TITLE
Production and use of imines of porphyrins FIELD OF THE INVENTION
This invention relates to the production and use of imines of porphyrins, of porphyrins, and of related compounds, including metal complexes, e.g., benzochlorinimines and benzochlorinimine metal complexes, which are useful in photodynamic therapy. The invention also relates to compositions containing such imines. Specific examples of the benzochlorinimines and of the benzochlorinimine metal complexes of the invention have the following structures:
where M comprises a metal cation that is complexed with two of the nitrogens of the benzochlorin and is Ag, Al, Ce, Co, Cr, Cu, Dy, Er, Eu, Fc, Ga, Gd, Hf, Ho, In, La, Lu, Mn, Mo, Nd, Ni, Pb, Pd, Pr, Pt, Rh, Sb, Sc, Sm, Sn, Tb, Tc, Th, Ti, Tl, Tm, U, V, Y, Yb, Z n or Zr, and
A is a physiologically acceptable anion, e.g., chloride.
The benzochlorins, benzochlorin metal complexes, and the other imines and imine metal complexes according to the instant invention are photo sensitizers; i.e., excitation at a suitable wavelength promotes them to the singlet state, from which they decay to the ground state primarily by non-radiative pathways, releasing their energy in several forms, including heal, electron transfer, and probably forming at least one active oxygen species, free radicals, or both. Further, when they are suitably administered, for example, intravenously, to a living patient, they are rejected by healthy tissue, but not by tumors and, as a consequence, they are still present, a suitable time after administration, in tumors of the patient to whom they were administered, but are no longer present in adjacent healthy tissue so that they can be promoted to the singlet state by excitement at a suitable wavelength and will then destroy the tumor as they decay to the ground state. Photothermal sensitizers, which destroy tumors by the release of heat after they have been promoted to the singlet state, are discussed by Jori, G. et al., Journal of Photochemistry
and Ph otobiology, B : Biology, 6(1990) , pages 93 - 101 Sensitizers that, after they h ave een promote to the singlet state, produce active oxygen species, probably including singlet oxygen, which then destroys tumors are also known, being disclosed, for example, in "Morgan et al. I", U.S. patent No. 4,988,808, January 29, 1991 and in references cited therein.
DISCUSSION OF RELATED ART
Benzochlorin metal complexes and benzochlorins having the formulas of Figs. 1 and 2, below, are disclosed in Morgan et al. I:
Compounds having the structures of Figs. 1 and 2 are also disclosed by Morgan et al., "Photodynamic
Action of Benzochlorins", SPIE Vol. 1066-Photodynamic Therapy: Mechanisms (1989), pages 146 et scq. and by Vicente ct al. "Vilsmcicr Reactions of Porphyrins and Chlorins with 3-(Dimcthylamino)acτolcin To Give meso-(2-Formylvinyl)porphyrins: * * *" J. Org. Chem. 1991, 56, pages 4407-4418 (see, also, Arnold, D.P. et al., Journal of The Chemical Society, Pcrkin Transactions I (1979), pages 1660 el scq.). The specific benzochlorins disclosed by Morgan et al. are compounds where each of R1 through R8 is ethyl, each of R10 through R12 is hydrogen, and
(a) the compound has the structure of Fig. 1, R14 is SO3Na and M is Sn;
(b) the compound has the structure of Fig. 2 and R14 is H;
(c) the compound has the structure of Fig. 2 and R14 is SO3Na; and
(d) the compound has the structure of Fig. 1, R14 is H, and M is Sn.
Similarly, porphyrins, chlorins, bactcriochlorins, chlorophylls, bactcriochlorophylls, purpurins, reduced purpurins, verdins, Diels-Alder Adducts, isobacteriochlorins, and metal complexes of the foregoing are all known, as is the use of the Vilsmeier reagent to introduce formyl groups into porphyrins; the reaction of the Vilsmeier reagent (dimcthylformamide, for example, and phosphoryl chloride) produces imines as intermediates. So far as is known, however, the imines produced by the Vilsmeier reagent have not previously been separated from the reaction mixture; instead, the reaction has been allowed to proceed until the formyl group was formed.
BRIEF DESCRIPTION OF THE PRESENT INVENTION
The present invention is a family of imines, e.g., benzochlorinimincs having the structure set forth below and identified by legend, and a family of imine metal complexes, e.g., benzochlorinimine metal complexes having the structure set forth below and identified by legend, and a method for treating tumors which involves the administration of one of the imines, e.g., a benzochlorinimine having the structure set forth below, or one of the imine metal complexes, e.g., a benzochlorinimine metal complex having the structure set forth below, to a human or animal patient with a tumor, and, after a suitable period of lime, irradiation of the tumor with light of a suitable wavelength and of sufficient intensity to promote the imine or imino metal complex to the singlet state.
In the benzochlorinimines and benzochlorinimine metal complexes having the foregoing formulas:
M and A have the meanings indicated above, R' and R" can be the same or different and each is hydrogen, an alkyl group having from 1 to 4 carbon atoms, or the two, togther, can consist of two CH2 groups each of which is bonded to the nitrogen atom, and the two of which are a part of an aliphatic hydrocarbon chain having from 4 to 6 carbon atoms, and each of R1 through R8 and R11 is
H or CHO,
an alkyl group other than t-butyl having from 1 to 4 carbon atoms,
an alkylene group having from 2 to 4 carbon atoms,
a group having the formula R-N(R4)2 where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is either a single or a double bond, and not more than one is a double bond; R4 is hydrogen or an alkyl radical having from 1 to 2 carbon atoms and the two R4 groups can be the same or different,
a group having the formula R3N(R5)3 A where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is cither a single or a double bond, and not more than one is a double bond; A is a physiologically acceptable anion and R5 is an alkyl group having from 1 to 2 carbon atoms and the three R3 groups can be the same or different,
a group having the formula R3OH where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is cither a single or a double bond, and not more than one is a double bond, or
CO2R', CH2CO2R' or CH2CH2CO2R' where R' is H, or an alkyl group other than t-butyl having from one to four carbon atoms,
with the proviso that R11 can be SO3H or a salt thereof.
Other imines and imine metal complexes of the families of the instant invention have the formulas set forth below, and identified by legend.
In the foregoing formulas, M comprises a metal cation that is complexed with two of the nitrogens of the benzochlorin and is Ag, Al, Ce, Co, Cr, Cu, Dy, Er, Eu, Fc, Ga, Gd, Hf, Ho, in, La, Lu, Mn, Mo, Nd, Ni, Pb, Pd, Pr, Pt, Rh, Sb, Sc, Sm, Sn, Tb, 99mTc, Th, Ti, Tl, T m, U, V, Y, Yb, Zn or Zr,
A is a physiologically acceptable anion, e.g., chloride, R' and R" can be the same or different and each is hydrogen, an alkyl group having from 1 to 4 carbon atoms, or the two, together, can consist of two CH2 groups each of which is bonded to the nitrogen atom, and the two of which are a part of an aliphatic hydrocarbon chain having from 4 to 6 carbon atoms, and each of R1 through R11 is
H or CHO,
an alkyl group other than t-butyl having from 1 to 4 carbon atoms,
an alkylene group having from 2 to 4 carbon atoms,
a group having the formula R3N(R4)2 where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is cither a single or a double bond, and not more than one is a double bond; R4 is hydrogen or an alkyl radical having from 1 to 2 carbon atoms and the two R4 groups can be the same or different,
a group having the formula R3N(R5)3 A where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is either a single or a double bond, and not more than one is a double bond; A is a physiologically acceptable anion and R5 is an alkyl group having from 1 to 2 carbon atoms and the three R5 gτoups can be the same or different,
a group having the formula R3OH where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is cither a single or a double bond, and not more than one is a double bond, or
CO2R', CH2CO2R' or CH2CH2CO2R' where R' is H, or an alkyl group other than t-butyl having from one to four carbon atoms,
with the proviso that R11 can be SO3H or a salt thereof.
In the foregoing Chlorinimincs and metal complexes, either R3 or R4 can be a CH2 group or O which, in either case, is bonded to the carbon of the pyrrole ring by a double bond. Likewise, in the foregoing families of compounds which are designated Isobacteriochlonnimine I and Isobactcriochlorinimine II either R1 or R2
can be a CH2 group or O which, in cither case, is bonded to the carbon of the pyrrole ring by a double bond and, when either R1 or R2 is a CH2 group or O, either R3 or R4 is also a CH2 group or O which is bonded to the carbon of the pyrrole ring by a double bond. Finally, in the foregoing families of compounds which are designated bactcriochlorinimine either R3 or R4 can be a CH2 group or O which, in either case, is bonded to the carbon of the pyrrole ring by a double bond and, when cither R3 or R4 is a CH2 group or O, either R7 or R8 is also a CH2 group or O which is bonded to the carbon of the pyrrole ring by a double bond.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The following examples constitute the best modes presently contemplated by the inventors, but are presented solely to illustrate and disclose ihe invention, and are not intended to be limiting.
As used herein, and in the appended claims, the terms "percent" and "parts" refer to percent and parts by weight, unless otherwise indicated; g means gram or grams; mg means milligram or milligrams; ng means nanogram or nanograms; pg means picogram or picograms; cm means centimeter or centimeters; mm means millimeter or millimeters; L means liter or liters; mL means millililer or milliliters; μL means microliter or microliters; v/v means percent by volume; m/o means mole percent, and equals 100 times the number of moles of the constituent designated in a composition divided by the total number of moles in the composition; v/v means percent by volume; w/v means weight per unit of volume, and is in terms of g/L; M means molar and equals the number of gram moles of a solute in one liter of a solution; μM means micromolar and equals the number of microgram moles in one liter of a solution; mM means millimolar and equals the number of milligram moles of a solute in one liter of a solution; N means normal, and equals the number of gram equivalents of a solute in one liter of solution; μN means micronormal and equals the number of microgram equivalents of a solute in one liter of solution; and mW means milliwatt or milliwatts. All temperatures are in ºC, unless otherwise indicated.
Example 1 describes the production of "Cu Benzochlorinimine I" (Formula II, supra, where M is Cu and A is Cl-). In Example 1, Cu Benzochlorinimine I is produced from a solution in 30 mL dichlorocthane of 1 mL Vilsmcicr reagent and 80 mg "Cu Octacthyl Benzochlorin" (Vicente et al., supra):
EXAMPLE 1
The Vilsmcier reagent was produced by mixing 0.5 mL phosphoryl chloride with 0.5mL dimethyl formamide, and was then added to a solution of the Cu Octacthyl Benzochlorin in the dichloroethane, which solution had
been heated to a temperature in the range of 60 to 65º. The reaction mixture was stirred for 15 minutes at a temperature within the indicated range, and was then washed with dcionized water. After removal of the solvent under reduced pressure, the crude product which remained was purified by rccrystallization from dichloromethane/hexane. The yield was 80 mg Cu Benzochlorinimine I (87 percent of theory). The Cu Benzochlorinimine I was identified by high resolution mass spcctromctry; in dichloromethane solvent it has absorbance peaks in the visible spcctium at wavelengths of 386, 448, 570, 690 and 752 nm (51000, 30000, 7000, 12000, 35000).
The procedure of Example 1 has been repeated, except that equivalent amounts of other formamides were substituted for the dimcthylformamide to produce other copper octacthyl benzochlorinimines. The formamides used had the formulas given in the following table, and produced benzochlorinimine metal complexes which had the structure previously identified by legend where R1 through R8 were ethyl, R11 was hydrogen, A- was chloride, M was copper, and the imine group had the structure given in the table:
In vitro and in vivo testing of Cu Benzochlorinimine I was also carried out by established procedures. The cells used for the in vitro testing were AY-27 FANFT transitional cell bladder cancer cells attached to 28 cm2 culture dishes. Cu Benzochlorinimine I was added to the culture dishes at four concentrations: 0.1, 0.25, 0.5 and 1 μg per mL, and"Crcmophor E" (defined below) was added as a control at 1 μg per mL. Four hours after the Cu Benzochlorin I and "Crcmophor E" additions, the cells were washed, irradiated, in one series of tests with a pulsed beam (750 nm) from an Alexandrite laser and, in another scries of tests, wilh a continuous beam (590 nm) from a xenon are lamp. The irradiated cells were then incubated for 4 to 7 days until colony formation occurred. Surviving colonies were then counted, and mean values for surviving colonies were determined. The results, when the Alexandrite laser was used, in terms of the mean numbers of surviving colonies as a function of the flucncc of radiation in Joules per cm2, are summarized in the following table.
To conduct the foregoing tests, the Cu Benzochlorinimine I was dissolved in a commercially available non-ionic solubilizer and emulsifier obtained by reacting ethylene oxide with castor oil in a ratio of 35 moles of ethylene oxide per mole of castor oil, diluting the resulting solution with 1,2-propanediol, and producing an emulsion with the resulting solution and 0.9 percent aqueous sodium chloride solution. The specific
non-ionic solubilizer used is available from BASF under the designation CREMOPHOR EL; it is composed of fatty acid esters of polyglycols, giyccroi polygiycols, polyethylene glycois and ethoxylated glycerol. The test solutions were prepared from 50 mg Cu Benzochlorinimine I, about 1 mL warm solubilizcr (enough to dissolve the test compound), and enough 1,2-propanediol to make a solution of the Cu Benzochlorinimine I in a mixed diol/solubilizcr solvent containing 32.9 percent solubilizcr; finally, enough 0.9 percent aqueous sodium chloride was added to make 10 mL test solution so that the final concentration of the Cu Benzochlorinimine I in the test solution was 5 mg per mL. Each test solution was made, with mechanical shaking and stirring, by dissolving the Cu Benzochlorinimine I in the solubilizcr, diluting the resulting solution with the indicated amount of 1,2-propanediol, and adding the sodium chloride solution to the diluted solution. A control solution was also prepared for use with each test solution. The control was identical with the test solution except that it contained no Cu Benzochlorinimine I.
The results of the in vitro testing, when the Xenon are lamp was used, in terms of the mean numbers of surviving colonies as a function of the fluence of radiation in Joules per cm2, are summarized in the following table.
The in vivo testing was conducted on male Fisher 344 rats weighing 135 to 150 g in whom the transplantablc FANFT (N-[4-(5-nitro-2-furyl)-2-thiazolyI]for mamide tumor system had been implanted. (Use of this system is reported by Sclman, S.H., ct al., Cancer Research, pp. 1924-1927, May, 1984.) Two tumors were implanted into the subcutaneous tissue of the flank of each test animal; when the testing was carried out, each tumor was about 1 cm in diameter.
The Cu Benzochlorinimine I was dissolved in the previously identified non-ionic solubilizcr that is commercially available under the designation CREMOPHOR EL, and test solutions which contained 2 mg per mL Cu Benzochlorinimine I were prepared as previously described.
The testing involved injecting each rat with a solution of the Cu Benzochlorinimine I, dosage 3.5 mg per kg of body weight or 7 mg per kg of body weight or with the same volume of the appropriate control, irradiating one of the two tumors with laser light, in some cases, observing the animals over a period of time and, in others, sacrificing the animals, and examining the tumors. The injections were made via the dorsal tail vein. The irradiation of one of the tumors occurred twenty four hours after each rat was injected while the other of the two tumors was shielded.
Tumor temperature and body core temperature wcic monitored, using thermistors, one placed percutaneously beneath the tumor and one placed intrarectally. Tumor temperature was kept within 2" of body core temperature by directing a jet of cool air over the tumor.
Both the Alexandrite laser and the Xenon are lamp were used to irradiate the tumors. The light intensity on the tumor was monitored; each tumor received 200 mW per cm2 (360 Joules per cm2).
Twenty four hours after the irradiation, some of the rats that had been injected with the test solution and one of the rats that had been injected with the control were sacrificed by an intracardiac injection of saturated aqueous potassium chloride solution. Others of the rats that had been injected with the test solution and with the control solution were observed over a period of time. During the testing, the rats were under barbituatc anesthesia (65 mg per kg body weight).
The tumors from the sacrificed rats were excised, placed in 10 percent phosphate-buffered formalin and cut into three sections perpendicular to their long axis. The tumors were then embedded in paraffin and cut into sections five microns in width. The sections were stained with hematoxylin and eosin.
Histologic examination of the stained sections (twenty four hours after a tumor was irradiated by either light source) revealed extensive necrosis of cancer cells in tumors of rats that had been injected with Cu Benzochlorinimine, and no necrosis of tumor cells in rats that had been injected with Cremoplior. The examination revealed no necrosis of cells of tumors that were not irradiated. Fourteen days after irradiation, the irradiated tumors of three of the six rats that were not sacrificed had and had been injected with 7 mg Cu Benzochlorinimine per kg of body weight showed no sign of tumor regrowth.
SKH1 hairless mice (five animals) were injected with Cu Benzochlorinimine (7 mg per kg of body weight), and the five animals were subjected to light treatment one day after the injection. One of the animals
showed slight skin burn, while the other animals showed no skin damage. This indication is important, because extensive and prolonged skin damage is a common side effect of other sensitizers.
The production of Cu Benzochlorinimine I by reaction between Cu Octaethyl Benzochlorin and a Vilsmeier reagent produced from phosphoryl chloride and dimethyl formamide is described in Example 1. The structure of Cu Octacthyl Benzochlorin is given above; its structure is also that of Fig. 1, above, where R1 through R8 are ethyl, R10 through R12 and R14 are hydrogen, and M is Cu; the reaction introduced a substitucnt having the formula -CH=N'(CH3)2. This was an R10 substitucnt in the Fig. 1 formula for Cu Octacthyl Benzochlorin. As has been stated above, other R10 substitucnts have been introduced, using the Example 1 procedure to react Cu Octacthyl Benzochlorin with Vilsmcicr reagents from phosphoryl chloride and formamides other than dimethyl formamidc, e.g., diethyl formamide, diisopropyl formamide, di n-butyl formamidc, cyciic formamides, and the like. In general, by using different formamides, benzochlorins can be produced which have the Formula II structure except that one of the CH3 groups of the R10 substituent is replaced by an alkyl group having from 2 to 4 carbon atoms or where both of the CH3 groups are so replaced; the two alkyl groups can be the same or different. Imines where R' is hydrogen, R" is hydrogen, or both R' and R" are hydrogen can also be prepared by conducting the reaction between Cu Octacthyl Benzochlorin or the like and the Vilsmeier reagent to introduce a formyl group into the molecule (see the second paragraph of Example A, infra) and then reacting the formyl group with ammonia, a primary alkyl amine, or a secondary alkyl amine, to produce, respectively, an imine where R' and R" are both hydrogen, an imine where one of R' and R" is hydrogen and the other is an alkyl group, and an imine where both R' and R" are alkyl groups. In any case, the alkyl group has from one to four carbons. As disclosed above, imines including cyclic structures can also be produced, e.g., where R' and R" are both CH2, each of which is bonded to the nitrogen atom, and the two of which are a part of an aliphatic hydrocarbon chain having from 4 to 6 carbon atoms.
Similarly, the procedure of Example 1 can be used to introduce -CH=N+(CH3)2 and other imine substitucnts into copper complexes of benzochlorins other than Cu Benzochlorin I, and, generally, into benzochlorin metal complexes having the structure of Fig. 1, supra where R1 through R8 and M have the meanings set forth above, R10 through R12 are hydrogen, and R14 can have the same meaning as R1 through R8, and can also be SO3H or a salt thereof. For example, the Cu or the Ni complex of octacthylbenzochiorin, compounds which have the structure of Fig. 1, supra, where R1 through R8 are ethyl, R10, R11, R12 and R14 are hydrogen, and M is copper or nickel, can be produced from octacthylporphyrin by the procedure of Example A, below, and can be reacted by the procedure of Example 1 to produce a benzochlorinimine according to the invention having the structure set forth above where R1 through R8 are ethyl, R11 is hydrogen, A is Cl-, and M is Cu or Ni. The identities of R' and R" depend upon the identity of the formamide used. Six intermediates were produced in the procedure of Example A, [I] nickel octacthylporphyrin [II], nickel meso-formyloctacthylporp hyrin, [III] Nickel meso-(ß-ethoxy-carbonylvinyl)-octaethylporphyrin [IV], meso-(ß-ethoxy carbonylvinyl)-octaethylporphyrin, and [V] meso-(ß-hydroxyvinyl)-octacthylporphyrin, and [VI] octacthylbenzochiorin, in addition to [VII] Nickel or Copper octaethylbenzochlorin, from the octacthylporphyrin, which has the structure of Fig. 3, below, where, R1 through R8 are ethyl, and R is hydrogen. Fig. 3 is a general formula for porp hyrins. The nickel octaethylporphyrin, the nickel meso-formyloctacthylporp hyrin, the Nickel meso-(ß-ethoxy-carbonyivinyl)-octaethylporp hyrin, and the
meso-(ß-hydroxymet hylvinyl)- octaethylporphyrin, all had the structure o f Fig. 4, b elow, where R1 through
R8 were ethyl. In the nickel octaclhylporp hyrin R was H; in the meso-formyloctacthylporp hyrin R was CHO; in the nickel meso-(ß-ethoxy-carbonylvinyl)-octacthylporp hyrin R was CH=CHCO2CH2CH3; in the meso-(ß-hydroxy-methylvinyl)-octacthylporphyrin R was CH=CHCH2OH. Fig. 4 is a general structure for nickel complexes of porp hyrins.
The nickel octaethylporphyrin is first produced from 100 mg nickel acetate and a solution of 20 mg octacthylporphyrin in a mixed solvent composed of 15 mL dichloromethane and 5 mL methanol.
Example A
Production of
Nickel octacthylporphyrin
The nickel acetate is added to the octacthylporphyrin solution; the mixture which results is refluxed for about 24 hours until the electronic spectrum of the reaction mixture indicates that chelation is complete. The reaction mixture is then concentrated to 7 mL and allowed to cool to room temperature of about 22°. Product which precipitates is recovered by filtration, dissolved in a mixed solvent composed of 5 mL dichloromethane and 2 mL methanol, and recrystallized, yielding Ni octaethylporphyrin.
Production of
nickel meso-formyloctacthylpo rphyrin
Nickel meso-formyloctaethylporp hyrin is produced (Grigg, . et al.,J. Chem. Soc. Perkin Trans I, 1972, pages 1789-1799) from a solution of 200 mg nickel meso-octacthylporphyrin in 150 mL 1,2-dichloroethane
and 4.8 mL of a solution of phosphoryl chloride in dimethylformamide prepared by making a dropwise addition of 13.7 mL freshly distilled phosphoryl chloride to 10 mL dry dimethylformamide that has been cooled on an ice bath, and keeping the solution at room temperature of about 22º for 30 minutes. The 4.8 mL portion of the phosphoryl chloride solution is warmed to 50º on a water bath and the nickel meso-octacthylporphyrin solution is added dropwise thereto; the resulting reaction mixture is maintained at a temperature of 50-55º and stirred for 15 minutes and is then warmed for an additional 30 minutes. A 150 mL portion of a saturated aqueous solution of sodium acetate is then added to the reaction mixture, after which stirring and heating are continued for an additional two hours. The organic and the aqueous layers are separated; the aqueous layer is extracted twice with 100 mL portions of diethyl ether; and the ether extracts are added to the organic layer. The organic solvents are then removed under reduced pressure, and the residue is dissolved in chloroform and chromatographed on an alumina column (3 × 30 cm). The product is crystallized from a mixed chloroform-ethanol solvent as long red felted needles.
The nickel meso-(ß-ethoxycarbonylvinyl) octacthylporphyrin was produced from a solution in 50 mL Xylene of 506 mg nickel meso-formyloclacthylporp hyrin and 1.024g (carbethoxymethylene)-triphenyl phosphorane.
Production of
nickel meso -(ß-ethoxycarbonylvinyl) octaethylporphyrin
The xylcne solution of nickel meso-formyloctacthylporp hyrin and (carbcthoxymethylene)-triphenyl phosphoranc was heated under reflux for 18 hours. The solution was cooled; the xylene was removed in vacua; and the solid which remained was dissolved in the minimum amount of dichloromethane and chromatographed on silica. A minor fraction of nickel meso-formyloctacthylporp hyrin and a major red fraction were recovered. The solvent was removed from the red fraction; the solid which remained was recrystallized from a solvent composed of equal parts by volume of dichloromethane and methanol, yielding 455 mg small brown needles. The product was identified by nuclear magnetic resonance as nickel mesσ-(ß-cthoxycarbonylvinyl) octaethylporp hyrin.
Production of
meso-[β-(ethoxycarbonyllvinyl] octaethylporphyrin
Asolution of 621 mg of nickel meso-(ß-cthoxycarbonylvinyl) octacthylporphyrin in 10 mL concentrated sulfuric acid is allowed to stand at room temperature of about 22° for 2 hours. Additions of 100mL dichloromethane and enough saturated sodium bicarbonate to neutralize the reaction mixture are then made. The organic layer is then collected, washed and dried, and the solvent is removed. Tlie crude product is purified by cryslallizaion from dichloromcthant-methanol.
Production of meso-[3-(hydroxy)propenyl] octaethylporphyrin
Asolution of 200 mg mero-[ß-(ethoxycarbony l)vinyl] octaethylporphyrin in 100 mL dry tetrahydrofuran is cooled under nitrogen to -78°, using an acetone/dry ice bath. An excess of diisobulyl aluminum hrdride in dry tetrahydrofuran (20 mL of 1M solution) is then added, followed by one hour of stirring at reduced temperature. Additions are then made of 100 mL water, 100 mL of a 10 percent aqueous solution of sodium hydroxide, and 200 mL water, and the resulting mixture is stirred for 30 minutes at room temperature of about
22º. The organic layer is then collecte d, washed and drie d, and the so lvent is removed un der vacuum. The crude product is purified by crystallization from dichloromethane-methanol.
Production of octacthylbenzochlorin
Asolution of 150 mg meso-[3-(hydroxy)propenyl] octaethylporphyrin in 3 mL concentrated sulfuric acid is kept at room temperature for 5 minutes, after which time a 20 mL portion of dichloromethane is added to the solution. Saturated aqueous sodium bicarbonate is then added until the reaction mixture is neutral. The organic layer is then collected, washed and dried, and the solvent is removed. The crude product was purified by crystallization from dichloromethane-methanol which contained 9 % methanol.
Production of Ni octacthylbenzochiorin
A solution is prepared by dissolving 20 mg octacthyl benzochlorin in a mixed solvent composed of 15 mL dichloromethane and 5 mL methanol and a 100 mg portion of nickel acetate is added to the solution; the mixture which results is rcfluxcd for about 2 hours until the electronic spectrum of the reaction mixture indicates that chelation is complete. The reaction mixture is then concentrated to 7 mL and allowed to cool to room temperature of about 22°. Product which precipitates is recovered by filtration, dissolved in a mixed solvent composed of 5 mL dichloromethane and 2 mL methanol, and recrystallized, yielding the Ni complex of octacthylbenzochiorin.
Production of Cu octaethylbcnzochlorin
A solution was prepared by dissolving 20 mg octacthyl benzochlorin (Morgan et al., "Observations on the Synthesis and in vivo Photodynamic Activity of some Benzochlorins", Photochemistry and Photobiology Vol. 55, No. 1, pages 133-136, 1992) in a mixed solvent composed of 15 mL dichloromethane and 5 mL methanol and a 100 mg portion of copper acetate was added to the solution; the mixture which resulted was rcfluxcd for about 2 hours until the electronic spectrum of the reaction mixture indicated that chelation was complete. The reaction mixture was then concentrated to 7 mL and allowed to cool to room temperature of about 22°. Product which precipitated was recovered by filtration, dissolved in a mixed solvent composed of 5 mL dichloromethane and 2 mL methanol, and recrystallized, yielding the Cu complex of octacthylbenzochiorin (yield, 90 percent of theory).
The procedure of Example 1 can be used to produce benzochlorinimine according to the invention from Ni octacthylbenzochiorin and from other benzochlorins which can be produced by the method of Example A from the corresponding porp hyrins (note that the identities of R1 through R8 in the Ni benzochlorins of the invention are the same as in the porp hyrin starting material for Example A; this is generally true). Porp hyrins having an appropriate structure to produce benzochlorinimine metal complexes according to the instant invention (formula setforth above, and identified by legend where R11 is hydrogen) are either known or can be produced by known reactions from the requisite dipyrrolic intermediates, e.g., dipyrromethancs and dipyrromethenes, which, in turn are cither known or can be synthesized from the requisite pyrroles. The requisite pyrroles, if not available, can be synthesized by the classical Knorr Reaction and variations, and by other known reactions, and can be manipulated and transformed (see, for example, David Dolphin, The Porphyrins, Volume I, Structure and Synthesis, Part A, Academic Press, New York, San Francisco and London, 1978, pages 101-163). The pyrroles have the following structure:
where A can be H, CH3, an ester, a nitrilc, a cyanovinyl or an amide group, D can be H, an ester, a nitrile, a cyanovinyl or an amide group and B and C are substituents which appear in the ultimate porp hyrin, frequently lower alkyl groups, particularly methyl and ethyl.
Dipyrrolic intermediates, e g., dipyrromethanes and dipyrromethenes, can be synthesized from pyrroles, and can be convened to porp hyrins by known reactions; some porp hyrins can be synthesized directly from pyrroles (see, for example, David Dolphin, supra, pages 85-100 and 163-234). Dipyrromethanes and dipyrromethenes have the following structures.
By way of
e x a m p l e ,
"Octamethyipor
phyrin" can be synthesized by heating 3,4-dimcthylpyrrole (foregoing structure, where A is HOOC, B and C are CH3 and D is CH2OH) at 160-170' and "Octacthylporphyrin" can be synthesized by heating 3,4- diethylpyrrole, where A is HOOC, B and C are CH2CH3 and D is CH2OH. Porphyrins can also be produced from dipyrromethanes by way of an aldehyde coupling reaction, a formic acid or orthoformate ester condensation, by the "dialdehyde synthesis" or by the Vilsmcicr pyrroketone synthesis, and from dipyrromethenes by the Fischer synthesis, or by reaction with dipyrromethanes. The porp hyrins that are produced have the following structure where R is hydrogen and R1 through R4 and R5 through R8 have the same meanings as B, C, E and F in the dipyrromethane and dipyrromcthene starting materials when the porp hyrins are synthesized from these precursors:
In octamethylporp hyriπ and octacthylporphyrin, R is hydrogen and R1 thiough R8 are methyl in the former and ethyl in the latter.
Ni Octaethylporphyrin, Ni Octamcthylporphyrin and Ni complexes of other known porp hyrins and of porp hyrins which can be synthesized by the procedures summarized above produce, when used in the procedure of Example A, Ni complexes of benzochlorins having the structure of Fig. 1, supra, where M is Ni and R10, R11, R12 and R14 are hydrogen. These benzochlorins, when used in the procedure of Example 1, produce Cu or Ni benzochlorinimines according to the invention having the structure set forth above, where R11 is hydrogen. The benzochlorins of Fig. 1 can be reacted with the Vilsmeier reagent to introduce a formyl group as RIO. The formyl group, after separation of the isomcrs, if necessary, can be reduced to CH3, or can be
reduced to CH2OH or converted to an oximc group, which can then be converted to a cyano group, which, in turn, can be converted to an amide. The formyl group can also be reacted with Wittig reagents to give alkyl, alkenyi or caiboxy side chains or to introduce the previously identified substituents which have an amine or an alcoholic OH function in the R9 or in the R10 position.
The procedure of Example 1, supra, produces Cu Benzochlorinimine I from Cu octacthyl benzochlorin. While octacthyl benzochlorin can be produced from m&yσ-(ß-hydroxyvinyl)-octaethyl porp hyrin, it is not possible, so far as is known, to produce the uncomplcxcd benzochlorinimine corresponding with Cu Benzochlorinimine I from octacthyl benzochlorin. Accordingly, to produce the benzochlorinimines according to the instant invention (structures set forth above) the coπesponding Ni or Cu benzochlorinimines should be produced by the method of Example 1, and the Ni or Cu should then be removed by acid treatment. Acid treatment to remove metals from porphyrins is disclosed in Vicente ct al., supra, and to remove Ni from Ni Octaethyl Benzochlorin is illustrated in Example B, below.
Example B
A 40 mg portion of Ni Octaethyl Benzochlorin was stirred for 2V. hours in 4 mL concentrated (98 percent) sulfuric acid. The reaction mixture which resulted was poured onto ice, neutralized with sodium hydrogen carbonate, and extracted with dichloromethane. Two reaction products (20 mg of each) were recovered by chromatographing the extract on silica gel. One of the products was identified as Octaethyl Benzochlorin, while the other was identified as the sulfonate thereof. The sulfonate was found to have the structure of Fig. 2, supra, where R14 is SO3Na, and is attached cither to the available carbon nearer R2 or to the available carbon nearer R3, probably the former. The octaethyl benzochlorin was crystallized from dichloromethane containing 2 v/v methanol, while the octaethyl benzochlorin sulfonate was crystallized from dichloromethane. Lambda maximum, U V, was 657 nm for both products. The S03Na group can be converted to SO3H by acidifying the sulfonate, and the hydrogen of the S03H group can be converted to other cations by neutralizing with other bases.
The Ni and other metal complexes of tire octaethyl benzochlorin and of the octacthyl benzochlorin sulfonate can be produced from octacthyl benzochlorin and from octacthyl benzochlorin sulfonate, a suitable procedure for producing the Ni complex being described below as Example C
Example C
Production of Ni octaethyl bcnzochlorin sulfonate
A solution is prepared by dissolving 20 mg octacthyl benzochlorin sulfonate in a mixed solvent composed of 15 mL dichloromethane and 5 mL methanol and a 100 mg portion of nickel acetate is added to the solution; the mixture which results is rcfluxcd for about 2 hours until the electronic spectrum of the reaction mixture indicates that chelation is complete. The reaction mixture is then concentrated to 7 mL and allowed to cool to room temperature of about 22°. Product which precipitates is recovered by filtration, dissolved in a mixed solvent composed of 5 mL dichloromethane and 2 mL methanol, and recrystallized, yielding the Ni complex of octacthylbenzochiorin sulfonate, which has the structure of Fig. 1, supra, where R1 through R8 are ethyl, R14 is SO3H, R10, R11 and R12 are hydrogen and M is Ni. The procedure of Example 1 can then be used to convert the Ni complex of octacthylbenzochiorin sulfonate to a benzochlorinimine according to the invention having the structure set forth above, and designated by legend, where R1 through R8 are ethyl, R11 is SO3H, the identities of R' and R" depend on the dialkyl formamide used, and A is Cl.
The method of Example C, supra, can be used to produce metal complexes of benzochlorinimines according to the invention. Specifically, an equivalent amount of a benzochlorinimine according to the invention can be substituted for the octacthyl benzochlorinimine, or copper acetate can be substituted for the nickel acetate, or both substitutions can be made. In this manner, benzochlorinimine metal complexes having the structure indicated by the foregoing formula where M is cither Cu or Ni can be produced from benzochlorinimines having the structure indicated by the foregoing formula. Iron complexes can be produced by the method of Example C by substituting FeCl3 for the nickel acetate, in which case M in the formula is Fe(Cl). NiCl2 can also be so substituted, in which case M in the formula is Ni(OH)2. Other benzochlorinimine metal complexes can also be made from the corresponding benzochlorinimines by the methods disclosed in "Morgan et al. II", U.S. patent No. 4,877,872, October 31, 1989 (sec column 32, line 56 to column 34, line 7) for the preparation of purp urin and chlorin metal complexes; all that is necessary is to substitute an equivalent amount of the benzochlorinimine metal complex for the purp urin or chlorin.
Similarly, porphyrinimine nickel complexes, chlorinimine nickel complexes, bactcriochlorinime nickel complexess, chlorophyllimine nickel complexes, bacteriochlorophyllimine nickel complexes, purp urinimine nickel complexes, reduced purp urinimine nickel complexes, verdinimine nickel complexes, and Diels Alder Adduct Imine nickel complexes, and isobactcriochlorin metal complexes can be produced by the method of Example 1, by substituting for the Ni Octacthyl Benzochlorin starting material an equivalent amount of the nickel complex of an appropriate porp hyrin, chlorin, bacteriochlorin, chlorophyll, bactcriochlorophyll, purp urin, reduced purp urin, verdin, Diels Alder adduct, or isobactcriochlorine to produce the desired imine. The imines can then be produced from the imine metal complexes by the method of Example B, and other imine metal complexes can then be produced by the method of Example C and the variations discussed above. The required porp hyrin starting materials are all either available or can be produced by the methods discussed above. The required purp urin metal complex and reduced purp urin metal complex starting materials can all be produced by the methods disclosed in "Morgan et al. III" (U.S. patent No. 5,051,415, granted , where the reduced purp urins are named as "chlorins"). The required Diels Alder Adducts can all be produced by the method of "Levy et al." (U.S. patent No. 4,883,790, granted November 28, 1989). The required vcrdin metal complex starting materials can all be produced by the method of Morgan et al. (supra). The required chlorin, bateriochlorin, chlorophyll, isobactcriochlorin, or bactcriochlorophyll starting material can be produced by the methods disclosed in David Dolphin, The Porphyrins, Volume II, Academic Press, New York, San Francisco and London, 1978, (sec pages 1-85 and 131 -156). The required bacteriochlorin Diels Alder Adducts to produce Imines I, II and III thereof can be produced as described in Morgan et al,. J. Med. Chem, 1990-1991, Volume 34, No. 7, pages 2126-2133, and the required starting materials to produce the Chlorinimines and metal complexes, the families of compounds which are designated Isobacteriochlorinimine I and Isobacteriochlonnimine II and the metal complexes thereof and the families of compounds which are designated bacteriochlorinimine and the metal complexes thereof, which include a CH2 group or O which, in either case, is bonded to a carbon of the pyrrole ring by a double bond, can all be produced by procedures which are disclosed in the literature. A dimcr composed of one molecule of any of the imines or imine metal complexes of the instant invention and a second molecule of the same or a different imine or imine metal complex of the instant invention or the parent porp hyrin, chlorin, bacteriochlorin, chlorophyll, bacteriochlorophyll, purp urin,
reduced purp urin, verdin, Diels Alder adduct, benzochlorin or a metal complex of one of the foregoing can be produced by the method disclosed in Morgan et al. II (supra). Such dimers are products of reaction between a CO2R', CH2mO2R' or CH2CH2CO2R' group of one of the imines or imine metal complexes and an amino nitrogen or an alcoholic OH group of the other of the imines or imine metal complexes.
By suitable substitution of starling materials, and the synthesis of porp hyrin and other starting materials as discussed above, if necessary, the procedures of Examples A and 1 can be used to produce Ni benzochlorins and other Ni imines according to the invention having the metal complex structures set forth above, where M is Ni, R' and R" can be the same or different and cacli is hydrogen or an alkyl group having from 1 to 4 carbon atoms, and each of R1 through R11 is:
H or CHO,
an alkyl group other than t-butyl having from 1 to 4 carbon atoms,
an alkylene group having from 2 to 4 carbon atoms,
a group having the formula R3N(R4)2 where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is either a single or a double bond, and not more than one is a double bond; R4 is hydrogen or an alkyl radical having from 1 to 2 carbon atoms and the two R4 groups can be the same or different,
a group having the formula R3N(R5)3 A where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is either a single or a double bond, and not more than one is a double bond; A is a physiologically acceptable anion and R5 is an alkyl group having from 1 to 2 carbon atoms and the three R5 groups can be the same or different,
a group having the formula R3OH where R3 is a bivalent aliphatic hydrocarbon radical having from 1 to 4 carbon atoms, wherein any carbon to carbon bond is cither a single or a double bond, and not more than one is a double bond, or
CO-R', CH2C02R' or CH2CH2C02R' where R' is H, or an alkyl group other than t-butyl having from one to four carbon atoms.
Benzochlorinimines according to the invention which have the structure of the foregoing formula can be produced as discussed above by removing the Cu or Ni from the corresponding Cu or Ni benzochlorinimines, and those benzochlorinimines can be metallated as discussed above to produce benzochlorinimine metal complexes where M comprises a metal cation that is complexed wiih two of the nitrogens of the benzochlorinimine and is any of those metals disclosed above. Similarly, other imines according to the invention can be produced by removing Ni from the corresponding Ni imines, and the imines can be metallized as discussed above to produce imine metal complexes where M comprises a metal cation that is complexed with two of the nitrogens of the imine and is any of those metals disclosed above.
An anion exchange resin can be used to introduce any desired anion (A- in the foregoing formulas) into an imine or imine metal complex according to the invention. The anion exchange resin is merely regenerated with a salt or acid which has the desired anion, and the imine or imine metal salt is poured through a colum packed with the anion exchange resin.
The production of Ni Benzochlorinimine I solutions in the specific non-ionic solubilizer that is availabl under the designation CREMOPHOR EL, and the production of emulsions of such solutions with
1,2-propane iol an d saline solution is described above, as is the use o f such solutions to detect and treat tumors. It will be appreciated that benzochlorinimines and other imines according to the invention and their metal complexes can be dissolved in other non-ionic solubilizers and that the solutions can be used to produce emulsions that can be administrated intravenously. For example, other reaction products of ethylene oxide and castor oil can be so used, as can reaction products of ethylene, propylene and other similar oxides with other fatty acids and the reaction products of propylene and other similar oxides with castor oil. Similarly, glycols other than 1,2-propanediol can be used in producing the emulsions for intravenous administration, or the glycol can be omitted, particularly if the solubilizer is prepared to have a lower viscosity and greater compatibility with water, by comparison with the solubilizer that is available under the designation CREMOPHOR EL. It is necessary only that the solution or emulsion be one which is physiologically acceptable and of a suitable concentration, or dilutable to a suitable concentration, for intravenous administration or for local administration, should that be desirable. An indefinitely large number of such solutions and emulsions will be apparent to those skilled in the relevant art from the foregoing specific disclosure. Similarly, the aqueous phase need not be 0.9 percent or any other concentration of sodium chloride. Such saline is presently favored for intravenous administration, but other aqueous phases can also be used, so long as the entire composition is physiologically acceptable for intravenous administration and, in fact, other aqueous phases may subsequently be favored. Indeed, other aqueous phases or organic phases may also be favored for local administration.
Dosages ranging from 3.5 to 7 mg per kg of body weight were used in the in vivo procedures described above. It has been determined only that the biological consequences described above were caused by the dosages administered, not that any dosage reported is cither a minimum or a maximum. It will be appreciated, therefore, that it is necessary only to use an effective amount of a benzochlorin or metal complex according to the invention in the detection and treatment of tumors, preferably as small a dosage as possible, and that the exact dosage can be determined by routine experimentation. While systemic administration has been described above, specifically intravenous, it will also be appreciated that local administration will be suitable, at least in some instances.
Illumination of tumors containing a benzochlorinimine or another imine or a metal complex in accordance with the instant invention can be a surface illumination with a conventional source for pulsed light of a suitable wavelength, frequency and intensity, as described above, or can be a surface illumination with a laser. The illumination can also be into the body of a tumor, for example through optical fibers inserted thereinto.
The benzochlorinimines, other imines, metal complexes, and dimers of the present invention can be used as discussed above for the treatment of tumors, and they can also be used for the dissolution of plaques in blood vessels, and for the treatment of topical conditions such as psoriasis, fungal infections, ache, athletes foot, warts, papilloma and for the sterilization of blood for transfusions, as will now be explained. While the intravenus injection of the benzochlorins and the like has been described, they can also be injected subcutaneously, intramuscularly or intrapcritoncally. Dosages can vary widely, but the in vivo test data reported above indicate that the intravenous administration of up to 7 mg per kg of body weight is safe. The benzochlorinimines and the like can be formulated in lotions, suspensions or pastes for localized treatment, e.g., of superficial tumors or skin disorders.
Various changes and modification can be made from the specific details of the invention as described above witout departing from the spirit and scope thereof as defined in the appended claims.