Synthesis and stereochemistry of the (9S,13S,14S)-3-hydroxy-17-methylmorphinan-10-ols

O-Demethylation of (9S,13S,14S)-3-methoxy-17-methylmorphinan-10-one ( 2 ) to (9S,13S,14S)-3-hydroxy-17-methylmorphinan-10-one ( 3 ) and reduction of 3 to 10α- and 10β-hydroxylated morphinans 4 and 5 , are described. The stereochemistry of these epimeric alcohols was established on the bases of ¹H nmr data.     

Synthesis and stereochemical studies of 6-substituted 1H,3H,6H,7aH-3,3-dimethylimidazo-[1,5-c]thiazol-5-one-7-thiones

The reaction of (4S)-5,5-dimethyl-4-thiazolidine-carboxylic acid 1 with alkyl and aryl isothiocyanates 2 gave bicyclic thiohydantoins 3 . The (2R,4S)- and (2S,4S)-mixtures of 2-substituted 5,5-dimethyl-4-thiazolidine-carboxylic acids 4 and 8 containing two centers of chirality in the analogous reaction afforded thiohydantoins 7 and 10 , respectively, with (1R)-configuration. In some cases we managed to isolate the thioureido acid intermediates 6 and 9 or their triethylamine salts which afforded the corresponding bicycles 7 and 10 under thermal cyclization or acidification. The stereochemistry has been elucidated by high resolution ram studies, optical rotation measurements and X-ray crystallography.     

Synthesis,characterization, and biological activity of some aza‐uracil derivatives

Thiation of 1 by LR gave the corresponding 3,5‐dithioxo derivative 2 and the trimer 3 . Methylation of 1 afforded the S‐methyl derivative 4 . Compound 1 was fused with 6‐bromo‐2‐phenyl‐benzo[1,3‐d]oxazin‐4‐one ( 5 ) and gave 6 . Condensation of 1 with some acid derivatives 7a , 7b , 7c , 7d and/or 8a , 8b , 8c yielded thiadiazolo‐triazine derivatives 9a , 9b , 9c , 9d and 10a , 10b , 10c . Compounds 9a , 9c and 10c were hydrolyzed to furnish 11a , 11b , 11c Acetylation of 14 afforded mono‐ and diacetyl‐derivatives 15 and 16 . Benzoylation of 14 afforded mono‐ and dibezoyl‐derivatives 17 and 18 . 14 with some aromatic aldehydes yielded 9a , 9b , 9c . Reacting 14 with phenyl (iso‐ and/or isothio‐) cyanate gave the urea derivatives 20a , 20b . Thiation of 14 with P₄S₁₀ furnished 21 . The newly synthesized compounds were tested as antimicrobial agents. J. Heterocyclic Chem., (2011)     

Stereoselektive Synthesen von substituierten Tricarbonyl[tris(methylen)methan]eisen(0)-Komplexen

Stereoselective Syntheses of Substituted Tricarbonyl[tris(methylen)methan]iron(0) Complexes The complexes 3 , 9 , 10 , 22 , and 23 with one, two, and three Me substituents at the tris(methylen)methane moiety have been synthesized from the (acyloxy-1,3-diene)(tricarbonyl)iron(0) complexes 1 , 4 , 5 , 20 , and 21 , respectively, by ionic hydrogenation with BF₃ and Et₃SiH at ?78° in CH₂C1₂. These reductions are completely stereoselective, and their course can be predicted by assuming a dominant stereoelectronic control of the reaction. Formation of the carbocationic intermediates 11 from 4 and 12 from 5 , e.g., takes place only if the dissociating O? C bond is antiperiplanar to the donor C(β)? Fe bond. Fast H-transfer then converts the intermediate 11 to 9 and 12 to 10 . The configurations of 17 and 20 can be deduced from the structure of 22 and those of 18 and 21 from that of 23 . An X-ray structure determination of (1R,4S)camphanoate (?)- 13 derived from alcohol (?)- 7 confirms the configuration of 5 deduced above, The structures of the complexes 9 and 10 , 22 and 23 were determined by their unique NMR spectra. The diastereoisomeric complexes 6 and 7 have been synthesized from aldehyde 8 with MeMgI, the diastereoisomers 17 and 18 analogously from 16 or from methyl ketone 19 by reduction with LiAlH₄. Optically active starting materials (+)- 1 , (?)- 13 , (+)- 20 , and (+)- 21 gave, by ionic hydrogenation, the complexes (?)-(3R)- 3 , (+)-(2S,4S)- 10 , (?)-(R,R, S)- 22 , and (?)-(R,R,R)- 23 respectively, with known absolute configurations.     

Umwandlung von Krötengiften (Bufadienoldien) durch Mikroorganismen IV. 7β-Hydroxybufalin, 7β-Hydroxyresibufogenin und 12α-Hydroxyresibufogenin. 16. Mitteilung über Reaktionen mit Mikroorganismen [1]

Bufalin ( 1 ) was transformed to 7β-hydroxybufalin ( 2 ) by an aqueous suspension of the mycelium of Absidia orchidis VUILL. (HAGEM. ). Incubation of resibuforgenin ( 9 ) under the same conditions yielded 12α-hydroxyresibufogenin ( 7 ) and, under changed conditions, another monohydroxylated derivative which possesses most likely the structure of 7β-hydroxyresibufogenin ( 10 ). The corresponding cardenolide 3-O-acetyl-14β, 15β-epoxy-14-anhydro-digitoxigenin ( 17 ) gave both the 7β- and the 12α-monohydroxylated derivatives 18 and 22 and another monohydroxylated product 21 of unknown structure. All microbial transformation products are new.     

Heteroannulation of 2-amino-6-thioxouracil: A new access for the synthesis of fused pyrimidine derivatives

In current work, heteroannulation of 2-amino-6-thioxouracil to new fused pyrimidine scaffolds is described, where pyrimidine 1 undergoes cyclocondensation with pyruvic acid derivative 2 and ninhydrin ( 6 ) to furnish thiopyranopyrimidine 5 and thienopyrimidine 8 , respectively. Alkylation of aminopyrimidine 1 with benzyl chloride consumed two moles to form S- and N-alkylated product 9 . Subjecting compound 9 to aminolysis with aniline derivatives resulted in 4-aminopyrimidine 10a , b through Dimorth rearrangement. Furthermore, the addition of cyclic enamine 10a , b to ninhydrin and benzoyl isothiocyanate produced pyrimidine derivatives 12a,b and 14 . Finally, the addition of enamenic carbon of 10a , b to polarized systems 2 or 18 afforded the pyrido[2,3-d]pyrimidines 17 and 21a-d in moderate to good yield.     

Totalsynthese von (+)-D-Homo-19-nortestosteron

Total Synthesis of (+)-D-Homo-19-nortestosterone A novel total synthesis of (+)-D-homo-19-nortestosterone ( 2 ) is described starting from (4a S, 5S)-5-(t-butoxy)-4a-methyl-4, 4a, 5, 6, 7, 7-hexahydro-3 H-naphthalen-2-one ( 3 ) as a chiral building block for the rings C and D. The key step involves combining of the derived reactive one-carbon atom adducts 5 and 6 with the β-keto ester 16 , a synthon for the rings A and B, to give the Δ⁹-4, 5-secosteroid 21 . 21 was readily transformed to the title compound 2 by hydrogenation and subsequent ring closure. Hydrogenation of the derived 3, 5-dione 22 followed by base-catalyzed cyclization gave the 17a-t-butoxy compound 27 and the 9β, 10α-D-homosteroid 29 as by-product.     

Tannins and Related Compounds from Quisqualis Indica

Continuous exploration of the chemical constituents of Combretaceous plants has led to the discovery of two novel ellagitannins, quisqualin A ( 1 ) and quisqualin B ( 2 ), from the fruits of Quisqualis indica. A total of twenty-one other tannins were also isolated from either the fruits or leaves of Q. indica. including [I] eleven ellagitannins: 2,3-(S)-HHDP-D-glucose ( 3 ), 2,3-(S)-HHDP-4-O-galloyl-D-glucose ( 4 ), 2,3-(S)-HHDP-6-O-galloyl-D-glucose ( 5 ), 2,3-(S)-HHDPA6-di-O-galloyl-D-glucose ( 6 ). pedunculagin ( 7 ), punicalagin ( 8 ), eugeniin ( 9 ), 1-desgalloyleugeniin ( 10 ), casuariin ( 11 ), 5-desgalloylstachyurin ( 12 ), castalagin ( 13 ); [II] five gallotannins-. 6-O-galloyl-D-glucose ( 14 ), 1,6-di-O-galloyl-β-D-glucose ( 15 ), 2,3-di-O-galloyl-D-glucose ( 16 ), 3,4-di-O-galloyl-D-glucose ( 17 ), 4,6-di-O-galloyl-D-glucose ( 18 ); [III] four phenol-carboxylic acids: gallic acid ( 19 ), ellagic acid ( 20 ), flavogallonic acid ( 21 ), brevifolin carboxylic acid ( 22 ) and [IV] one other hydrolyzable tannin: punicalin ( 23 ).     

The synthesis of 1H-benzimidazole derivatives containing a 9H-xanthene or 9H-thioxanthene ring

2-(9H-Xanthen-9-ylmethyl)-1H-benzimidazole ( 2a ) was prepared by condensing 9H-xanthene-9-acetic acid ( 1a ) with 1,2-benzenediamine. Similarly, 2-(9H-thioxanthen-9-ylmethyl)-1H-benzimidazole ( 2b ) and its S,S-dioxide ( 2d ) were obtained. Compound 2d was also prepared by oxidizing 2b with hydrogen peroxide in acetic acid. Heating of 9H-thioxanthene-9-acetic acid 10-oxide ( 1c ) with 1,2-benzenediamine gave 9-methylene-9H-thioxanthene ( 3 ). 2-(9H-Thioxanthen-9-ylmethyl)-1H-benzimidazole S-oxide ( 2c ) was obtained by oxidizing 2b with m-chloroperbenzoic acid in acetone.     

Asymmetric Synthesis of α-Amino Acids and α-N-Hydroxyamino Acids from N-Acylbornane-10,2-sultams: 1-chloro-1-nitrosocyclohexane as a practical [NH] equivalent

Successive treatment of N-acylsultams 3 with sodium hexamethyldisilazide, 1-chloro-1-nitrosocyclohexane ( 1 ), and aq. HCl gave diastereoisomerically pure, crystalline N-hydroxyamino-acid derivatives 5 . These were converted into various amino acids 7 , N-hydroxyamino acids 8 , and an N-Boc-amino acid 9 . (S, S)-Isoleucine ( 17 ) and (S, S)-2-acetamido-3-phenylbutyric acid ( 23 ) were obtained from N-crotonoylsultam 15 via 1,4-addition of an organomagnesium or organocopper reagent followed by enolate ‘amination’ with 1 .     

Furopyridines. II. Bromination and nitration of furo[2,3-b]-, furo[3,2-b]-, furo[2,3-c]- and furo[3,2-c]pyridine

In order to reveal the reactivities of furopyridines, we undertook bromination and nitration of four furopyridines ( 1, 2, 3 and 4 ) whose chemical properties had been almost unknown. Bromination of 1, 2, 3 and 4 gave the corresponding trans-2,3-dibromo-2,3-dihydro derivatives 6, 8, 10 and 12 , respectively, which were converted to 3-bromofuropyridines 7, 9, 11 and 13 by treatment with sodium hydroxide in aqueous methanol. Nitration of 1 with a mixture of fuming nitric acid and sulfuric acid afforded a mixture of addition products 14a, 14b and 14c and 2-nitro derivative 15 . Both 14a and 14b were easily converted to 15 by treatment with sodium bicarbonate. Compound 2 was nitrated to give a mixture of cis- and trans-2-nitro-3-hydroxy-2,3-dihydro derivative 16a and 16b and 2-nitro derivative 17 . The cis isomer 16a was transformed to the trans isomer 16b by refluxing on silica gel in ethyl acetate. Compound 16b was dehydrated with acetic anhydride to give 17 . Nitration of 3 gave a nitrolic acid derivative 20 . Nitration of 4 gave a mixture of 2-nitro derivative 22 and 3-(trinitromethyl)pyridin-4-ol ( 23 ). The structures of 20 and 23 were established by single crystal X-ray analysis. The differences of behavior observed in these reactions are discussed in connection with the results of the determination of pKa values and the relative reactivities of deuteriodeprotonation of these furopyridines.     

N-Monoalkylation of Tetra-O-benzyl-D-arabinonamide: Synthesis of Some Open-Chain Analogues of N-Acetylneuraminic Acid and Their Evaluation as Sialidase Inhibitors

N-Arabinonoylglycine 2 , its phospho analogue (arabinonoylamino)methylphosphonate 14 , N-arabinonoyltaurine salt 18 , and [2-(arabinonoylamino)ethylidene]bis[phosphonic acid] 22 have been synthesized from D -arabinose in seven ( 2 or 14 ), and eight steps ( 18 or 22a ), respectively. With the exception of the salt 22b , none of these compounds showed a significant inhibitory activity in vitro against the sialidases of Vibrio cholerae, Salmonella typhimurium, or Influenza A (N9), or B (B/Lee/40) virus. Ammonolysis of the oxosulfonate 8 obtained by oxidation of the hydrogensulfite adduct 7 of 2,3,4,5-tetra-O-benzyl-aldehydo-D -arabinose ( 6 ) yielded the primary amide 9 (64% from 6 ), which was alkylated with the triflates 10 or 11 of benzyl glycolate and dibenzyl hydroxymethylphosphonate, respectively, to give the protected N-arabinonoylglycinate 12 and the (arabinonoylamino)methylphosphonate 13 (45 and 90%, resp.). N-Alkylation of 9 with 2-bromoethyl triflate 15 followed by nucleophilic displacement with sodium sulfite yielded the protected taurine analogue 17 (21% from 9 ), whereas the protected tetraethyl bis[phosphonate] 20 was formed in 90% yield by 1,4-addition of 9 to tetraethyl ethenylidenebis[phosphonate] 19 . Debenzylation of 12 and 13 , followed by purification by reversed-phase HPLC gave the triethylammonium salt of N-(D -arabinonoyl)glycine ( 2 ) and triethylammonium (D -arabinonoylamino)methylphosphonate ( 14 b ), respectively, whereas the deprotection of 17 afforded the N-(D -arabinonoyl)taurine salt 18 . Debenzylation of 20 , followed by treatment with Me₃SiBr and hydrolysis of the resulting silyl ester gave the bis[phosphonic acid] 22 a (3 steps, 88%).     

3,6-Thioanhydro sugar derivatives. An enantiospecific synthesis of (2R,3R,4S)-3-benzyloxy-4-hydroxy-2-[(R)-1-benzyloxy-4-hydroxybutyl]thiolane as the key intermediate for thioswainsonine

Methyl 2-O-benzyl-3,6-thioanhydro-α-D-mannopyranoside ( 9 ) was obtained in eight steps from the commercially available methyl α-D-glucopyranoside. Compound 9 was transformed into (2R,3R,4S)-3-benzyloxy-4-hydroxy-2-[(R)-1-benzyloxy-4-hydroxybutyl]thiolane ( 14 ) by acid hydrolysis of its 2,4-di-O-benzyl derivative 10 followed by reaction of the not isolated 2,4-di-O-benzyl-3,6-thioanhydro-D-mannose ( 11 ) with ethoxycarbonylmethylenetriphenylphosphorane to give an = 1:1 E/Z mixture of the corresponding α,β-unsaturated ester ( 12 ). Finally, catalytic hydrogenation of 12 to ethyl (R)-4-benzyloxy-4-[(2′R)3′R,4′S)-3′-benzyloxy-4′-hydroxythiolan-2′-yl]butanoate ( 13 ) and subsequent reduction with lithium aluminum hydride gave the title compound 14 .     

Chirale Synthesebausteine durch Kolbe-Elektrolyse enantiomerenreiner β-Hydroxy-carbonsäurederivate. (R)- und (S)-Methyl-sowie (R)-Trifluormethyl-γ-butyrolactone und -δ-valerolactone

Chiral Building Blocks for Syntheses by Kolbe Electrolysis of Enantiomerically Pure β-Hydroxybutyric-Acid Derivatives. (R)- and (S)-Methyl-, and (R)-Trifluoromethyl-γ-butyrolactones, and -δ-valerolactones The coupling of chiral, non-racemic R* groups by Kolbe electrolysis of carboxylic acids R*COOH is used to prepare compounds with a 1.4- and 1.5-distance of the functional groups. The suitably protected β-hydroxycarboxylic acids (R)- or (S)-3-hydroxybutyric acid, (R)-4,4,4-trifluoro-3-hydroxybutyric acid (as acetates; see 1 – 6 ), and (S)-malic acid (as (2S,5S)-2-(tert-butyl)-5-oxo-1,3-dioxolan-4-acetic acid; see 7 ) are decarboxylatively dimerized or ‘codimerized’ with 2-methylpropanoic acid, with 4-(formylamino)butyric acid, and with monomethyl malonate and succinate. The products formed are derivatives of (R,R)-1,1,1,6,6,6-hexafluoro-2,5-hexanediol (see 8 ), of (R)-5,5,5-trifluoro-4-hydroxypentanoic acid (see 9,10 ), of (R)- and (S)-5-hydroxyhexanoic acid (see 11 ) and its trifluoro analogue (see 12, 13 ), of (S)-2-hydroxy- and (S,S)-2,5-dihydroxyadipic acid (see 23, 20 ), of (S)-2-hydroxy-4-methylpentanoic acid (‘OH-leucine’, see 21 ), and of (S)-2-hydroxy-6-aminohexanoic acid (‘OH-lysine’, see 22 ). Some of these products are further converted to CH₃- or CF₃-substituted γ- and δ-lactones of (R)- or (S)-configuration ( 14 , 16 – 19 ), or to an enantiomerically pure derivative of (R)-1-hydroxy-2-oxocyclopentane-1-carboxylic acid (see 24 ). Possible uses of these new chiral building blocks for the synthesis of natural products and their CF₃ analogues (brefeldin, sulcatol, zearalenone) are discussed. The olfactory properties of (R)- and (S)-δ-caprolactone ( 18 ) are compared with those of (R)-6,6,6-trifluoro-δ-caprolactone ( 19 ).     

Über Pterinchemie 76. Mitteilung [1] Eine einfache Synthese von Leucovorin

A Convenient Synthesis of Leucovorin The synthesis of leucovorin, a 5-formyl-(6R or S)-5,6,7,8-tetrahydropteroyl-L -glutamic acid (II) is described. The L -folic acid was first reduced to (6R, S)-tetrahy-dro-L -folic acid (I); formylation with methyl-formate in DMSO gave directly leucovorin (as a diastereomeric mixture) in good yields. To demonstrate, that the formylation occurred regiospecifically at N (5) and not at N (10), N (10)-nitroso-(6 R, S)-tetrahydro-L -folic acid was formylated under the same conditions. Reductive elimination of the N (10)-nitrosogroup gave the identical leucovorin as in the previous case. The synthetic leucovorin was biologically as active as the natural product with Streptococcus faecalis ATCC 8043 and Pediococcus cerevisiae ATCC 8081.     

Furopyridines. VI. Preparation and reactions of 2- and 3-substituted furo[2,3-b]pyridines

This paper describes the synthesis and chemical properties of some 2- and 3-substituted furo[2,3-b]pyridines. Reaction of ethyl 2-chloronicotinate 1 with sodium ethoxycarbonylmethoxide or 1-ethoxycarbonyl-1-ethoxide gave β-keto ester 2 or ketone 5 , respectively. Ketonic hydrolysis of 2 afforded ketone 3, from which furo[2,3-b]pyridine 4 was obtained by the method of Sliwa. While, 2-methyl derivative 7 was prepared from 5 by reduction, O-acetylation and the subsequent pyrolysis. Reaction of ketone 3 with methyllithium gave tertiary alcohol 8 which was O-acetylated and pyrolyzed to give 3-methyl derivative 9 . Formylation of 4 , via lithio intermediate, with DMF yielded 2-formyl derivative 10 , from which 7 , was obtained by Wolff-Kishner reduction. Dehydration of the oxime 11 of 10 gave 2-cyano derivative 12 , which was hydrolyzed to give 2-carboxylic acid 13 . Reaction of 3-bromo compound 14 with copper(I) cyanide gave 3-cyano derivative 15 . Alkaline hydrolysis of 15 afforded compound 16 and 17 , while acidic hydrolysis gave carboxamide 18 . Reduction of 15 with DIBAL-H afforded 3-formyl derivative 19 . Wolff-Kishner reduction of 19 gave no reduction product 9 but hydrazone 20 . Reduction of tosylhydrazone 21 with sodium borohydride in methanol afforded 3-methoxymethylfuro[2,3-b]pyridine 22 .     

Synthese von zwei natürlich vorkommenden Lactonen mit 10gliedrigen Ringen: (±)-Phoracantholid J und I

Synthesis of Two Naturally Occurring 10-Membered Ring Lactones: (±)-Phoracantholide J and I Two 10-membered ring lactones 7 and 11 from the metasternal secretion of the eucalypt longicorn Phoracantha synonyma have been synthesized by the following method. Reaction of the dilithium derivative of 4-pentynoic acid ( 3 ) with 4-tetrahydropyranyloxy-1-pentylbromide ( 2 ), followed by removal of the protecting group and by esterification with diazomethane, gave methyl 9-hydroxy-4-decynoate ( 4 ; s. Scheme 1). Partial hydrogenation of the triple bond in 4 with Lindlar palladium catalyst, followed by saponification lead to cis-9-hydroxy-4-decenoic acid ( 6 ). The 9-hydroxydecanoic acid ( 9 ) was synthesized by addition of methyl magnesium iodide to methyl 8-formyloctanoate ( 8 ) followed by saponification (s. Scheme 2). The hydroxy acids 6 and 9 were converted into the S-(2-pyridyl) thioesters and cyclized in dilute benzene solution under the influence of silver ions to yield (±)-phoracantholide J ( 7 ) and I ( 11 ) in 74 and 71% yield, respectively.     

Totalsynthese von Decarboxybetalainen durch photochemische Ringöffnung von 3-(4-Pyridyl)alanin

Total Synthesis of Decarboxybetalaines by Photochemical Ring Opening of 3-(4-Pyridyl)alanine A photochemical approach is presented for the total synthesis of the decarboxybetalaines, which were previously known from the mild decarboxylation of the natural plant colorants, the betalaines: Irradiation of rac-3-(4-pyridyl)alanine ( 1 ) yielded the rac-2-decarboxybetalamic-acid-imine ( 4 , 86%), presumably via a Dewar pyridine 2 , a cyclic aminal 3 and an electrocyclic ring opening. The imine-zwitterion 4 was treated with three amines, namely (S)-cyclodopa ( 6 ), (S)-proline ( 7 ), and indoline ( 8 ), to afford three decarboxybetalaines, namely (2S)-17-decarboxybetanidine ( 9 , red, 34%), (2S)-13-decarboxyindicaxanthine ( 10 , yellow, 56%), and rac-16-decarboxyindobetalaine ( 11 , orange, 78%), respectively. The structures of these coloring matters were confirmed by their electrophoretic behavior and their spectroscopic properties. 17-Decarboxybetanidine 9 was shown to be a ca. 1:1 mixture of two C(15)-epimers 9a and 9b , separable by chromatography. The configuration of 9a was determined as (2S, 15S) and that of 9b as (2S, 15R), by correlating their optical rotations with those of betanidine ( 12a ) and isobetanidine ( 12b ), respectively. The decarboxybetalaines 9 , 10 , and 11 did not show the double-bond isomerism at C(β), (Cγ) of the chromophore which had been found characteristic for the corresponding betalaines 12 , 13 , and 14 .     

Studied Directed toward the Synthesis of Phomenoic Acid. Part 2. Stereocontrolled Synthesis of the C(7)-to-C(14) Segment

Starting from the esters (2E,4S)- 6 and (2E,4R)- 6 , bromo aldehydes (S)- 9 and (R)- 9 as well as bromo alcohols (S)- 10 and (R)- 10 , respectively, were prepared. Bromo alcohol (R)- 8 was converted to the diol (2E,4R)- 16 . Ozonolysis of the latter led to aldehyde (R)- 17 , which was transformed, by a Wittig reaction, to (2R,4E,6R)- 18 , corresponding to the C(7)-to-C(14) segment of phomenoic acid ( 1 ). Attempts to improve the yields by applying a Julia coupling of (R)- 23 , which was prepared from (2E,4R)- 7 , with (R)- 24 were unsuccessful. Finally, the coupling of the iodo derivative (2E,4S)- 28 with the lithiated derivative of 1,3-dithiane 30 by the Corey-Seebach ‘Umpolung’ led to (3S,4E)- 32 which is a derivative of the C(7)-to-C(14) segment of 1 , suitable for further transformations.     

Glyconothio-O-lactones. Part III. Thermolysis of a 4,5-Dihydro-1,2,3- and a 2,5-Dihydro-1,3,4-thiadiazole

Addition of CH₂N₂ to 2,3:5,6-di-O-isopropylidene-1-thio-mannono-1,4-lactone ( 1 ) gave the 2,5-dihydro-1,3,4-thiadiazole 2 and the 4,5-dihydro-1,2,3-thiadiazole 3 . First-order kinetics were observed for the thermolysis of 3 (Scheme 3) at 80–110° in C₆D₅Cl solution and of 2 (Scheme 3) at 20–35° in CDC1₃, respectively. The 1,2,3-thiadiazole 3 led to mixtures of the thiirane 9 , the starting thionolactone 1 , the thiono-1,5-lactone 8 , and the enol ether 7 , while the isomeric 1,3,4-thiadiazole 2 led to mixtures of the anomeric thiiranes 9 and 12 , the O-hydrogen S,O,O-ortholactone α-D - 14 , the S-methyl thioester 15 , the S,S,O-ortholactone 13 , and the 2,3:5,6-di-Oisopropylidene-mannono-1,4-iactone ( 16 ). Pure products of the thermolysis were isolated by semipreparative supercritical fluid chromatography (SFC), whereas preparative HPLC led to partial or complete decomposition. Thus, the β-D -mannofuranosyl β-D -mannofuranoside 10 , contaminated by an unknown S species, was isolated by preparative HPLC of the crude product of thermolysis of 3 at 115–120° and partially transformed in CD₃OD solution into the symmetric di(α-D -mannofuranosyl) tetrasulfide 11 . Its structure was evidenced by X-ray analysis. Similarly, HPLC of the thermolysis product of 2 gave the enethiol 17 , the sulfide 19 , and the mercapto alcohol 18 as secondary products. Thermolysis of the thiirane 9 at 110–120° (Scheme 4) led to the anomeric thiirane 12 which was transformed into mixtures of the enethiol 17 and the enol ether 7. Addition of H₂O to 17 and 7 gave the corresponding hemiacetals 18 and 20. The mechanism of the thermolysis of the dihydrothiadiazoles 2 and 3 , and the thiiranes 9 and 12 is discussed.