United States Patent [191 [1 1] 4,045,440 Rapoport Et A1

United States Patent [191 [1 1] 4,045,440 Rapoport Et A1

United States Patent [191 [1 1] 4,045,440 Rapoport et a1. [45] Aug. 30, 1977 [54] METHOD OF PRODUCING THEBAINE Primary Examiner-Donald G. Daus FROM CODEINE AND ORIPAVINE FROM Assistant Examiner-Diana G. Rivers MORPHINE Attorney, Agent, or Firm-John S. Roberts, Jr.; Norman [75] Inventors: Henry Rlpoport; Randy B. Barber, J. Latker; Thomas G. Ferris both of Berkeley, Calif. [57] ABSTRACT [73] Assignee: The United States of America as represented by the Department of A method of producing thebaine from codeine and Health, Education and Welfare, oripavine from morphine which comprises (a) produc Washington, DC. ing the 0-6 methyl ethers from codeine and morphine using potassium hydride and methyl iodide as the O [21] Appl.No.: 724,018 alkylation agents and (b) subsequently oxidizing the [22] Filed: Sept. 16, 1976 respective 0-6 methyl ethers of codeine and morphine to shift from allylic structure to a dienol ether structure [51] Int. Cl.2 .......................................... .. C07D 489/02 using an oxidizing amount of M1102 in tetrahydrofuran [52] US. Cl. .................................................. .. 260/285 to produce thebaine from codeine and oripavine from [58] Field of Search ....................................... .. 260/285 morphine. In the case of morphine, it is preferable to [56] References Cited protect the 0-3 position by acetylation prior to the oxi dizing step. Both the etheri?cation and oxidizing steps FOREIGN PATENT DOCUMENTS are carried out under a protecting blanket such as nitro 1,133,392 7/l962 Germany gen and the reactions are carried out preferably under atmospheric pressure and ambient temperature with the OTHER PUBLICATIONS exception of the etheri?cation affecting the 0-6 position Barber et al., J. Med. Chem, vol. 18, No. 11, pp. which may be commenced by cooling with ice. 1074-1077 (Nov. 1975). ' Martin et al., J. Org. Chem, vol. 33, 3758-3761 (1968). 4 Claims, No Drawings 4,045,440 1 2 TABLE l-continued METHOD OF PRODUCING THEBAINE FROM Structures of Certain Opiates Chemically CODEINE AND ORIPAVINE FROM MORPI-IINE Related to Morphine Chemical Radicals The present invention is concerned with producing Nonproprietary and Positions Other particularly certain phenanthrene opiate derivatives Name 3" 6' l6‘ Changes+ and in particular thebaine and oripavine. It has been Codeine —OCH3 —OH —CH; —— found that these members of the opium alkaloid family Thebaine —OCH, —OCH; e-CH; (l) ‘The numbers 3, b, and 16 refer to positions in the morphine molecule as shown may be produced by the present process from the most above. abundant opium alkaloids, namely, morphine and co ‘Other changes in the morphine molecule are: deine, and the production of thebaine and oripavine, (1) Double bonds ll AIn and Au‘ replacing A“. which are quite rare in nature, has greater pharmaco logical potential for the production of drugs combatting PRIOR ART addiction. Essentially, the present process involves starting with 15 The prior art appears vacant as to the conversion of codeine and morphine and producing the 0-6 methyl allylic ethers to dienol ethers using MnOz as an oxidant ether from each and further oxidizing the C-ring which and specially in the application of the conversion of contains the 0-6 substituent to oxidize or dehydrogenate thebaine from codeine and oripavine from morphine. and effect a shift from an allyl ether to a dienol ether. The present process utilizing codeine and morphine as This results in the loss of 2 hydrogens from the ring C 20 reactants ?rst produces an ether at the 0-6 position of and the consequent change of A“ to A6‘? and AM‘. the C ring using potassium hydride and methyl iodide, in the case of morphine which, by this process, pro the latter as a methylating agent. duces oripavine, it is preferred to block the 0-3 position As a second step, the codeine methyl ether and the of the C ring prior to oxidizing. This may be conve morphine 0-6 methyl ether (preferably as the 0-3 ace niently done by acetylation to produce the O-acetate, 25 tate) are then shaken with tetrahydrofuran and manga although the reaction will go without this protective nese dioxide resulting in thebaine and oripavine, respec step with reduced yield. tively. A preferred solvent or carrier in both the etheri?ca The basic journal article of the present inventors is tion procedure and the oxidation procedure with man herewith cited: ganese dioxide is tetrahydrofuran, an acyclic ether. 30 Barber and Rapoport, J. Med. Chem., 18:1074-1076 Satisfactory alternatives are ethyl ether and dioxane. (November 1975). As illustrative, the structures for morphine and oripa REACTANTS vine are set out below and Table ] shows the structure relationships of the reactants and products of this inven The ?rst step of the process is O-alkylation at 0-6 of tion. 35 ring C of the phenanthrene structure utilizing potassium hydride and methyl iodide. In the case of morphine, the 0-3 position may be blocked by acetylation using acetic acid. The second step is oxidation of the C ring with man ganese dioxide. Of the various forms of manganese dioxide available, all will function as oxidizing agents and the investigators preferred the 'y isomer, which is more prevalent (see Kirk-Othmer, Encyclopedia of Chemical Technology II, Vol. 13, pages 19-20). In the 45 oxidation, the 'y MnO; gave yields ranging from 67-82% overall and, in addition, MnOz on a charcoal support was utilized. The manganese dioxide gave sig ni?cantly better yields than organic oxidizing agents, such as DDQ (2,3-dichloro-5,6-dicyano-l,4-benzoqui 50 none) or o-chloranil. In a comparative reaction with DDQ producing thebaine, it was found that at least two equivalents of DDQ were necessary, the ?rst equivalent forming a benzene insoluble complex with codeine methyl ether (CME). Of the inorganic oxidants CrO3. 55 PY; and selenium dioxide were also used but no produc tion of thebaine from codeine methyl ether was de tected. The oxidation of the C ring with maganese dioxide Oripavine produces an oxidation and change of the allylic ether to a dienol ether. This method may have broad applicabil ity based on the oxidation and consequent loss of two TABLE 1 hydrogens and the production of the two double bonds Structures of Certain Opiates Chemically in the dienol pattern. However, in the speci?c ?eld of Related to Morphine opiates, it was shown that the attempted oxidation of Chemical Radicals Nonproprietary _ and Positions Other 65 isocodeine methyl ether (i-CME) and geranyl methyl Name 3’ 6' 16' Changes‘ ether was not successful and both were recovered un Morphine —OH —OH -CH; — changed. It is surmised that in the case of i-CME the Ortpavme —OH —OCH, —CH_, (1) reason may be steric in nature, since the hydrogens 4,045,440 3 4 being removed are trans. Therefore, one must recognize ple of codeine methyl ether by TLC, GC, mass spec that the present process is speci?c to certain structures trum, and NMR. such as the present 0-6 morphine and codeine ethers. EXAMPLE 2 THE CHANGE IN THE C RING Thebaine by Oxidation with 'y-MnO; The oxidation of the C ring removes two hydrogens A solution of codeine methyl ether (343 mg, 1.00 and the double bond at A" becomes two double bonds mmol) in THF (10 ml, distilled from LiAlH4) was at A65’ and All-l4. Thus, the 0-6 methyl ether for codeine shaken vigorously with 'y-MnOZ (440 mg, 5.0 mmol) and morphine shifts from an allyl con?guration to a under a nitrogen atmosphere at room temperature. Fur dienol con?guration. The preferred oxidizing agent is ther portions of 'y-MnOz (440 mg, 5.0 mmol) were added MnOz and the investigators have preferred ‘)1 MnO2. at intervals of l, 3, 5, and 10 hr. After 24 hr. the black The contrasting value to other organic and inorganic mixture was ?ltered through a ?ne sintered glass funnel, oxidizing. agents has been set out above. the residue was washed with THF (4 X 50 ml), and the REACTION CONDITIONS washings were combined with the original ?ltrate and evaporated to give 207 mg of crude thebaine. The A. The Etherifying Step at 0-6 MnOZ was then washed with methanol (4 X 30 ml) In the investigative procedure, the etherifying step is which yielded an additional 119 mg of crude thebaine. carried out at ambient temperature and pressure. A 3:1 The two fractions were combined and crystallized from molar ratio is preferred for codeine/methyl iodide. In ethanol to give thebaine (251 mg, 80%) identical with the production of morphine-6-methyl ether, potassium an authentic sample by mp (l9l°—l92°), TLC, GC, mass hydride was used with the methyl iodide and the mor spectrum [m/e 311 (M+)], and NMR. phine was added in the cold (ice). The remainder of the reaction was carried out at room temperature (rt). EXAMPLE 3 B. Oxidation of the C Ring Thebaine by Oxidation with DDQ An inert atmosphere is preferred in the oxidation step and the investigators teach, for example, a nitrogen To a stirred solution of codeine methyl ether (156 mg, blanket. The reaction is carried out at room temperature 0.5 mmol) in 5 ml of benzene under a nitrogen atmo and a large molar excess of MnOz has been utilized; for ‘ sphere was added 2,3-dichloro-5,6-dicyano-1,4-ben example, 1.00 mmol of codeine methyl ether reacted zoquinone (DDQ) (119 mg, 0.525 mmol) and the dark with 25 mmol of )1 MnO; added sequentially. green precipitate (272 mg) which formed was collected by ?ltration.

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