Pyridinium reduction

Two synthetic bridged nitrogen heterocycles are also prepared on a commercial scale. The pentazocine synthesis consists of a reductive alkylation of a pyridinium ring, a remarkable and puzzling addition to the most hindered position, hydrogenation of an enamine, and acid-catalyzed substitution of a phenol derivative. The synthesis is an application of the reactivity rules discussed in the alkaloid section. The same applies for clidinium bromide. 

Pyridinium iodide, 4,4 (l,3,4-thiadiazole-2,5-diyl)-bis(l-methyl)-reduction, 6, 564 Pyridinium ion, Af-methyl-as metabolite of pyridine, 1, 234 Pyridinium ions hydrogen bonding to water mass spectrometry, 2, 135 magnetic circular dichroism, 2, 129 NMR, 2, 121... 

Pyridinium salts, 4-methoxy-l-methyl-3-nitro-reduction... 

Pyrrolo[2,3-6]pyridinium iodide, 1,7-dimethyl-reduction, 4, 508 Pyrrolo[3,2- 6]pyridin-2-ones spectra, 4, 502... 

Generated by one-electron reduction of the pyridinium salt. Stable, distillable, and only moderately reaetive to oxygen. 

When a pyridinium salt such as (27) is treated with sodium borohydride, the final product is the tetrahydropyridine (30). The mechanism for this reaction was proposed by Katritzky (65) and experimentally verified by Anderson and Lyle (66-68). The sequence is visualized as reduction of the... 

Lithium aluminum hydride reduction of pyridinium salts is very similar to sodium horohydride reduction and gives similar products, but the ratio of 1,2- and 1,4-dihydro- or tetrahydropyridines differs considerably (5). Isoquinolinium salts are reduced hy sodium borohydride or lithium aluminum hydride in a manner identical to pyridinium salts (5). Quino-linium salts are reduced by sodium borohydride to give primarily tetra-hydroquinolines (72) as shown by the conversion of 33 to 34 and 35. When lithium aluminum hydride is used, the product is usually the dihydroquinoline (73) as shown in the conversion of 36 to 37 and 38. 

The reduction (136) of pyridinium compounds to 1,2- or 1,4-dihydro products with complex metal hydrides or dithionite leads to cyclic di-enamines of synthetic and biochemical interest. 

Thus the critical synthetic 1,6-dihydropyridine precursor for the unique isoquinuclidine system of the iboga alkaloids, was generated by reduction of a pyridinium salt with sodium borohydride in base (137-140). Lithium aluminum hydride reduction of phenylisoquinolinium and indole-3-ethylisoquinolinium salts gave enamines, which could be cyclized to the skeletons found in norcoralydine (141) and the yohimbane-type alkaloids (142,143). 

Eda and Kurth applied a similar solid-phase combinatorial strategy for synthesis of pyridinium, tetrahydropyridine, and piperidine frameworks as potential inhibitors of vesicular acetylcholine transporter. One member of the small library produced was prepared from amino-functionalized trityl resin reacting with a 4-phenyl Zincke salt to give resin-bound product 62 (Scheme 8.4.21). After ion exchange and cleavage from the resin, pyridinium 63 was isolated. Alternatively, borohydride reduction of 62 led to the 1,2,3,6-tetrahydropyridine 64, which could be hydrogenated to the corresponding piperidine 65. 

The configuration of the amine was retained, except in the case of amino acid derivatives, which racemized at the stage of the pyridinium salt product. Control experiments showed that, while the starting amino acid was configurationally stable under the reaction conditions, the pyridinium salt readily underwent deuterium exchange at the rz-position in D2O. In another early example, optically active amino alcohol 73 and amino acetate 74 provided chiral 1,4-dihydronicotinamide precursors 75 and 76, respectively, upon reaction with Zincke salt 8 (Scheme 8.4.24). The 1,4-dihydro forms of 75 and 76 were used in studies on the asymmetric reduction of rz,>S-unsaturated iminium salts. 

Marazano and co-workers have used the Zincke reaction extensively to prepare chiral templates for elaboration to substituted piperidine and tetrahydropyridine natural products and medicinal agents. For example, 3-picoline was converted to Zincke salt 40 by reaction with 2,4-dinitrochlorobenzene in refluxing acetone, and treatment with R- -)-phenylglycinol in refluxing n-butanol generated the chiral pyridinium 77. Reduction to... 

Direct addition of Grignard reagents to Zincke-derived chiral pyridinium salts such as 99, meanwhile, allowed subsequent reduction to 1,2,3,6-tetrahydropyridines (e.g., 100, Scheme 8.4.32). This strategy provided entry to asymmetric syntheses of (-)-lupetidin and (+)-solenopsin. Tetrahydropyridines prepared by reduction of chiral... 

Further elaboration of 152 resulted in the synthesis of (derived from the reduction of pyridinium salt 150b with excess of LiAlFt4 in THE Acid-catalyzed cyclization of 154 led to indoloquino-lizidine 155 (25% yield from 150b), a precursor of deplancheine (80TL2341) (Scheme 5). 

A convenient synthesis of 5-(methoxymelhoxy)-2-pentenal was accomplished by selective reduction of 5 to 6, followed by oxidation with pyridinium chlorochromale (59). 

The reaction product (1-carbethoxymethyM-carbomethoxy-pyridinium bromide) was obtained in crystalline form. (It formed prisms melting at 166°-169°C after recrystallization from a mixture of isopropanol and acetone.) It was not necessary to isolate it. For the following reduction step, the reaction mixture was brought into solution by the addition of about 1 liter of warm ethyl alcohol. It was then hydrogenated at about 30 atm pressure in the presence of 2 g of platinum oxide. The temperature rose during this reaction to about 40°C. 

The unknown phosphate ester had the same electrophoretic mobility as 2-deoxy ribitol 5-phosphate and it seemed reasonable to expect that in the conditions used (0.1 M pyridinium acetate buffer of pH 5) 2-deoxy ribitol-4- and -5-phosphates would behave similarly therefore it was considered probable that the unknown phosphate ester is 2-deoxy ribitol 4-phosphate, resulting from the reduction of the periodate resistant 2-deoxy ribose 4-phosphate. However, the possibility that both 2-deoxy ribitol 4-phosphate and 2-deoxy erythritol 3-phosphate (formed from... 

What product would you obtain by reduction of digitoxigenin (Problem 27.39) with LiAl.H4 By oxidation with pyridinium chlorochromate ... 

All that remains before the final destination is reached is the introduction of the C-l3 oxygen and attachment of the side chain. A simple oxidation of compound 4 with pyridinium chlorochro-mate (PCC) provides the desired A-ring enone in 75 % yield via a regioselective allylic oxidation. Sodium borohydride reduction of the latter compound then leads to the desired 13a-hydroxy compound 2 (83% yield). Sequential treatment of 2 with sodium bis(trimethylsilyl)amide and /(-lactam 3 according to the Ojima-Holton method36 provides taxol bis(triethylsilyl ether) (86 % yield, based on 89% conversion) from which taxol (1) can be liberated, in 80 % yield, by exposure to HF pyridine in THF at room temperature. Thus the total synthesis of (-)-taxol (1) was accomplished. 

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