Pyridinium chlorochromate, reaction with alcohols

The C2-symmetric epoxide 23 (Scheme 7) reacts smoothly with carbon nucleophiles. For example, treatment of 23 with lithium dimethylcuprate proceeds with inversion of configuration, resulting in the formation of alcohol 28. An important consequence of the C2 symmetry of 23 is that the attack of the organometallic reagent upon either one of the two epoxide carbons produces the same product. After simultaneous hydrogenolysis of the two benzyl ethers in 28, protection of the 1,2-diol as an acetonide ring can be easily achieved by the use of 2,2-dimethoxypropane and camphor-sulfonic acid (CSA). It is necessary to briefly expose the crude product from the latter reaction to methanol and CSA so that the mixed acyclic ketal can be cleaved (see 29—>30). Oxidation of alcohol 30 with pyridinium chlorochromate (PCC) provides alde-... 

Furfuryl alcohol is oxidized directly to 2,3-dideoxy-DL-pent-2-eno-pyranosid-4-nlose (325, R = H) by treatment with m-chloroperoxy-benzoie acid.236 A variety of substituted furfuryl alcohols have thus been converted into over 60 enediulose derivatives (345) in connection with studies of their antimicrobial activity.211 It was later found that pyridinium chlorochromate may be applied in this reaction, instead of a peroxy acid.237... 

Alcohols are the most important precursors in the synthesis of carbonyl compounds, being readily available. More complex alcohols are prepared by reaction of Grignard reagents with simpler carbonyl compounds. Ordinarily MnO and Cx OY in acid are used to oxidize 2° RjCHOH to RjCO. However, to oxidize 1° RCHjOH to RCHO without allowing the ready oxidation of RCHO to RCOOH, requires special reagents. These include (a) pyridinium chlorochromate (pcc),... 

Popular oxidation reactions of peptide alcohols such as the Parikh-Doering or Dess-Martin in addition to older oxidation reactions such as Collins, pyridinium chlorochromate, or Swern oxidation afford racemization free productsJ9121415 37-39 Oxidations using pyridinium dichromate results in racemization and low yields of product.[l3 Oxidation reactions have also been utilized in semisynthetic pathways of peptide aldehydes (1) peptide aldehydes are obtained through the enzymatic acylation of a peptide ester to an amino alcohol with subsequent oxidation of the peptide alcohol to afford the aldehyde, and (2) peptide aldehydes can also be obtained by direct enzymatic oxidation of the peptide alcohol by alcohol de-hydrogenaseJ40 41 ... 

The oxidation of primary alcohols to aldehydes also suffers from the problem of overoxidation of the aldehyde to a carboxylic acid. Mild methods capable of stopping die oxidation at the aldehyde oxidation level are required if aldehydes are to be obtained. The most common and effective reagent for this purpose is pyridinium chlorochromate (PCC), produced by the reaction of pyridinium hydrochloride with chromium trioxide. This reagent is soluble in dichloromethane and smoothly oxidizes primary alcohols to aldehydes in high yields. Because of die mild, neutral reaction conditions and the use of stoichiomettic amounts of oxidant, the aldehyde product is not oxidized further. 

This method is of value when the alcohol is readily available from natural sources, or when it can be prepared, for example, by the reaction of an alkenyl-organometallic reagent with an aldehyde. An example of the former is the oxidation of the terpenoid alcohol carveol to carvone (Expt 5.88) using pyridinium chlorochromate-on-alumina reagent. 

Although in principle naturally occurring (—)-galanthamine could have been prepared by an identical sequence of reactions commencing with D-tyrosine, an alternate route to 319, the enantiomer of 314, was developed. Thus, epimeriza-tion of the methyl ester group at C-6 of the A -trifluoroacetamide derived from 315 followed by oxidation of the allylic alcohol with pyridinium chlorochromate furnished 319 in 78% optical purity, albeit in low chemical yield. Since 319 could be converted to (-)-galanthamine (291) by the same sequence of reactions outlined for the transformation of 314 to (+)-galanthamine, its preparation may be considered to represent a formal total synthesis of 291 from L-tyrosine (163). 

Oxidation of several primary aliphatic alcohols with potassium dichromate, pyri-dinium dichromate, quinolinium dichromate (QDC), imidazolium dichromate, nico-tinium dichromate, isonicotinium dichromate, pyridinium fluorochromate (PFC), quinolinium fluorochromate, imidazolium fluorochromate, pyridinium chlorochromate (PCC), quinolinium chlorochromate (QCC), and pyridinium bromochromate (PBC), in aqueous acetic acid and in the presence of perchloric acid, showed similar kinetics. The values of the reaction constants did not differ significantly, indicating operation of a common mechanism.1... 

The reducing power of diborane has been blunted by forming its adduct with dimethyl sulfide. This adduct, Me2S BH3, is stable and commercially available and therefore more attractive as a hydride reagent than diborane itselfNevertheless, the adduct still reduces carboxylic acids to alcohols which are isolated as cyclic boroxins (2 Scheme 1). In a one-pot reaction, carboxylic acids can be reduced to boroxins and then oxidized with pyridinium chlorochromate to the required aldehyde (Scheme I)."... 

We protect one hydroxyl terminus of the commercially available 1,8-octane diol 1 by reaction with dihydropyran to give the monoalcohol, 8-tetrahydropyranyloxyoctanol 2. The protected alcohol 2 is oxidized to the aldehyde with pyridinium chlorochromate to give 8-tetrahydropyranyl-oxyoctanal 3. 1-Heptyne 4 is coupled with propargyl bromide 5 in a copper catalyzed reaction to produce the diacetylenic 1,4-decadiyne 6. 

Reactions, which are seemingly 1,3-sigmatropic rearrangements, have been carried out with various substrates. Cyclopropyl vinyl alcohols have been converted to 3-cyclopropylprop-2-enyl derivatives by treatment with acetic acid, ° pyridinium chlorochromate, thionyl chloride,benzenethiol, and diethylaminosulfur trifluoride, e.g. reaction of 3 with thionyl chloride to give Double bond migration has also been mediated by treatment... 

Reaction of the C-0 and O-H Bonds Primary alcohols oxidize to carboxylic acids secondary alcohols oxidize to ketones with chromium trioxide or sodium dichromate. Tertiary alcohols do not oxidize under mild conditions. With pyridinium chlorochromate (PCC) the oxidation of primary alcohols can be stopped at aldehydes. 

A quantitative 1,4-chirality transfer is observed in the construction of the acyclic segment C-l to C-ll 11 of the antibiotic ionophore A-23187 (12, calcimycin)441. Both the wanted and unwanted stereoisomer 9 and 10, obtained from the alcohol 8 by pyridinium chlorochromate oxidation followed by Grignard reaction with vinylmagnesium bromide, can be rearranged by the ester enolate procedure simply by changing the reaction conditions to give the stereoisomer 11 with the correct configuration at C-10. 

Reaction of estrone methyl ether with 2,2-dimethylpropane-l, 3-diol in the presence of a catalytic amount of acid leads to derivative 26-1, in which the ketone at 17 is protected as an acetal (Scheme 3.26). Treatment of this intermediate with pyridinium chlorochromate leads to oxidation of the Cg benzylic carbon atom to a carbonyl group (26-2). Potassium tert-butoxide abstracts a proton from the adjacent methylene at C7 alkylation of the resulting anion with 4-(A, A -dimethyl)butyl iodide gives 26-3 as a mixture of diastereomers. The carbonyl group is next reduced to an alcohol by means of sodium borohydride (26-4). Dehydration of the newly introduced hydroxyl group is arguably facilitated by the adjacent aromatic ring (26-5). Aqueous acid removes the 17-acetal to afford 26-6, which is in essence an equilinin derivative. 

The reported synthesis for (5Z,9Z)-14-methylpentadeca-5,9-dienoic acid (14) started with commercially available 4-methylpentan-l-ol, which upon reaction with phosphorous tribromide afforded l-bromo-4-methylpentane [52], Commercially available pent-4-yn-l-ol was also protected as the tetrahydropyranyl ether as shown in Fig. (18). Formation of the lithium acetylide with n-BuLi in THF and subsequent addition of 1-bromo-4-methylpentane in hexamethylphosphoric acid triamide resulted in the isolation of the tetrahydropyranyl protected 9-methyldec-4-yn-l-ol. Hydrogenation of the alkyne with Lindlar s catalyst and quinoline in dry hexane afforded the cis hydropyranyl-protected 9-methyldec-4-en-l-ol. Deprotection of the alcohol with />-toluenesulfonic acid afforded (Z)-9-methyldec-4-en-l-ol. Pyridinium chlorochromate oxidation of the alcohol resulted in the isolation of the labile (Z)-9-methyldec-4-enal. Final Wittig reaction with (4-carboxybutyl) triphenylphosphonium bromide in THF/DMSO resulted in the desired (5Z,9Z)-14-methylpentadeca-5,9-dienoic acid (14). 

---