None.
None.
A. Polychlorinated Dibenzo-p-Dioxins
Polychlorinated dibenzo-p-dioxins (“PCDDs”), also commonly referred to as “dioxins,” are among the most toxic xenobiotics known. They rank high in the awareness of both the general public and regulatory agencies world-wide. They are ubiquitous compounds of high environmental and biological persistence. Dioxins are subject to biomagnification and, more importantly, bioaccumulation. Therefore, the exposure of humans, being at the top of the food chain, is inevitable. Their toxicological properties, which depend on the pattern of chlorination, in combination with high lipophilicity and an extremely low rate of biotransformation, make PCDDs to a potential risk for human health and the environment.
PCDDs display different toxic potencies among congeners. The lowest LD50 values were observed for congeners having chlorine substituents in the four lateral positions. The potency of PCDDs relative to each other is expressed by toxic equivalency factor (“TEF”) values, which were established by NATO and WHO. 2,3,7,8-Tetrachlorodibenzo-p-dioxin (TCDD) and 1,2,3,7,8-pentachlorodibenzo-p-dioxin (PeCDD) are the two most toxic members with TEF-values defined as 1 (WHO).
LD50 values TCDD vary across species, with guinea pigs being the most sensitive animals (LD50=2.1 μg/kg (Schwetz et al. 1973)) and hamsters being the most resistant (LD50=1157−5051 μg/kg (Eisler 1986)). TCDD has an LD50 of 22.0 μg/kg in male and 45.0 μg/kg in female rats (Schwetz et al. 1973). There is also a very pronounced inter-strain variability as shown by about a 300-fold difference (10 μg/kg and >3000 μg/kg, respectively) between Long-Evans and Han Wistar rats (Pohjanvirta et al. 1990; Pohjanvirta et al. 1993).
PCDDs' detrimental effects are widely known and quite diverse. They include a wasting syndrome (Harris et al. 1973; Seefeld et al. 1984a), carcinogenicity (Luster et al. 1990), endocrine effects on ovulation (Li et al. 1995a; Li et al. 1995b), inhibition of 17-β estradiol-induced uterotrophy (Gallo et al. 1986; Romkes et al. 1989), thymic atrophy (Gupta et al. 1973), and immunosuppression (Miller et al. 1977). In humans, chloracne is the most common symptom of elevated TCDD body burdens. In susceptible individuals, symptoms may occur at TCDD concentrations of 800 ppt based on serum lipid content, although differential diagnosis of acne-like skin conditions is notoriously difficult in adolescents. Most individuals do not show signs below 11,000 ppt (Williams & Wilkins 1992), which corresponds to doses of about 100 μg/kg TCDD (Young 1984). Investigations after accidental exposure also link TCDD to increased risk of digestive tract and respiratory tract cancer, the occurrence of which was elevated in smokers (Ott & Zober 1996). Liver cancer was unequivocally demonstrated in animals only (Kociba et al. 1978; Huff 1992). Out of all the effects shown to occur in animals and humans (Skene et al. 1989) the number one concern for human health is carcinogenicity (Fingerhut et al. 1991). Other effects claimed to occur in humans include hyperkeratinosis, hyperpigmentation, hirsutism, liver damage, elevated blood fat content and cholesterol, intestinal effects with diarrhea, cardiovascular effects, headache, peripheral neuropathy, reduced sensory performance, loss of libido, and psychiatric changes (Abel 1987). Some of these effects are also age-related and therefore difficult to assess if indeed dioxins are contributory or not. In animals, PCDDs are also fetotoxic and teratogenic (Neubert & Meister 1987).
B. Phenothiazines
Phenothiazines are similar in structure to dioxins but have a large number of medical and other uses. Phenothiazines have been used as textile dyes for centuries, especially for silk. Today, phenothiazines are a class of compounds with a multitude of uses. Without any doubt, the most important use lies in medicine. Their application ranges from the most prominent area of antipsychotics/neuroleptics (Shen 1999) and sedatives, anti-histamines and anti-emetics to the treatment of migraine (Stiell et al. 1991), diabetes (Pandey & Pathak 1999), cardiac irregularities (Fauchier et al. 1991; Vizir et al. 1991) and many more.
Unexpected death is a serious side effect of sedative phenothiazines (Mehtonen et al. 1991). Studies on piglets revealed a decrease in the spontaneous occurrence of swallowing, and an increased occurrence of sleep apnea. Thus, the effectiveness of protection mechanisms for the trachea during sleep is decreased (McKelvey et al. 1999).
Most toxic effects are related to exaggerated pharmacological responses. The most troublesome side-effects are related to the extra-pyramidal system. A detailed accounting of them may be found in Goodman & Gilman (Goodman & Gilman 2001).
Classical phenothiazines offer open sites on their aryl rings for the oxidative phase I enzymes of the class cytochrome P450. Ring-hydroxylated metabolites are common and have intrinsic pharmacological effects themselves (Nowak et al. 1990). The phenothiazines' N-substituents possibly offer more sites for metabolic interactions in addition to the common cleavage of the N—R bond (Choo et al. 1990). The formation of the sulfoxide was studied in Aspergillus niger (Parshikov et al. 1999) and is a likely metabolic pathway in higher organisms, as a product of cytochrome P450 activities.
The pharmacological effects of phenothiazines are thought to be directed by different N-substituents. Aliphatic N-substituents (derivatives promazin, chlorpromazine and promethazin) show strong sedative effects. Piperidyl N-substituents (the pecazin-types, e.g. pericazin, thioridazin) have a medium sedative potency. Piperazinyl N-substituents (members of the perphenazin-class) have only weak sedative properties but act as antihistamines, and are strongly anti-psychotic and anti-emetic.
The vast majority of phenothiazines have only been developed for the effects of their N-substituents. Only a handful of studies have been found that investigated the effects of ring-substituents (Jovanovic & Biehl 1987). That study was a comparison between chlorpromazine and 2-methoxypromazine. The latter proved to have no effects compared to its prominent analogue's properties. A likely explanation evokes differences in pharmacokinetics. Due to rapid de-methylation, the half-life of the 2-methoxy-analogue is greatly shortened.
Several alkoxylated phenothiazine dertivatives have also been proposed. See Quelet et al., “Synthesis of 2,3-dimethoxy-10-methylphenothiazines,” Fac. Sci., Paris, Compt Rend. (1964), 258(13); Japanese Patent No. 69-79103 to Ichihara et al. entititled “Methoxy-substituted 10-bromoacetylphenothiazines” (1973); Japanese Patent No. JP-70-6422 to Ichihara et al. entitled “Alkoxy-substituted 10-iodoacetylphenothiazines” (1973); all of which are incorporated by reference. In addition, a few researchers have synthesized several halogenated derivatives of phenothiazines. See Ma et al., “Fluoroescence Study on Phenothiazine Halogenate Derivatives,” Test and Analysis Center Shanzi University, Guangpuzue Yu Guangpu Fenxi, 19(2), 250-252 (1999) (3-bromo-N-ethyl-phenothiazine); Nodiff et al., “Synthesis of Phenothiazines”, Temple University,” Journal of Organic Chemistry, 26, 824-28 (1961); Kumar et al, “Synthesis of 1- and 3-chlorophenothiazines”, University of Rajasthan, Heterocyclic Communications, 8(5), 447-450 (2002); Sharma et al., “Synthesis of Phenothiazines via Smiles Rearrangement,” University of Rajasthan, Heterocylic Communications, 8(2), 195-198 (2002) all of which are incorporated by reference. In addition, Li (1988) and Huang (1997) reported the synthesis of a tetra-substituted derivative in “Synthesis of N-ethylphenothiazine and its derivatives” and “Fluorescence spectra study on 2,3,7,8-tetrachloro-N-ethyl-phenothiazine”, respectively, both of which are incorporated by reference. However, further studies using the synthesis techniques described in these latter Chinese publications indicate that the compound synthesized was actually 1,3,7,9-tetrachloro-N-ethyl-phenothiazine.
The present invention is directed to novel phenothiazine derivatives and their use in the treatment of diabetes mellitus (type I and type II), ovulation inhibitor (contraceptive), cancer chemotherapeutic agent, anti-obesity drug (body weight regulator), immunostimulant, and life-prolonging drug.
An object of the present invention is to provide novel phenothiazine derivatives.
In accordance with the present invention, phenothiazines substituted with three or four halogens or trihalomethyl groups at the 2,3,7, and 8 positions are provided.
In one aspect of the present invention, phenothiazine compounds having the following formula are provided:
wherein X1, X2, X3, and X4 are independently hydrogen, halogen, or trihalomethyl, and not more than one of X1, X2, X3, and X4 is hydrogen; and
In another aspect, one of X1, X2, X3, and X4 is halogen; and at least two of X1, X2, X3, and X4 are independently trihalomethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In still another aspect, two of X1, X2, X3, and X4 are independently halogen; and at least one of X1, X2, X3, and X4 is independently trihalomethyl; and R is H or lower alkyl group; and the sulfur is optionally oxidized.
In another aspect of the present invention, at least three of X1, X2, X3, and X4 are independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In a further aspect, three of X1, X2, X3, and X4, are independently F or trifluoromethyl; and R is lower alkyl.
In yet another aspect, at least three of X1, X2, X3 and X4, are independently Cl or trifluoromethyl; and R is lower alkyl.
In another aspect, at least three of X1, X2, X3, and X4 are halogen; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In still another aspect, X1, and X2 are both Cl; and at least one of X3, and X4 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In a further aspect, X1, and X3 are both Cl; and at least one of X2, and X4 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In a further aspect, X1, and X4 are both Cl; and at least one of X2, and X3 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In another aspect, X2, and X3 are both Cl; and at least one of X1, and X4 are halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In still another aspect, X1, and X2, are both F; and at least one of X3, and X4 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In a further aspect, X1, and X2 are both I; and least one of X2, and X4 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In still a further aspect, X1, and X2 are both Br; and at least one of X2, and X4 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In yet another aspect, X1 is Cl and X3 is Br; and at least one of X2, and X4 is independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In still another aspect, X1, X2, and X3, are all Cl; and at X4 is hydrogen, halogen, or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In still another aspect, the phenothiazine compound is selected from the group consisting of 2,3,7-trichlorophenothiazine; 2,3,7-trichlorophenothiazine-5-oxide; 2,3,7-trichoropheonothiazine-5,5-dioxide; N-methyl-2,3,7-trichorophenothiazine; N-methyl-2,3,7-trichorophenothiazine-5-oxide; N-methyl-2,3,7-trichorophenothiazine-5,5-dioxide; 2,3,8-trichlorophenothiazine; 2,3,8-trichlorophenothiazine-5-oxide; and 2,3,8-trichoropheonothiazine-5,5-dioxide; N-methyl-2,3,8-trichorophenothiazine; N-methyl-2,3,8-trichorophenothiazine-5-oxide; N-methyl-2,3,8-trichorophenothiazine-5,5-dioxide.
In another aspect, X1, X2, and X3, are all F, and X4 is hydrogen, halogen, or trifluoromethyl.
In still another aspect, the phenothiazine compound is selected from the group consisting of 2,3,7-trifluorophenothiazine; N-methyl-2,3,7-trifluorophenothiazine; N-methyl-2,3,7-trifluorophenothiazine-5-oxide, 2,3,7-trifluorophenothiazine-5,5-dioxide, 2,3,8-trifluorophenothiazine; N-methyl-2,3,8-trifluorophenothiazine; N-methyl-2,3,8-trifluorophenothiazine-5-oxide, 2,3,8-trifluorophenothiazine-5,5-dioxide.
In another aspect, X1, X2, and X3, are all Br, and X4 is hydrogen, halogen, or trifluoromethyl.
In still another aspect, the phenothiazine compound is selected from the group consisting of 2,3,7-tribromophenothiazine; 2,3,7-tribromophenothiazine-5-oxide; 2,3,7tribromopheonothiazine-5,5-dioxide; N-methyl-2,3,7-tribromophenothiazine; N-methyl-2,3,7-tribromophenothiazine-5-oxide; N-methyl-2,3,7-tribromophenothiazine-5,5-dioxide; 2,3,8-tribromophenothiazine; 2,3,8-tribromophenothiazine-5-oxide; and 2,3,8-tribromopheonothiazine-5,5-dioxide; N-methyl-2,3,8-tribromophenothiazine; N-methyl-2,3,8-tribromophenothiazine-5-oxide; N-methyl-2,3,8-tribromophenothiazine-5,5-dioxide.
In yet another aspect, each of X1, X2, X3, and X4 are independently halogen or trifluoromethyl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In another aspect, X1, X2, X3, and X4 are all Cl; and R is H or lower alkyl; and the sulfur is optionally oxidized.
In another aspect of the present invention, the phenothiazine compound is selected from the group consisting of 2,3,7,8-tetrachlorophenothiazine; 2,3,7,8-tetrachlorophenothiazine-5-oxide; 2,3,7,8-tetrachlorophenothiazine-5,5-dioxide; N-methyl-2,3,7,8-tetrachlorophenothiazine; N-methyl-2,3,7,8-tetrachlorophenothiazine-5-oxide; N-methyl-2,3,7,8-tetrachlorophenothiazine-5,5-dioxide.
In another aspect of the present invention, X1, X2, X3, and X4 are all F.
In another aspect of the present invention, the phenothiazine compound is selected from the group consisting of 2,3,7,8-tetrafluorophenothiazine; 2,3,7,8-tetrafluorophenothiazine-5-oxide; 2,3,7,8-tetrafluorophenothiazine-5,5-dioxide; N-methyl-2,3,7,8-tetrafluorophenothiazine; N-methyl-2,3,7,8-tetrafluorophenothiazine-5-oxide; and N-methyl-2,3,7,8-tetrafluorophenothiazine-5,5-dioxide.
In another aspect, X1, X2, X3, and X4 are all Br.
In still another aspect of the present invention, the phenothiazine compound is selected from the group consisting of 2,3,7,8-tetrabromophenothiazine; 2,3,7,8tetrabromophenothiazine-5-oxide; 2,3,7,8-tetrabromophenothiazine-5,5-dioxide; N-methyl-2,3,7,8-tetrabromophenothiazine; N-methyl-2,3,7,8-tetrabromophenothiazine-5-oxide; and N-methyl-2,3,7,8-tetrabromophenothiazine-5,5-dioxide.
In still another aspect, X1, X2, X3, and X4 are independently Cl or trifluoromethyl.
In yet another aspect, X1, X2, X3, and X4 are all trifluoromethyl.
Still another object of the present invention is to provide a phenothiazine compound that causes wasting syndrome at a low level of toxicity.
Another object of the present invention is to provide a phenothiazine compound which alters the set-point for body weight.
Another object of the present invention is to provide a compound which can be used in the treatment of obesity
Yet another object of the present invention is to provide a phenothiazine compound which has cancer-inhibiting effects.
Another object is to provide a phenothiazine compound that operates as a contraceptive by inhibiting ovulation.
Another object of the present invention is to provide a drug which is useful in the treatment of type I and type II diabetes mellitus.
Still another object of the present invention is to provide a compound which operates as an immunostimulant, inducing both a cell mediated and humoral response.
In yet another aspect of the present invention, the compounds are useful to prolong life, and act as insulin-like growth factor (IGF-1) inhibitors.
Thus, still another object is to provide a phenothiazine derivative with a substitution pattern structurally similar to the potent dioxin congener TCDD.
As found in the present invention, the compounds of the present invention do show TCDD-like effects, but they are exhibited at a lower level of toxicity. The hallmark of TCDD exposure in laboratory animals, the wasting syndrome, was shown in animals treated with 2,3,7,8-tetrachlorophenothiazine (TCPT); however, the effects after p.o. dosing were shown at dose rates that suggest a peroral potency of TCPT that is by four orders of magnitude lower. Alteration of the set-point for body weight was observed in agreement with reports on TCDD. It will be appreciated that people are influenced by physical ideals suggested by society and media. Conventional weight-loss programs, which are based on conscious or pharmacological food-restriction, mostly result in a bounce-back of the bodyweight to levels prior to dieting once they are terminated. Influencing bodyweight by liposuction or partial gastrectomy are desperate, high-risk, and invasive methods to regain control. TCPT with its lowering effects on the regulation level of bodyweight could represent an attractive alternative on this market.
The inhibiting effects of TCDD on ovulation in rats demonstrate its potential as endocrine disrupter. Studies with TCPT in guinea pigs have not resulted in the same observations; however, no investigations of the effects of TCDD on guinea pigs have been conducted in that field, either. Therefore, an effect of TCPT in other species, such as rats, yet has to be investigated and is still likely. From an inhibition of ovulation by TCPT, a potential application as a “morning after pill” is within the scope of the present invention. TCPT could also be used as an alternative contraceptive, completely inhibiting menstruation as some oral contraceptives do that are already on the market. If combined with anti-cancer properties, TCPT could become the contraceptive of choice for many women.
The term “halogen atom” as used in the definition means fluorine, chlorine, bromine, iodine, etc.
The term “therapeutically effective amount” refers to an amount sufficient to effect treatment when administered to a patient in need of treatment.
The term “treatment” as used herein refers to the treatment of a disease or medical condition in a patient, such as a mammal (particularly a human) which includes:
A therapeutically effective amount of the compounds of the present invention may be administered to any animal, preferably a mammal (such as apes, cows, horses, pigs, boars, sheep, rodents, goats, dogs, cats, chickens, monkeys, rabbits, ferrets, whales, and dolphins), and more preferably a human.
The following examples further illustrate the present invention in detail but are not to be construed to limit the scope thereof.
A first time synthesis of 2,3,7,8-tetrachlorophenothiazine, described below, was successfully conducted. The usual synthetic pathways for phenothiazines proved to be insufficient to overcome the deactivating effects of the four chlorine atoms on ring cyclization. Out of a multitude of attempted synthetic pathways, only an optimized Ullmann coupling yielded the target compound, shown in the last of three reaction steps depicted below.
TCPT was formed in a short time-window and subsequently decomposed
under the rough reaction conditions. At the point of maximum yield (24 h), the reaction was terminated and worked up. The yield of 5.2% after sophisticated purification was low, but enough to generate gram quantities under up-scaled reaction conditions. The first two steps of the synthesis proceeded almost quantitatively once the proper conditions had been worked out.
Details of the three-step procedure for the production of TCPT are set-forth below:
Step 1:
Preparations:
First, the molecular sieves 3 Å were activated by grinding up with a mortar. The powder was flame-heated under a vacuum and purged with argon gas. The sieves were stored under argon for future use.
Experimental Set-up:
The experimental set-up included an oven-dried round bottom flask (“rbf”) with a stirring magnet and reflux condenser, under argon. The maximum upscaled was 1 L rbf, 500 ml methylene chloride, 100 mmole scale.
Procedure:
The reagents were added into the flask under a stream of argon, with solids added first, and the solvent last. The reflux condenser was set-up and kept under argon throughout the reaction. The rbf was lowered into a pre-heated oil bath at about 55-60° C. and refluxed for 16-21 h. The reaction was checked for completion by thin liquid chromatography (“TLC”) with toluene.
Work-Up:
The mixture was gravity-filtrated through a cellulose filter, collected, and the solid washed with methylene chloride for maximum yield. The solvent was then evaporated, and the mixture was dried on an oil pump over night. The product was a yellow solid.
Purification:
Product was yielded in high purity.
Identification
1H-NMR (400 MHz, CDCl3)
d(ppm)=8.41 (1H, H1), 7.83 (1H, H6), 7.75 (1H, H4), 6.79 (1H, H9)
Step 2:
Preparations:
The iron filings were first activated: They were washed with water until the effluent was almost colorless. Concentrated hydrochloric acid was added and reacted for about a minute. The mixture was washed with distilled water and the surface of the filings was inspected. The procedure was repeated at least three times. After the surface appeared rust-free and metallic, it was washed with HPLC grade ethanol, then with HPLC grade diethyl ether. The mixture was then dried on an oil pump and then stored in an air-tight container for future use.
Experimental Set-up:
The set-up used a three-neck rbf with a mechanical stirrer and reflux condenser. The maximum upscaled was 3 L three-neck rbf, 1.5 L acetone, 0.375 ml concentrated acetic acid, 0.375 ml distilled water, 100 mmole scale.
Procedure
KWF1 was added in acetone in the rbf and heated to reflux. When dissolved, glacial acetic acid and water were added. The yellow suspension was stirred under heat to reflux. Activated iron filings were then added in 30 min intervals (3.5 mole equivalents at a time). The reaction progress was checked by TLC (95% hexanes, 5% ethyl acetate) and more iron was added.
Work-Up
The hot reaction mixture was filtrated through Celite®, most easily on a wide column. The filter agent was washed thoroughly for quantitative yield. The pH-value of the filtrate was adjusted to 8 with sodium hydroxide solution. KWF2 was then extracted from the liquid with diethyl ether. The organic phase was shaken with sodium carbonate solution and brine and then dried over magnesium sulfate before the solvent was evaporated. The crude product was a light-brownish solid.
Purification
The impurities have a higher solubility in hexanes than KWF2 does. Therefore, the crude product was suspended in hexanes at room temperature and stirred for about 1 hour. 250 ml hexanes were used for 15 g crude product. The purified KWF2 was filtrated off and the solid dried under oilpump vacuum. The product was a yellow solid.
Identification
1H-NMR (400 MHz, CDCl3)
d(ppm)=7.53 (1H, H6), 7.48 (1H, H9), 6.96 (1H, H4), 6.68 (1H, H1), 4.36 (2H, NH2)
Step 2
Step 3
Preparations:
First, clean copper iodide was prepared. A solution of 375 g potassium iodide in 300 ml distilled water was prepared. Next, 60 g copper iodide was added and stirred for 5 minutes at room temperature. Decolorizing charcoal was added and stirring was continued for another 5 minutes. The mixture was filtered through Celite®. About 1.5 L distilled water was added to the liquid. The precipitated copper iodide was collected by vacuum filtration, washed with HPLC grade ethanol and then washed with HPLC grade diethyl ether. The purified copper iodide was dried on a oil pump and protected from light. The material was stored dark and under argon for future use.
Fresh copper was prepared within one hour of usage. About 0.500 g copper sulfate (CuSO4.5H2O) and 0.131 g zinc dust were used to prepare fresh copper for a 10 mmole scale. The copper sulfate was dissolved in distilled water and cooled to 0° C. with an ice bath. At 0° C., zinc dust was added. After complete precipitation (i.e., decolorization), the supernatant was decanted, and the precipitate was washed with 1N hydrochloric acid. The mixture was stirred until no generation of hydrogen gas was noted. The mixture was kept at 0° C., decanted, and washed with distilled water until neutral. Next, the mixture was decanted and washed with HPLC grade ethanol and stored under ethanol until shortly before use. Lastly, the mixture was decanted and washed with Sure Seal® DMF and flushed into a reaction vessel.
Experimental Set-up:
To set-up, an oven-dried rbf with a stirring magnet and reflux condenser, under argon was used. The maximum upscaled was 2 L rbf, 1 L dimethyl formamide, 25 mmole scale.
Procedure
All reagents and catalysts were added under a stream of argon. The rbf was lowered into a pre-heated oil bath at about 185° C. and stirred for about 24 hours. A check of the reaction mix by TLC (95% hexanes, 5% ethyl acetate) revealed still existing starting material, but with increasing reaction time, another product was formed and the amount of target compound decreased.
Work-Up
The heat was turned off, and the oil bath was removed. When the rbf was about hand-warm, the mixture was poured into double the volume of ice water under vigorous stirring. The addition of sodium chloride enhanced precipitation considerably. The precipitate was allowed to age and then filtrated by gravity through a cellulose filter (for a 25 mmole scale, a filter paper of 50 cm diameter and a kitchen-drainer proved most practical). The precipitate was washed with distilled water, then vacuum-filtered and dried. The crude product was then dissolved/suspended in tetrahydrofuran (2 L THF for a 35 mmole scale) to extract KWF3 in addition to other products. Because the KWF3 degraded when kept in acetone for longer periods of time, THF was used. The addition of sodium chloride proceeded drying over magnesium sulfate and evaporation of the solvent. The crude product was a black, tar-like goo.
Purification
To purify, column chromatography on silica gel was used with a solvent mixture of 94% hexanes and 6% tert.-butyl methyl ether, and the crude product was put on silica gel before put on the column. A by-product has the same retention factor (Rf value) as the target compound KWF3 (TCPT) (˜0.22). After preliminary clean-up on a few columns, the black constituents were removed successfully. The first columns were used to remove KWF2 and other fast-running compounds. The solvent-fractions that followed were saved, trying to cut off only the major fraction of more slowly moving impurities. At the last column, KWF3 was put on the column as a solid powder and until the end mostly stayed accumulated on top of the column and was then flushed down with acetone. The mixture was evaporated immediately since TCPT decomposes in acetone. The product was a white/grayish-purple solid.
Identification
1H-NMR (400 MHz, CDCl3)
d(ppm)=7.03 (2H, H1,9), 6.64 (2H, H4,6), 5.83 (1H, NH)
X-ray crystallographic measurements on an orthorhombic crystal resulted in the first crystal structure of TCPT.
The orthorhombic space group Pna21 was determined by systematic absences and statistical tests and verified by subsequent refinement. The structure was solved by direct methods and refined by full-matrix least-squares methods on F2. See (a) G. M. Sheldrick (1994). SHELXTL Version 5 Reference Manual. Bruker-AXS, 6300 Enterprise Dr., Madison, Wis. 53719-1173, USA. (b) International Tables for Crystallography, Vol C, Tables 6.1.1.4, 4.2.6.8, and 4.2.4.2, Kluwer: Boston (1995). Hydrogen atom positions were initially determined by geometry and refined by a riding model. Non-hydrogen atoms were refined with anisotropic displacement parameters. Hydrogen atom displacement parameters were set to 1.2 (1.5 for methyl) times the displacement parameters of the bonded atoms. A total of 163 parameters were refined against 1 space group restraint and 2155 data to give wR(F2)=0.0764 and S=1.065 for weights of w=1/[σ2 (F2)+(0.0600 P)2], where P=[Fo2+2Fc2]/3. The final R(F) was 0.0284 for the 2122 observed, [F>4σ(F)], data. The largest shift/s.u. was 0.001 in the final refinement cycle. The final difference map had maxima and minima of 0.521 and −0.225 e/Å3, respectively. The absolute structure was determined by refinement of the Flack parameter. See H. D. Flack, Acta Cryst. A39, 876-881 (1983). The polar axis restraint was taken from Flack and Schwarzenbach. See H. D. Flack and D. Schwarzenbach, Acta Cryst. A44, 499-506 (1988).
The results are shown below in Tables 2A to 2G below
wR2 = {Σ [w(Fo2 − Fc2)2]/Σ [w(Fo2)2]}1/2
R1 = Σ ||Fo| − |Fc||/Σ |Fo|
Symmetry transformations used to generate equivalent atoms:
#1 −x + 3/2, y + 1/2, z + 1/2
The information gained from the crystal structure was important for the structural comparison of TCPT and TCDD. TCDD has a perfectly planar structure (Boer et al. 1972). This example showed that the molecular structure of TCPT is non-planar due to the different heteroatoms positioned in the central ring. Semi-empirical calculations by the present inventor had predicted an angle formed between the two aryl rings of 160.2° for TCPT; 149.2° and 154.3° for its sulfoxide and sulfone, respectively (Fried 2000). The successful X-ray crystallography revealed an angle of 161.5° for TCPT, which supports these calculations. With different stereochemistry, some receptor-interactions of TCPT and TCDD are likely to differ, which in turn could be related to macroscopic manifestations of toxicity.
In this example, dose-range finding studies were performed with a small number of animals to accommodate the limited availability of TCPT. Guinea pigs were chosen for the studies because they represent the most sensitive species for dioxin toxicity. Because of the close structural similarity to TCDD, it was assumed that this would be the case also for TCPT. Rats were also investigated as being the standard kinetic model.
1. Guinea Pigs.
Six adult male Dunkin-Hartley guinea pigs were given daily p.o. doses of TCPT. Due to its insolubility, TCPT was administered as a solid in size 9 gelatin capsules and dosing devices purchased from Torpack, Inc. (Fairfield, N.J.). The dosage and results were as follows:
The experimental design of daily dosing accounted for the short half-life known from clinically used phenothiazines and the results of prior unpublished studies with 1,2,3,7,8,9-hexachlorophenothiazine. Based on this example, a dose for the acute lethal toxicity of TCPT was broadly calculated to be about p.o. 25-50 mg/kg/day with 8-11 days of dosing until death. The development of tolerance was noticed in survivors.
During ovulation studies (see Example 4 below), an adult female was lost after having been dosed with 10 mg/kg/day for 9 consecutive days; the animal died on day 13. Single intravenous administration of 10 mg/kg TCPT in acetone (0.5 ml/kg) showed no observable effects.
2. Rats.
Adult female Sprague-Dawley rats were injected 5, 10 and 30 mg/kg TCPT in acetone (1 ml/kg). Both animals receiving 30 mg/kg died within five seconds. Animals dosed with 10 mg/kg became unconscious for 30 min, whereas in the 5 mg/kg dose group, the rats lost consciousness for 3 min only, likely representing the effects of acetone in this case. The dose for the acute lethal toxicity of TCPT in rats was therefore broadly calculated to be about i.v. 10-30 mg/kg.
1. Guinea Pigs.
This example first looked at daily p.o. administration to guinea pigs. Eleven guinea pigs received multiple doses of TCPT, with dosages ranging from 2.5 to 100 mg/kg/day. All animals showed body weight loss. Only females (less than 5 mg/kg/day) males (less than 25 mg/kg/day) with constant doses were able to stabilize their body weight during the dosing period. All guinea pigs that were to die constantly lost bodyweight throughout the whole study up to a point of complete feed refusal and starvation. The death of one animal five days after cessation of dosing indicates the existence of a “point of no return.” Weight loss progressed thereafter. With time, units of feces from dosed animals sporadically contained bubbles which seemed to be intestinal gases contained in a film of solidifying mucus. This observation was made dose-independently and also occurred in one control animal in a single instance. Consultations with pathologists at Bayer Crop Science in Stilwell, KS did not reveal symptoms known from studies with other compounds. Eventually, the animals became diarrhetic. With increasing weight loss, the animals' fur became increasingly puffy. Saliva wetted their feed and their lower neck down to the stomach as feed intake decreased. Dosed animals were often found sitting with their front paws on their feed bowl and digging through their feed than the control animals, giving rise to the assumption that the animals felt hunger but could not act on it. Welcoming squeaks and excited jumping (popcorning) upon arrival of the conductor of the studies were reduced and eventually vanished. Control animals showed these welcoming behaviors throughout the whole study, which leads to the conclusion that the dosing procedure itself had no effect on it. The overall activity of all dosed animals decreased. Purring upon handling endured until death. It is assumed that a general decrease in wellness caused the observed decrease in activity and interactions. The animals became apathetic. About one day before death, mucus was observed on eyes, snout and mouth.
Autopsy revealed the loss of all adipose tissue as expected. The gastrointestinal tract was empty or filled with a brown liquid and was slimy from the outside.
2. Rats.
This example also investigated two rats receiving a single i.v. administration of 30 mg/kg TCPT in acetone (1 ml/kg). The dosed rats first jumped, ran one round in their cage and dropped dead within five seconds after dosing. Those animals that survived lower doses showed breathing from the diaphragm rather than from the chest during their coma. Due to the unexpectedly rapid onset of death, no more detailed observations, e.g. on the heart rate, could be made.
After p.o. administration of various doses during pentobarbital-induced anesthesia, rats breathed very shallow and in long intervals. Survivors (of the lower doses) recovered after two minutes. One death candidate was re-animated by CPR (chest massage and artificial ventilation with a rubber pipette bulb) and seemed to recover but died about 15 minutes later.
The toxicity of TCPT was next compared to TCDD using the preliminary studies conducted in Examples 3 and 4. For reasons of simplicity, the dose ranges of acute lethal toxicity found for TCPT is here referred to as LD50.
For guinea pigs (female), the p.o. LD50 of TCPT was estimated to be about 25-50 mg/kg. This is roughly 10,000 times more than the reported p.o. LD50 of 2.1 μg/kg for TCDD (Schwetz et al. 1973).
For rats, the i.v. LD50 of TCPT was estimated to be about 10-30 mg/kg. This is roughly 1,000 times more than the reported i.v. LD50 of TCDD of 25 μg/kg for TCDD (Schwetz et al. 1973).
The difference of one order of magnitude between the i.v. data from rats and the p. o. data from guinea pigs could have several reasons. First, a strong first pass effect could cause such a difference. Second, a lower absorption of TCPT from the gastrointestinal tract as compared to TCDD could also account for the variation. Comparing human data, the absorption of TCDD is >86% (Poiger & Schlatter 1989), whereas that of chlorpromazine ranges between 10.5 and 25.7% (Koytchev et al. 1994). Third, the different doses of acetone vs. gelatin as a carrier may play a role.
In this example, the toxicity of TCPT was compared between each species. When a female guinea pig received i.v. 10 mg/kg TCPT, there was no observable effect. On the other hand, a female rat receiving i.v. 10 mg/kg was sedated within 30 minutes. In addition, increasing levels of TCPT to i.v. 30 mg/kg in rats resulted in an lethal dose.
The results presented here, although based on two animals per dose group only, give rise to skepticism regarding the degree of analogy of TCPT and TCDD as far as species-differences in acute toxicity is concerned. No amount of TCDD was ever shown to kill animals within five seconds.
After a single oral dose of TCDD, rats lose body weight dose-dependently (Seefeld et al. 1984a; Seefeld & Peterson 1984). It can be calculated from the literature (Seefeld et al. 1984b) that once the body burden of TCDD after a non-lethal dose of 15 μg/kg was reduced to 6.6-8 μg/kg (i.e. after 11 days), feed intake started rising again. Below about 5 μg/kg TCDD body burden (3 weeks after dosing), weight gain resumed. TCDD-treated rats then gained weight at the same rate as the controls, although at a lower level. The set-point for bodyweight remained reduced throughout the following observation period (10 weeks), while efficiency of feed utilization was unaffected (Seefeld et al. 1984a).
In the present invention, guinea pigs were dosed for 9 consecutive days with 2.5, 5, 10 and 20 mg/kg/day TCPT, respectively. The observations presented here were made during another study which was not designed for comparative body weight analysis. Hence, only one pair-fed (to 20 mg/kg/day) animal was used. All animals showed a decrease in bodyweight during the dosing period and all but one resumed gaining weight once TCPT administration was terminated. The animal treated with 10 mg/kg/day did not recover and died on day 13. In contrast to studies on TCDD, weight gain resumed 1-2 days after cessation, probably due to TCPT's shorter half-life and therefore more rapid elimination. All survivors showed a reduced set-point of bodyweight, as depicted in comparison of the treated guinea pig with the respective pair-fed animal, and the control animal in
The set-point for bodyweight was reduced by 66 grams in the treated animal and 79 grams in the pair-fed control. The slope of weight gain remained the same for the pair-fed control but increased in the treated animal after cessation of exposure to TCPT.
In adult cycling rats, a dose of 10 μg/kg TCDD resulted in a prolonged diestrus stage, reduced ovulatory rate and fewer ova shed (Li et al. 1995a). Studies in the immature rat model determined the ED50 for these effects to be between 3 and 10 μg/kg TCDD. Pair-fed controls did not show effects on ovulation, and therefore, an effect of feed intake can be excluded (Li et al. 1995b).
In the present invention, guinea pigs were chosen for this study for two reasons. First, they represent the species that is the most sensitive to TCDD. Second, oral administration was only possible as undissolved solid in gelatin capsules due to the low solubility of TCPT in any solvent. Dosing with gelatin capsules can be performed in this species without anesthesia, which is not possible in rats. This is an important factor, since anesthetics generally influence ovulation.
The guinea pigs were followed for at least two regular consecutive cycles (about 16 days each) before commencing with dosing and also after the administration of TCPT was terminated. Their cycles were tracked by observation of vaginal opening and vaginal smears. The day of ovulation, day 1, was defined as a leucocytic smear following a cornified smear. The animals were dosed for 9 consecutive days starting on day 9 of a highly regular normal cycle. This way, the dosing period overlapped with the relevant time-span for ovulation and regulation of the cycle length (Terranova & Greenwald 1981). The animals received dose rates of 2.5, 5, 10 and 20 mg/kg TCPT per day. One animal was pair-fed to an animal dosed with 20 mg/kg/day TCPT. The pair-fed animal showed a regular cycle length with irregular vaginal opening. Animals in the two lowest dose groups showed no effect, 10 mg/kg/day TCPT resulted in a shortened period of vaginal opening and lethality five days after cessation in one guinea pig. A dose rate of 20 mg/kg/day TCPT inhibited ovulation and led to irregular vaginal opening.
Based on this experiment, it appears TCPT exerts no direct or endocrine effect on the ovaries in guinea pigs, but that the effects on ovulation were merely a result of altered energy regulation in the animals.
The induction of CYP 1A1 has been quantitatively measured in an cell-line study. The choice of EROD as an in vitro study was made based on its established procedure and speed. This revealed the relative AhR interaction of TCPT compared to TCDD as a measure to quantify its dioxin-like induction of gene expression in a cell-based assay. Its metabolic context is both, a strength and a weakness of the EROD assay. The greatest advantage of cell-based assays is the detection of the actual gene expression as compared to the study of interaction with DREs (Seidel et al. 2000).
The EROD-specific activity of TCPT declined over time, with its maximum at 24 h out of measurements after 24, 48 and 72 h. This indicates a comparatively rapid metabilization of TCPT by rat hepatoma cells.
At 24 h, TCPT showed a potency for the induction of in vitro EROD-specific activity of 10−2.6 (0.25%) of that of TCDD, as approximately also found in the comparison of the acute i.v. toxicity of both compounds. The efficacy of TCPT reached 77% of the efficacy of TCDD in the in vitro EROD-bioassay. Further studies are currently under investigation for a most accurate determination of the differences in potency and efficacy.
As observed during other experiments, TCPT treatment enhanced the effects of anesthetics. The i.v. administration of 5 mg/kg TCPT in acetone (1 ml/kg) resulted in immediate respiratory arrest in animals that were anesthetized by 55 mg/kg of pentobarbital. CPR was successful in one case; however only for 15 minutes. Animals receiving a 3 mg/kg i.v. dose showed less of an effect, with one animal dying out of three. Peroral administration of solid TCPT 30 min prior to pentobarbital administration (55 mg/kg) shortened the onset of anesthesia by about 50% but lead to no fatalities.
Studies on a limited number of animal have been conducted to determine the approximate half-life of TCPT. The kinetics were found to follow a two-compartment model after intravenous dosage with a distribution- and an elimination-phase.
For the distribution phase after intravenous dosing, a half-life below 1 h was found, i.e. 0.82 h, 0.47 h and 0.42 h in two rats dosed 5 mg/kg, one rat dosed 10 mg/kg and two guinea pigs dosed 10 mg/kg, respectively.
The elimination phase was found to be 5.42 h, 2.25 h and 2.71 h in two rats dosed 5 mg/kg, one rat dosed 10 mg/kg and two guinea pigs dosed 10 mg/kg, respectively.
Those skilled in the art will appreciate that striking similarities between TCPT and TCDD were found in their effects on bodyweight. TCPT administrated daily exerted a wasting effect analogous to the wasting syndrome known from single dose rates of dioxins. However, as soon as the exposition ceased, animals resumed gaining weight (except for one guinea pig). This is understandable in that the half-life of TCDD is much longer than that of TCPT (weeks vs. hours). Therefore, efficacy is lost more rapidly with the latter. Subsequent weight gain occurred on a reduced scale, with both compounds reducing the set-point for body weight.
The foregoing examples also show several differences between TCPT and TCDD. Their synthesis consists of fusing two aryl rings via heterocyclic bridges. TCPT lacks the energetically advantageous formation-profile of TCDD, and is therefore very difficult to synthesize. Comparing their acute toxicity in animals as well as their in vitro EROD-specific activity, TCPT is by approximately three orders of magnitude less potent than TCDD. The 10−4-fold difference in acute toxicity found for oral administration is probably due to hepatic first pass effect and/or differences in absorption. Finally, the large species-differences typical for TCDD's acute toxicity could not be confirmed by these preliminary observations. The endocrine effects of TCDD on ovulation in rats could not be reproduced by TCPT in guinea pigs, however, studies of TCPT in rats yet have to be conducted, as do studies of TCDD in guinea pigs.
Cytochrome P450s play a major role in phase I metabolism, representing the oxidative enzymes. Compounds can exert transcriptional influence over these proteins via promoters. As first described in 1976 (Poland et al. 1976), TCDD induces CYP 1A1 by interacting with its gene through a receptor-mediated mechanism. The cytoplasmic AhR and its nuclear partner arnt (AhR nuclear translocator) play key roles in this signal transduction. The non-TCDD specific receptor elicits the signaling pathway. An AhR ligand, such as TCDD, enters the cell and interacts with AhR in the cytoplasm. Proteins bound to AhR dissociate to facilitate the binding of TCDD or another substrate to the ligand-binding site. The newly formed receptor/ligand complex migrates into the nucleus and forms a heterotrimer with arnt. This trimer binds to a core heptanucleotide sequence, the dioxin response elements (DREs), in the DNA and initiates transcription. After processing and migration into the cytoplasm, translation of the mRNA takes place and the newly formed proteins elicit a biological response. One manifestation is an increased CYP 1A1 activity in the organism or isolated cell line.
To elucidate the interactions of TCPT with the AhR, receptor-binding studies will be performed. No 3H-TCPT is available, yet, and no radiolabeling of TCPT has been attempted, thus far. Due to this uncertain situation of the availability of labeled compound, studies cannot be proposed based merely on experimental conditions for classical approaches in binding studies. Under these circumstances, there is a wide spectrum of assays for dioxins and dioxin-like compounds (Behnisch et al. 2001) and the Ah-immunoassay (AhIA) (Wheelock et al. 1996) seems to fit the requirements best. It is a commercially available kit (U.S. Pat. No. 6,127,136; Japan Patent No. 3144689), which shows important advantages over the classical approach. However, classical binding studies are outlined below as backup to provide limited validation of the chosen alternative.
Ah-Immunoassay (AhIA)
The Ah-immunoassay is a hybrid of an immunoassay and an in vitro AhR-based assay. Ligands are added to this cell-free test and if they bind to the AhR, the known complex with arnt is formed subsequently. This heterotrimer binds to DREs as in the regular signaling pathway, however, the assay is performed in a cell-free system on a special ELISA plate. After washing, antibodies are added which bind arnt in the complex with AhR, still bound to the plate. Quantification is conducted photometrically. The limit of detection for this assay is given as 1 pg TCDD per sample.
Binding studies of TCPT in the AhIA will be performed with different concentrations of TCDD as a positive control, and the results will be used as standards for quantifying the effects of TCPT. For the study of competitiveness, combinations of both compounds will be investigated.
Instead of the exact quantification of classical binding assays with radiolabeled ligand, the AhIA uses a calibration with TCDD as standard. Concerns may arise from the question if TCDD quantitatively binds in the signaling pathway, since it is used for calibration. The detected activity of TCPT is therefore proportional to the percentage of TCDD bound. This question, however, can be negated by calibrating the test with the low-concentration stretch of first-order TCDD binding kinetics, where quantitative binding applies.
Classical 3H-TCPT Binding Study
Based on the availability of 3H-TCPT, classical binding and displacement studies of TCPT in an AhR assay are planned. The limitations for biological interpretability mentioned earlier are considerable and have to be taken into account. However, binding studies with labeled ligands represent a highly reliable, established system for isolated receptor interactions.
The binding kinetics of 3H-TCPT will be studied. Also, the displacement of 3H-TCPT by TCPT is of interest for the determination of the dynamics, i.e. reversibility, of binding. The displacement of radiolabeled TCDD by TCPT and radiolabeled TCPT by TCDD will provide information about the strength of the ligand interaction with the AhR.
Hypothesis
Based on the structural similarity between TCDD and TCPT, the binding of these two compounds to the AhR is hypothesized to be competitive with agonistic effects. However, due to their differential stereochemistry, a lower affinity of the angled TCPT to the AhR as compared to TCDD is expected. Both compounds are expected to interact with the same ligand-binding domain of the AhR. Consequently, increasing competitive inhibition of the effects of TCDD (AhIA) or displacement of TCDD (classical binding assay) is expected with an increasing TCPT concentration.
The recent solution of the crystal structure of TCPT provides important information for the computational modeling of TCPT/AhR interactions. Although the crystal structure of the AhR has not been determined, yet, in silico studies can be undertaken: Just recently, theoretical research on the structure of the AhR has yielded a three dimensional structure of the ligand-binding domain by homology modeling (Jacobs et al. 2003). Therefore, in addition to the binding studies, calculations will be used to support the investigations of the interactions of TCPT with the AhR.
Hypothesis
A lower but existing goodness-of-fit is hypothesized for TCPT as compared to TCDD, as reasoned for the kinetics studies.
To further study the mechanism of the TCPT-induced loss of bodyweight, as well as to further dissect the mechanism of TCDD-toxicity stated in Chapter 1.1.4, PEPCK inhibition should be measured.
Hypothesis
A dose-dependent inhibition of PEPCK-activity in the same dose-range as toxicity occurs is expected in analogy to TCDD (Rozman, 1992)
Unlike TCDD with its chemically inert structure of two bivalent oxygen atoms in the central ring, TCPT possesses a trivalent nitrogen atom and a sulfur atom that can be bi-, tri- or tetravalent. This offers the possibility of derivatives with properties slightly differing from TCPT. The nitrogen atom can bind groups other than hydrogen such as lower alkyl groups. Further, the sulfur atom is subject to oxidation. The derivatives of primary interest are:
Sulfoxo-Derivatives
N-Methylated Derivative
Combined Derivatization
The acute toxicity of all compounds will be determined for comparison. If no lethality is observed at doses limited by the logistics of administration, such as dosing volume and regimen, the effects of a high, single oral dose on body weight, feed intake and spillage will be determined.
Sulfoxo-Derivatives
In the organism, TCPT is subject to oxidation by cytochrome P450s. As research from many current drugs shows, often metabolites show activity. Since TCPT O and TCPT O2 are presumed metabolites, a study of their potency as compared to TCPT will be performed. A higher potency of the sulfoxides, however, is not expected, since the oxo-derivatives deviate even more from planarity and therefore from dioxin-like stereochemistry than TCPT does. This would negatively effect their receptor-binding ability.
N-Alkyl Derivatives
TCPT is readily subject to oxidation not only on the sulfur atom, but also on the amine. Formation of the hydroxylamine leads to higher water solubility and, especially after phase II biotransformation, to faster excretion. To slow down the metabolism of TCPT, a lower alkyl group, is used as a protecting group on the amine. Preferably, the lower alkyl group is a methyl group. A higher efficacy of N-Me TCPT as compared to TCPT is expected due to its greater persistence and, if dosing is repeated within four half-lives, its accumulation. If oxidative demethylation does not turn out to be a rate-limiting step in the elimination of N-Me TCPT, then it will behave as TCPT itself.
Among other things, the compounds of the present invention are useful for the treatment of diabetes mellitus (type I and type II), ovulation inhibitor (contraceptive), cancer chemotherapeutic agent, anti-obesity drug (body weight regulator), and immunostimulant.
The compounds of the present invention may be administered in any suitable fashion. For example, the compounds may be administered both orally and parenterally in the dosage form of tablets, powders, granules, capsules, syrups, troches, inhalants, suppositories, injections, ointments, ophthalmic ointments, eye drops, nasal drops, ear drops, cataplasmas, and lotions.
The administration dose widely varies depending on the type of the treatment, the severity of the symptoms, the age, sex and drug sensitivity of the animal. In general, the compounds of the present invention are administered in a daily dose of from about 0.5 mg/kg to 20 mg/kg, preferably from about 3 mg/kg to 15 mg/kg, and most preferably about 5 mg/kg to 10 mg/kg.
The compounds of the present invention may be processed into preparations by conventional methods with the use of conventional pharmaceutical carriers. For example, solid preparations for oral administration are prepared by mixing the principal agent with fillers, binders, disintegrating agents, lubricants, coloring agents, corrigents, antioxidants, etc. and then processed into tablets, coated tablets, granules, powders, capsules, etc. by conventional methods. Examples of the above-mentioned fillers are lactose, corn starch, sucrose, glucose, sorbitol, microcrystalline cellulose, silicon dioxide, etc. Examples of the binders are polyvinyl alcohol, polyvinyl ether, ethylcellulose, methylcellulose, acacia, tragacanth, gelatin, shellac, hydroxypropylcellulose, hydroxypropylmethylcellulose, calcium citrate, dextrin and pectin. Examples of the lubricants are magnesium stearate, talc, polyethylene glycol, silica, hardened vegetable oils, etc. The coloring agents are those admitted to be added to medicines. Examples of the corrigents include cocoa powder, menthol, aromatic powder, peppermint oil, borneol and powdered cinnamon bark. As the antioxidants, use can be made of any pharmaceutically authorized ones such as ascorbic acid and alpha-tocopherol. Tablets and granules may be appropriately coated with sugar, gelatin, and extended release coatings, if necessary. The compounds of the present invention may also be soluble in sodium bicarbonate, thus providing for a suitable injection route.
Since many possible embodiments may be made of the invention without departing from the scope thereof, is to be understood that all matters herein set forth or shown in the accompanying drawings are to be interpreted as illustrative, and not in a limiting sense.