hydroxyanisole, tyrosine, L3,4 ^dihydroxyphenylalanine, dopamine, tertbutylcatechol, hydroquinone, 6hydroxydopa, and methyl gallate.
5. The method according, to claim 4 wherein the cytotoxic compound is hydroxyanisole.
6. The method according to claim 2 wherein the cytotoxic compound is selected from the group consisting of hydroxyanisole, tyrosine, L3,4 dihydroxyphenylalanine, dopamine, tertbutylcatechol, hydroquinone, 6hydrosydopa, and methyl gallate.
7. The method according to claim 6 wherein the cytotoxic compound is hydroxyanisole.
8. The method according to claim 1 wherein, prior to administration of said conjugate, the patient is administered an alkalinizing agent in an amount sufficient to maintain the pH level of the nontumor tissues of the patient at approximately 7.4 during the treatment with said conjugate.
9. The method according to claim 1 wherein, prior to administering said conjugate, the tumor cells are hyperacidified.
10. The method according to claim 1 further including the step of inducing hyperthermia at least at the site of the tumor being treated to an extent suffi¬ cient to increase. substantially glucuronidase activity 5 at the site without substantially affecting the overall health of the patient at the time of maximum conjugate concentration at the tumor.
11. The method according to claim 10 wherein said hyperthermia is induced locally at the tumor by 10 administration of the glucuronide of a pyrogen, by micro¬ wave treatment or by passage of electrical current through the body.
12. The method according to claim 1 further including the step of administering estrogen or testoster 15 one substantially simultaneously with administration of said conjugate, wherein the tumor is not estrogen or testosteronedependent.
13. A composition for selectively treating tumor cells which have both 0glucuronidase and 20 tyrosinase activity comprising an effective amount of a conjugate made by conjugating a glucuronide compound selected from the group consisting of glucuronic acid and pharmaceutically acceptable esters and salts thereof to a cytotoxic phenolic compound which is also a substrate for 25 tyrosinase, and a pharmaceutically acceptable carrier.
14. The composition according co claim 12 wherein the glucuronide compound is a triacetylated glucuronic acid.
15. The composition according to claim 14 0 wherein the glucuronide compound is methyl (triOacetyl αDglucopyranosyl) bromide uronate.
16. The composition according to claim 13 wherein the phenolic compound is selected from the group consisting of 4hydroxyanisole, tyrosine, L3,4 5 dihydroxyphenylalanine, dopamine, tertbutylcatechol, hydroquinone, 6hydroxydopa, and methyl gallate.
17. The composition according to claim 16 wherein the phenolic compound is hydroxyanisole.
18. The composition according to claim 14 wherein the phenolic compound is selected from the group consisting of hydroxyanisole, tyrosine, L3,4 dihydroxyphenylalanine, dopamine, tertbutylcatechol, hydroquinone, 6hydroxydopa, and methyl gallate.
19. The composition according to claim 16 wherein the phenolic compound is hydroxyanisole.
20. The composition according to claim 19 wherein the glucuronide compound is methyl (tri0acetyl αDglucopyranosyl) bromide uronate.
21. The composition according to claim 13 wherein the carrier is suitable for parenteral administra tion.
22. The composition according to claim 14 wherein the carrier is suitable for oral administration.
23. The method according to claim 1 wherein the tumor cells are selected from the group consisting of solid breast tumors, lung carcinoma, colon carcinoma, testicular carcinoma, hepatic carcinoma, pancreatic carci¬ noma, ovarian carcinoma, bronchogenic carcinoma, prostate carcinoma, Hodgkin's disease, and rectal carcinoma.
24. The method according to claim 23 wherein the tumor cells are solid breast tumors.
Description:
METHOD AND COMPOSITION FOR TREATING TUMORS HAVING HIGH TYROSINASE ACTIVITY

Field of the Invention

The present invention is directed to methods and compositions for treating tumors and other metastatic diseases exhibiting high tyrosinase and yθ-glucuronidase activity. The invention is further directed to methods and compositions for treating tumors having high tyrosinase and jS-glucuronidase activity in which the toxicity of the materials used to treat the tumors is localized at the site of the tumors.

This application is a continuation-in-part of Serial No. 07/787,347, filed November 4, 1991.

There have been many reports in the prior art relating to the general concept of providing direct trans¬ port of an agent which is toxic to tumor cells directly to tumors having 0-glucuronidase activity by conjugating the agent with glucuronic acid. Among such reports are Von Ardenne, M. et al., Aαressoloαie. 1976, 176(5): 261- 264; East German Patent No. 122,386; German Offenlegungsschrift 22 12 014; Sweeney et al., Cancer Research 31: 477-478, 1971; Baba et al., Gann. 69: 283- 284; and Ball, Biochem. Pharm 23: 3171-3177 (1974). Von Ardenne suggest broadly many types of aglycones which may be conjugated to glucuronic acid and will be active at the tumor site. There include, broadly, alkylating groups, antimetabolites, cytotoxins, membrane- active (lytic) groups, glycolysis stimulators, respiration inhibitors, inorganic and organic acids and cell cycle stoppers. The East German patent also suggests many such combinations, including 5-fluorouracil-glucuronide, ani¬ line mustard-glucuronide and many others. The Offenlegungsschrift also mentions a large number of glucuronides. Sweeney et al. disclose the anti-tumor activity of mycophenolic acid-9-D-glucuronides. Baba et al. note the anti-tumor activity of 5-fluorouracil-o-jS-

D-glucuronide, and Ball discloses the anti- umor activity of p-hydroxyaniline mustard glucuronide.

Kneen in European Patent Application 054,924, discloses phenyl ether compounds which can be used to make tumors more sensitive to radio therapy.

Rubin, in U.S. Patents Nos. 4,337,760 and 4,481,195, discloses methods for treating tumors having high β-glucuronidase activity with glucuronides with aglycones toxic to the tumor cells with great safety toward the rest of the body by first administering an alkalinizing agent in an amount sufficient to maintain the pH level of non-tumor tissues at approximately 7.4 during the glucuronide treatment to inactivate β - glucuronidase activity in the rest of the body. Thus, the toxic agent is directed onlyto the cancer cells, as opposed to all of the healthy cells of the body, since the aglycone is only released at the cancer site. Tumors having high glucuronidase activity can be identified by assaying tumor cells obtained in a biopsy for β - glucuronidase activity, or by administering a glucuronide whose aglycone has been labelled with a radioactive iso¬ tope. If upon a full body scan it is found that the radioisotope is accumulated at any specific areas of the body, this will indicate not only the location of the tumor but the fact that the tumor has sufficient β- glucuronidase activity to deconjugate the glucuronide.

The rationale for the use of 4-hydroxyanisole in the treatment of melanoma is based upon the premise that the only cells in vertebrates that contain tyrosinase are the melanocytes. 4-Hydroxyanisole inhibits DNA synthesis, but by itself shows little toxicity. However, it is oxidized by tyrosinase to highly cytotoxic products, and consequently is preferentially toxic to those melanoma cells that contain the enzyme tyrosinase [Riley, Philos. Trans. R. Soc. fBiol.) 311: 679, 1985].

Morgan et al., in Clinical Oncology 2=227-231, 1981, also note that 4-hydroxyanisole, which is oxidized

by tyrosinase, gives rise to cytotoxic oxidation products. The specific maelanocytotoxic action of this agent is of particular interest because of its use in treatment of malignant melanoma- It was found that localized malignant melanomas treated by intra-arterial infusion of 4- hydroxyanisole underwent regression, although intravenous administration of the drug was not therapeutically effec¬ tive. The need to use the intra-arterial route of admin¬ istration imposes certain limits on the use of 4- hydroxyanisole, since it is not always possible to perfuse the site occupied by a tumor. However, it is believed that, as an adjunct to the conventional treatment of primary melanoma in accessible sites, 4-hydroxyanisole infusion will reduce the dissemination of metastases. Kanclerz et al., in Br.-J. Cancer 54: 693-698,

1986, reported that animal studies on experimental melano¬ mas have given variable results with respect to the thera¬ peutic efficacy of phenolic depigmentation agents. The most active melanocytotoxic agen -was found to be an analog of tyrosine, 4-hydroxyanisole. However, evidence for an antitumor effect of 4-hydroxyanisole on melanoma in vivo was found to be variable and not conclusive.

Unfortunately, intra-arterial infusion of 4- hydroxyanisole has serious clinical drawbacks, including difficulties in placing and maintaining the potency of intra-arterial catheters. Clogging and/or clotting fre¬ quently occur, and, furthermore, 4-hydroxyanisole has a short half-life in blood (only nine minutes) after intra- arterial injection. Saari, in U.S. Patent No. 4,812,590, discloses that certain carbamates of 4-hydroxyanisole are suitable substitutes for 4-hydroxyanisole in the treatment of melanoma. These carbamates can be delivered by, for example, intravenous injection, and provide increased levels of 4-hydroxyanisole at the tumor site. The deliv¬ ery of 4-hydroxyanisole is more convenient and safer than many other methods of delivering 4-hydroxyanisole, al-

though, because serum tyrosinase levels may be elevated in patients having tumors with high tyrosinase activity, the metabolic products of 4-hydroxy anisole may be present in locations other than the tumor site. Pavel et al.. Pigment Cells Research 2.:421-246,

1989, reported an investigation of the human metabolism of 4-hydroxyanisole using urine samples from melanoma pa¬ tients treated with -hydroxyanisole. The most important metabolite of 4-hydroxyanisole was found to be 3,4- dihydroxyanisole, although other metabolic products in¬ cluded 3-hydroxy-4-methxylanisole and 4-hydroxy-3- methoxyanisole, as well as quinone. These compounds were excreted predominantly as sulfates and glucuronides. Unfortunately, when tyrosinase oxidizes 4-hydroxyanisole in the body, the product, 4-methoxybenzoquinone, is ex¬ tremely toxic. Because the 4-hydroxyanisole is not con¬ fined to the tumor site, and because the serum levels of tyrosinase of patients suffering from tyrosinase-active tumors tends to be elevated, there is always the danger in administering -hydroxyanisole to such patients that an excess of metabolic products of 4-hydroxyanisole will be present in the blood, and thus exert a cytotoxic effect on cells other than tumor cells.

Chen et al. discovered that serum tyrosinase activity in many persons with metastatic diseases was found to be significantly higher than activity in normal persons. Although the highest serum tyrosinase activity was observed in melanoma and breast carcinoma, there is measurable tyrosinase activity in a variety of other metastatic diseases, including lung carcinoma, colon carcinoma, testicular carcinoma, hepatic carcinoma, pan¬ creatic carcinoma, ovarian carcinoma, leukemia, bronchogenic carcinoma, prostate carcinoma, Hodgkin's disease, and rectal carcinoma, the tyrosinase activity of the foregoing diseases listed in decreasing order. In addition, serum melanin bands were demonstrated by polyacrylamide disc gel electrophoresis of serum

tyrosinase followed by incubation of the gel with L-dopa at room temperature overnight to form melanin bands. The following types of metastatic disease demonstrated serum melanins bands with this technique: mouth carcinoma, multiple myeloma, carcinoma of the stomach, carcinoma of the larynx, carcinoma of the cervix, carcinoma of the tonsil, lymphoma, lymphosarcom , thyroid carcinoma, carci¬ noma of cecum, endometrial carcinoma, polycythemia, thymoma, lymphadenopathy, and vertebral carcinoma. Although the elevation of serum tyrosinase level is explicable in some diseases such as melanoma and breast carcinoma, the high tyrosinase content in melanoma and breast skin increases the tyrosinase circulation level in the blood. Although it has not yet been determined if malignant disease causes a high yield of serum tyrosinase or if a high yield of serum tyrosinase causes malignant "" disease, it has been postulated that serum immunoglobulins are involved as tyrosinase carriers. Whatever the in¬ volvement of tyrosinase in metastatic diseases, there is an elevated level of serum tyrosinase in the case of a great many metastatic diseases.

Passi et al., in Biochem. . 245: 536-542, 1987, compared the cytotoxicity of a number of phenols in vitro.

These researches found that in vitro, two melanotic human melanoma cell lines IRE 1 and IRE 2, and the lymphoma- and leukemia-derived cell lines Raji and K 562, and noted that there was no significant differences in percentage surviv¬ al among the different cell lines for each drug tested. The major component of toxicity up to 24 hours of di- and tri-phenols was due to toxic oxygen species acting outside the cells, and not to cellular uptake of these phenols per se. It is believed that scavenger enzymes may interfere with the cytotoxic effect of some of these phenols. Additionally, it was noted that the cytotoxic effect of these phenols was not necessarily related to their being substrates for tyrosinase, as the level of toxicity of butylated hydroxyanisole, which is not a substrate of

tyrosinase, was significantly higher than that of 4- hydroxyanisole, which is a substrate of tyrosinase. With respect to dosages of 4-hydroxyanisole to be given Wallevik et al. report in "Non-specific Inhibition of In Vitro Growth of Human Melanoma Cells, Fibroblasts, and Carcinoma cells by 4-Hydroxyanisole" in Hydroxyanisole: Recent Adv. Anti-Melanoma Ther. , pp. 153-164 (1984) Edi¬ tor, Patrick A. Riley, that 4-hydroxyanisole was inhibito¬ ry to cultures of human melanotic and amelanotic melanoma cell lines, human fibroblasts and a human bladder carcino¬ ma at concentrations of 10" 3 M to 10" 5 M. This activity was independent of tyrosinase activity, as high tyrosinase activity was only connected with the melanotic cell line. Unfortunately, the therapeutic concentration of 4- hydroxyanisole is difficult to obtain in tissue by intra- arterial infusion of the drug. Furthermore, infusion is given only for one hour twice a day, which is an exposure of the cells that in vitro has no inhibitory effect, even at a high concentration of 4-hydroxyanisole. Tyrosinase is known to convert several phenols, such as its natural substrate, tyrosine, to catechols and quinones. These compounds react strongly with SH-groups, and are highly toxic to normal cells. Therefore, it is essential that the cytotoxic phenols such as 4- hydroxyanisole be delivered efficiently to the tumor cells, and only to the tumor cells, and that the reaction product of tyrosinase on the substrate, such as 4- hydroxyanisole, be retained in the tumor cells.

Summary of the Invention

It is an object of the present invention to overcome the aforementioned deficiencies in the prior art.

It is another object of the present invention to provide a method and composition for treating metastatic cells.

It is another object of the present invention to provide a composition and method for treating metastatic cells without damaging normal cells.

It is a .further object of the present invention to provide a two-step method for treating tumors whereby healthy cells are spared from treatment.

According to the present invention, a cytotoxic phenol which is a substrate for tyrosinase is conjugated to a glucuronide to provide a compound for treating tumors which have β-glucuronidase activity and tyrosinase activity. The glucuronide, upon contact with the β - glucuronidase, is cleaved to produce the tyrosinase substrate cytotoxic phenol at the tumor site, which, upon being acted upon by tyrosinase, then can exert its cytotoxic effect on the tumor cells. In this manner, the truly toxic compound is delivered only to the tumor cells, and there is virtually no contact with the healthy cells, since the cytotoxic phenol is not released at the tumor site until the glucuronide compound has been cleaved by the β-glucuronidase at the tumor site. This avoids contact of healthy cells with the cytotoxic phenol, and the reaction products of the cytotoxic phenol and any tyrosinase can be limited to the tumor site.

The cytotoxic phenolic compounds which are substrates for tyrosinase compounds which can be used in the present invention are those which have been found to be toxic to tumor cells, including tyrosine, 4- hydroxyanisole, butylated hydroxyanisole, -3,4- dihydroxyphenylalanine, dopamine (3,4-dihydroxyphenethy- lamine) , terbutylcatechol, hydroquinone, resorcinol, 6- hydroxydope (3,4,6-trihydeoxyphenylalanine) and methyl gallate. These compounds are conjugated to glucuronic acid by any convenient means to form the compounds of the present invention. in addition, the cytotoxic phenolic compounds conjugated to glucuronic acid can be used in the acetylated form. That is, when the conjugates are formed

by conjugating a phenolic compound with methyl(tri-O- acetyl-α-D-glucopyranosyl bromide) -uronate, a triacetyl methyl ester is formed. This triacetyl methyl ester can be used in the acetylated form. Since these acetyl groups are not easily removed, the compounds are not particularly cytotoxic to normal cells. However, since primitive cells, such as growing cancer cells, can produce many different types of enzymes, including acetylase, these primitive cells can readily remove the acetyl groups on the acetylated conjugates to provide active forms of the compound directly at the site of a growing tumor. Of particular importance are the 3-acetylated conjugates, since the 3-acetylated conjugates are lipid soluble and are retained by the body at the tumor site for a much longer period of time than the unacetylated conjugates. The 3-acetylated conjugates have also been found able to cross the blood-brain barrier.

A number of methods can be used to manufacture the glucuronic acid conjugates according to the present invention, including those disclosed in Rubin, U.S. Patent No. 4,481,195 and Rubin, U.S. Patent No. 4,424,348, the entire contents of both of which are incorporated by reference.

The cytotoxic phenols are conjugated to glucuronic acid by conjugation of the phenol with meth¬ yl(tri-O-acetyl-α-D-glucopyranosyl bromide) -uronate, which is the active form of glucuronic acid, and may be produced in accordance with the teachings of Bollenback, et al., J. Am. Chem. Soc. 77: 3310, 1955. The cytotoxic phenol is introduced to the methyl(tri-0-acetyl-α-D-glucopyranosyl)bromide uronate in a solution of phenol catalyzed by a small catalytic amount of silver oxide. Besides phenol, there may be used, as solvent, quinoline, methyl nitrile or methyl cyanide. silver carbonate may also be used as the catalyst.

Another method of condensation is to use sodium or potassium hydroxide as the condensing agent in aqueous

acetone solution. A stoichiometric excess of cytotoxic phenol is preferably used. The reaction solution is maintained at room temperature for 24 hours or until the reaction to form the triacetyl methyl ester is complete. The triacetyl methyl ester can be used as such or can be converted to the acid form of the conjugate by reaction of the triacetyl methyl ester as obtained above with a 1/2 molar amount of 0.5 N barium hydroxide which is added slowly to this solution to form a white precipitate. Preferably, an excess of barium hydroxide is added until there is no more precipitation.

The addition of 0.5 N sulfuric acid, volume to volume, followed by cooling in ice water for 20 minutes, releases the free glucuronides. The mixture is then filtered, and the supernatant is dried in vacuum and crystallized from ether.

The triacetylated form of the glucuronideis the preferred form of the compounds to be used in accordance with the present invention. However, the free acid form of the conjugates may also be used when a water-soluble form of the conjugate is desired. Therefore, whenever the term "glucuronide compound" is used in the present specification and claims, it is understood to include not only the free glucuronic acid form of the conjugate but also acetylated glucuronic acid conjugates as well as pharmaceutically acceptable salts and esters thereof as discussed hereinabove.

The selectivity of glucuronide compounds toward tumors can be greatly increased and the possible deconjugation of the toxic aglycones in healthy parts of the body can be greatly minimized by administering to the patient, prior to or simultaneously with administration of the glucuronide, an alkalinizing agent which will maintain the pH of the rest of the body at a pH of about 7.4. It is known that the activity of -glucuronidase activity is. substantially nil at a pH of about 7.4. Thus, the

administration of alkalinizing agents such as bicarbonates or other basic salts will substantially decrease and eliminate β-glucuronidase activity which occurs natural¬ ly in certain healthy tissues such as the kidneys, spleen and liver. Such an administration of alkalinizing agent will not diminish the acidity of the tumor cells them¬ selves, however, in view of the naturally low pH of the tumor cells, the mechanism of prior hyperacidification and the lack of substantial blood perfusion through the tumor area, as well as other possible mechanisms. It has been suggested in the literature, in fact, that bicarbonate will actually increase the acidity of the cancer cells, cf.. Gullino ' et al., J.N.C.I. 34 (6): 857-869, 1965. Since the β-glucuronidase activity of the tumor cells is enhanced by acidification, and the β - glucuronidase activity of the rest of the body, particu¬ larly of the kidneys, will be substantially eliminated by alkalinization, the cytotoxic phenols will only be re¬ leased at the tumor site itself-due to deconjugation of the glucuronides by the action of β glucuronidase.

Without the alkalinization step, substantial amounts of toxic materials may be released, for example in the kid¬ neys, and the cytotoxic phenols so released may cause substantial damage to these organs if there is any tyrosinase present at this site. Thus, only through the use of the present invention can glucuronides of phenols which are toxic to tumor cells be used with a great degree of safety and efficacy. The greater the toxicity of the phenols after action of tyrosinase, the more important is the alkalinization step.

Other steps for increasing β-glucuronidase activity at the tumor cells may also be undertaken. One method of accomplishing this is to elevate the temperature of the toxic cells at the time of treatment. This may be done by elevating the temperature of the entire body such as by use of a pyrogenic drug or by elevating the tempera¬ tures solely in the area of the toxic cells, such as by

microwave radiation or electrical current. Raising of the temperature increases -glucuronidase activity, thereby increasing the efficiency of the deconjugation of the glucuronides. , It is known that an elevation of tem- perature of 3°C increases -glucuronidase activity by 50%.

Known pyrogenic drugs include etiocholanolone, progesterone, dinitrophenol, dinitrocresol, and the like. Because dinitrophenol and dinitrocresol are also cytotoxic, the use of these compounds are preferred, particularly when they are administered as the glucuronide. This gives the result that, when the glucuronide is deconjugated at the tumor site, the aglycone will act not only to denature the cytoplasmic protein, but also to raise the temperatures directly in the region of the tumor cells, thus greatly increasing the efficiency of further deconjugation.

Local hyperthermia in the region of suspected tumor cells is preferred to general hyperthermia, because general hyperthermia will also increase the β - glucuronidase activity in healthy cells. However, because of the alkalinization step, this is not a major problem. If the hyperthermia is local, then this provides an additional degree of certainty that the glucuronides will only become deconjugated at the tumor site. The application of microwave treatment directed at the suspected tumor site is one way to achieve total hyperthermia. Due to the different electrical resistance of tumor cells, another method of achieving some degree of local hyperthermia is by administering a low electrical current through the body.

A further manner of increasing -glucuronidase activity selectively at tumor cells is by administration of estrogen to female patients or testosterone to male patients, for tumors which are not estrogen- or testosterone-dependent. It has been reported that these compounds induce -glucuronidase activity in

trophoblastic cells. Since certain tumor cells are known to be trophoblastic, this method is particularly useful for those types of cells. The alkalinization step would prevent damage to .healthy trophoblastic cells. Before treatment of patients in accordance with the present invention, it should be ascertained that the particular type of tumor involved has both a high β - glucuronidase activity as well as a high tyrosinase activ¬ ity. This may be done in a number of ways. One way is to assay tumor cells obtained in a biopsy for β - glucuronidase activity. If such a test is positive, then the pharmaceutical compositions of the present invention may be administered.

A second method is the administration of a glucuronide whose aglycone has been labelled with a radio¬ active isotope. If, upon a full body scan, it is found that the radioisotope is accumulated at any specific areas of the body, then this will indicate not only the location of the tumor but the fact that the tumor has sufficient -glucuronidase activity to deconjugate the glucuronide. After this has been determined, the appropriate amount of the glucuronide of choice may be administered. If there are no tumors present, or if the tumors are of the type which do not have β-glucuronidase activity, then there will be no accumulation of radioisotope in the body as the alkalinization step of the present invention eliminates all ø-glucuronidase activity and the isotope will be passed through the body.

Another method of diagnosing tumors which are treatable by means of the present invention is to test for the presence of free glucuronic acid in the urine. While the presence of glucuronides in the urine is common, the presence of free glucuronic acid in the urine, and partic¬ ularly the presence of increasing amounts of glucuronic acid when tested over a period of several days, is a potent indication of the presence of tumors with β - glucuronidase activity. It is hypothesized that the

presence of free glucuronic acid in the urine in cancer patients is caused by the action of β-glucuronidase in the cancer cells on the intercellular filaments and con¬ nective tissue. Glucuronic acid is a reaction product of such activity because the intercellular filaments and connective tissues are composed of polymers of which glucuronic acid is an element and which are known substrates for the enzyme -glucuronidase.

A method for distinguishing free glucuronic acid from conjugated glucuronides in the urine has previously been disclosed in Rubin, U.S. Patent no. 4,337,760. Both glucuronides and glucuronic acid give a chromogenic com¬ plex with tetraborate in concentrated sulfuric acid which reacts with m-hydroxydiphenyl to create a colored water- soluble complex. When lead acetate is added at an alka¬ line pH, the glucuronides precipitate and the addition of ditizone (dithiosemicarbazone) makes a stable complex with the excess lead. Accordingly, an optical reading may be taken representative of the amounts of total glucuronides and free glucuronic acid after tetraborate and m- hydroxydiphenyl have been added. A second reading may then be taken after the conjugated glucuronides and excess lead have been removed from the aqueous phase by the addition of basic lead acetate and after ditizone has been added. Alternatively, the conjugated glucuronides can be removed by reaction with barium hydroxide. The addition of barium hydroxide to the urine sample will cause precip¬ itation of the conjugated glucuronides but not of the free glucuronic acid. After centrifugation and filtration the conjugated glucuronides are eliminated and what remains is only the free glucuronic acid. A reading representative of the amount of free glucuronic acid many then be taken. The alternative procedure bypasses the necessity of the use of ditrizone. in the urine test for glucuronidase activity, normal patients exhibit between 200 and 400 mg per 24 hours of free glucuronic acid in the urine. Cancer pa-

tients with well developed tumors which have β - glucuronidase activity show greater than 200 to 7000 mg per 24 hours of free glucuronic acid. Accordingly, using this above test, if more than about 400 mg per 24 hours of free glucuronide is exhibited, this is an excellent indi¬ cation of the presence of tumors having a high β - glucuronidase activity.

A negative indication on this urine test will not conclusively rule out the presence of tumors having β-glucuronidase activity, because tumors in their ini¬ tial stages, although they might have β-glucuronidase activity, might not release sufficient free glucuronic acid to cause a positive reading of the urine. Therefore, the urine test should be repeated, and if an increasing amount of free glucuronic acid is found, then this is another indication of the presence of a tumor having β - " glucuronidase activity.

Although 4-hydroxyanisole and other cytotoxic phenols may not generally be toxic to healthy cells, when these substances are substrates to tyrosinase, they are converted to toxic metabolite which have their dominant effect inside the cells, where they are produced (i.e., melanoma cells and melanocytes) , as tyrosinase is known to convert several phenols (e.g., its natural substrate, tyrosine) to catechols and quinones which react strongly with SH groups.

Tyrosinase activity of tumor cells can be deter¬ mined by assaying a sample obtained from a biopsy by the method of Pomerantz, . Biol. Chem. 241: 161, 1966, using L-[3.5- 3 H] -tyrosine (Amersham TRK 200). Using this meth¬ od, Wallevik et al. (op_. cit.) determined that melanotic melanoma had the greatest tyrosinase activity, while bladder carcinoma and amelanotic melanoma had less but measurable tyrosinase activity. Skin fibroblasts were found to have no tyrosinase activity.

Once it has been determined that the patient has a tumor having both tyrosinase and β-glucuronidase

activity, the first step of the treatment is to administer a dose of glucose as, for example, 100 g of honey, glu¬ cose, or other simple sugar. Approximately one hour later, an intravenous drip is begun of a solution in distilled water containing approximately 10% glucose and 60 milliequivalents sodium bicarbonate. Approximately 1 liter is administered, assuming no contraindications, and the pH of the urine is checked to determine that it has reached a pH of approximately 7.4. This will establish that the system has become alkalinized and it is now safe to administer the glucuronide. Another liter of the same glucose-bicarbonate solution, but also including the desired amount of glucuronide, is then administered. This is repeated daily as needed. if there are contraindications for the adminis¬ tration of bicarbonate, then an antacid may be orally ~ administered. This antacid may be any conventional antacid such as sodium bicarbonate, magnesium bicarbonate, alumi¬ num hydroxide, aluminum magnesium silicate, magnesium carbonate, magnesium hydroxide, magnesium oxide, or the like. The important criterion is that the pH of the urine become approximately 7.4 and remain so during treat¬ ment.

The hyperacidification of the tumor cells is caused by a hyperglycemic condition in the patient. Therefore, any hyperglycemic agent may be used as the hyperacidification agent, as, for example, fructose, galactose, lactose or glucagon. Furthermore, it should be understood that this hyperglycemic condition may be ef- fected in any known manner. For example, if the patient is diabetic, then the condition can be brought about by decreasing the insulin administration.

Any agent which will raise the pH of the urine to approximately 7.4 can be used as the alkalinizing agent, including sodium or potassium bicarbonate or citrate, or other basic salts or antacids. While it is

preferred that these agents be administered intravenously, they may be administered orally.

When the term "approximately 7.4" is used in the present specification and claims, with respect to the pH level to be maintained in the rest of the body, it should be understood that a pH level slightly above or below 7.4 may be used, although this is not preferred. As the pH deceases from 7.4, the ø-glucuronidase activity in¬ creases until the optimal pH is reached. Furthermore, below pH 7.0 the rest of the body will not be alkaline but will be acid. Above 7.4 the danger of alkalosis increases without any substantial further decrease in β - glucuronidase activity. A pH level of 7.4 is preferred, as this is physiological pH and cannot be harmful to the body, and it is known that the β -glucuronidase activity in healthy organs is substantially nil at this pH level.

The dosage of the compounds administered should be monitored to avoid any side effects due to the massive release of toxins caused by the dying cancer cells. It ma be preferable to treat the patient with the compounds of the present invention in short courses of several days, leaving several days in between to allow any toxins re¬ leased by the dying cancer cells to leave the body before continuing with treatment. Besides intravenous administration, the acid form of the glucuronide conjugates may be administered by any means of parenteral administration. However, the free acid form of the glucuronides should not be administered orally, as it is known that ø-glucuronidase is present i the digestive tract. The tri-acetylated conjugates, however, can be administered orally, as the β - glucuronidase in the digestive tract does not affect the acetylated conjugates.

The amount of glucuronide conjugate to be admin- istered to any given patient must be determined empiri¬ cally and will differ depending upon the condition of the patient. Relatively small amounts of the conjugates can

be administered at first, with steadily increasing dosages if no adverse effects are noted. Of course, the maximum safe toxicity dosage as determined in routine animal toxicity tests should ever be exceeded. Optimally, the concentration of glucuronide conjugates to be administered may be sufficient to admin¬ ister a concentration of from about 5 x 10"*M to about 5 x 10" 6 M of the phenolic cytotoxic compound to the tumor site. it is clear that any tumor cells having both ø-glucuronidase activity and tyrosinase activity may be treatable in accordance with the present invention, with the remaining organs of the body being protected by the alkalinization step. Tumors which are known to have β - glucuronidase activity include solid breast tumors and their metastases, bronchogenic carcinoma and its metasta- ses, and lymphomas, as well as lung carcinoma, colon carcinoma, testicular carcinoma, hepatic carcinoma, pan¬ creatic carcinoma, ovarian carcinoma, leukemia, bronchogenic carcinoma, prostate carcinoma, Hodgkin's disease, and rectal carcinoma. Tumors which have high tyrosinase activity, as noted above, include melanoma, amelanotic melanoma, and breast carcinoma, and bladder carcinoma, as well as a number of others noted above. it is also known that neoplasms which do not have high -glucuronidase activity, and therefore cannot be treated in accordance with the present invention, include leukemias. It must be understood, however, that these lists are not meant to be complete, and that the prior art is aware of many other tumors that have β - glucuronidase and tyrosinase activity. However, whether or not the art is presently aware that any given tumor has β-glucuronidase or tyrosinase activity, this can be determined by any of the various methods of diagnosis discussed in the present specification. If it is deter¬ mined that the tumor does indeed have both β - glucuronidase and tyrosinase activity, the therapeutic

treatment of the present invention can ϋ effectively used.

When it is desired to induce hyperthermia to increase -glucuronidase activity, a method should be selected by which the temperature is raised as much as possible without risking damage to healthy portions of the body, such as the eyes. An increase of about 2°C for whole body hyperthermia and as much as 4.5°C for local hyperthermia is preferred. The hyperthermia should be timed to last about an hour at the time of greatest glucuronide concentration at the tumor site. For example, when local microwave treatment is selected, it should begin about one half hour after commencement of the intra¬ venous conjugate drip and be continued for about one hour. The proper dosage of known pyrogens to achieve the desired degree of hyperthermia would be known to those skilled in the art, or could be easily empirically determined. A dosage of about 30 mg/day of dinitrophenol, for example, would be appropriate. Because the triacetylated form of the conjugate is not affected by β-tyrosinase in the digestive tract, this form of the conjugate can be administered orally without loss of activity. Moreover, it has been found that, because the triacetylated form of the conjugate is lipid-soluble, it is retained in the body for a much longer time than the free acid form of the conjugate. ^ The tri- cetylated form of the conjugate provides one addi¬ tional level of protection for normal cells, as the pheno¬ lic compounds is not released in the body until the acetyl groups are removed and the glucuronic acid is removed from the phenolic compound. Primitive cells can produce acetylase along with a great variety of other enzymes, and this acetylase removes the acetyl groups from the conju¬ gate. The more anaplastic (more immature) the tumor cells, the more enzymes they produce, so that the triacetylated form of the drug is more selectively toxic to tumor cells than even the conjugated form. Thus, since

two steps are required to liberate the phenolic compound, the conjugates are even more preferentially delivered to the site of an active tumor than are the acid form of the conjugates. When estrogen or testosterone are to be adminis¬ tered, a dosage of 5-15 mg/body weight/day would provide the desired inducement of -glucuronidase activity.

To treat patients suffering from cancers which exhibit tyrosinase activity, the phenolic compounds are administered in the form of acetylated glucuronic acid conjugates. Capsules are formulated, generally containing approximately 0.6 gram/capsule of active ingredient. Generally, five capsules three times daily, providing nine grams/day of active ingredient are administered. The patient's serum is measured after a loading dosage is administered of the compound to maintain a level of ap¬ proximately 1 rriM of compound in the serum.

EXAMPLE 1 A patient suffering from mammary intraductular poorly differentiated adenocarcinomas was treated with 5 capsules of 0.6 grams/capsule of triacetylated glucuronic acid conjugate of 4-hydroxyanisole. Tumors involved five conjoined axillary lymph nodes. The total tumor size was about 8 x 6 x 4 cm in the right breast. The dosage admin¬ istered, once a level of 1 mM of triacetylated glucuronic acid conjugate of 4-hydroxyanisole in serum was attained, was five capsules of 0.6 grams active ingredient, admin¬ istered orally three times a day. Shortly after the first dose was administered, the patient experienced sever sharp pains at the locus of the tumor less than one hour after administration of the drug. The pain subsided after two hours, and soon there¬ after the tumor was observed to shrink. After three weeks of treatment, the total tumor size had shrunk to about 3 3 x 3 cm, and the skin sur¬ face above the tumor site that was red and excreted pus

and had a cauliflower-like appearance became almost normal in appearance. After six weeks of treatment, the redness had disappeared and the cauliflower had shrunk almost completely; normal skin covered most of what had been the tumor area. The armpit lymph nodes had disappeared.

EXAMPLE 2

A patient suffering from mammary intraductular poorly differentiated adenocarcinoma was treated as above. within six weeks, the tumor had almost completely disap¬ peared. No side effects were observed.

EXAMPLE 3.

A patient with malignant melanoma which had metastasized to the brain was near death. Capsules con¬ taining 0.6 gram of triacetylated glucuronic acid conju¬ gate of -hydroxyanisole were administered to the patient to bring the serum concentration of the active ingredient to 1 M, and then treatment was continued at a level of five 0.6 gram capsules, three times daily. After five months of therapy, MRI examination showed considerable shrinkage of the brain tumor, and the patient appears to be recovering fully.

EXAMPLE 4

A patient with lung cancer had the lung tumor removed surgically. Two months after surgery, the patient suffered loss of balance and equilibrium, accompanied by epileptic-like seizures. MRI examination revealed a tumor encompassing 1/4 of the occupital area of the brain.

Capsules containing 0.6 gram of triacetylated glucuronic acid conjugate of 4-hydroxyanisole were administered to the patient to bring the serum concentration of the active ingredient to 1 iriM, and then treatment was continued at a level of five 0.6 gram capsules, three times daily.

After two months of treatment, the patient exhibited no more symptoms, and had returned to work.

Examples 3 and 4, which describe the treatment of brain tumors, demonstrate that the triacetylated form of the phenolic-glucuronide conjugate are able to cross the blood-brain barrier to reach the tumor site.

The conjugates of the present invention can be administered to patients suffering from tyrosinase-depen¬ dent cancers at doses ranging from about 1-15 grams/day of total dosage. Although it has been found that maintaining a serum level of about 1 mM of conjugate is desirable, serum levels ranging from about 0.1 mM to about 10 mM can be used, depending upon the patient's response to the treatment.

The conjugates of the present invention can be combined with a pharmaceutically acceptable carrier there¬ fore, and optionally other therapeutic and/or prophylactic ingredients. The carriers must be "acceptable" in the sense of being compatible with the other ingredients of the formulation and not deleterious to the recipient thereof.

Pharmaceutical formulations suitable for oral administration wherein the carrier is a solid are most preferably presented as unit dose formulations such as boluses, capsules, and the like, as well as sachets or tablets each containing a predetermined amount of the active ingredient. A tablet may be made by compression or molding, optionally with one or more accessory ingredi¬ ents. Compressed tablets may be prepared by compressing in a suitable machine the active conjugate in a free- flowing form, such as a powder or granules optionally mixed with a binder, lubricant, interdiluent, lubricating, surface active or dispersing agent. Molded tablets may be made by molding the active conjugate with an inert liquid diluent. Tablets may be optionally coated and, if un- coated, may optionally be scored. Capsules may be pre¬ pared by filling the active conjugate, either alone or in admixture with one or more accessory ingredients, into the

capsule cases and then sealing them in the usual manner. Cachets are analogous to capsules wherein the active conjugate together with any optional accessory ingredient is sealed in a rice paper envelope. Pharmaceutical formulations suitable for oral administration in which the carrier is a liquid may conve¬ niently be presented as a solution in an aqueous liquid or a non-aqueous liquid, or an an oil-in-water or water-in- oil liquid emulsion. Pharmaceutical formulations suitable for parenteral administration are conveniently presented in unit does or multi-dose container which are sealed after introduction of the formulation until required for use.

It should be understood that in addition to the aforementioned carrier ingredients the pharmaceutical formulations described above may include, as appropriate, one or more additional carrier ingredients such as dilu¬ ents, buffers, flavoring agents, binders, surface active agents, thickeners, lubricants, preservative (including anti-oxidants) and the like, and substances included for the purpose of rendering the formulation isotonic with the blood of the intended recipient.

The pharmaceutical formulations may be any formulation in which the active compound may be adminis- tered and include those suitable for oral or parenteral (including intramuscular and intravenous) administration. The formulations may, where appropriate, be conveniently presented in discrete dosage units and may be prepared by any of the methods well known in the art of pharmacy. All of the methods include the step of brining into associa¬ tion the active compound with liquid carriers or finely divided solid carriers of both and then, if necessary, shaping the product into the desired formulation.

The foregoing description of the specific em- bodiments will so fully reveal the general nature of the invention that others can, by applying current knowledge, readily modify and/or adapt for various applications such

specific embodiments without departing from the generic concept, and therefore such adaptations and modifications are intended to be comprehended within the meaning and range of equivalents of the disclosed embodiments. It is to be understood that the phraseology or terminology herein is for the purpose of description and not of limi¬ tation.