Benzyl chloride, reaction with pyridine

The key intermediate 21 is in principle accessible in any of several ways. Thus reaction of thiophenecarbox-aldehyde with amninoacetal would lead to the Schiff base 20 treatment with acid would result in formation of the fused thiophene-pyridine ring (21). Alkylation of that intermediate with benzyl chloride gives the corresponding ternary imini urn salt 23. Treatment with sodium borohydride leads to reduction of the quinolinium ring and thus formation of ticlopidine (24). ... 

Lack of selectivity in the reaction of the /3-D-glucoside derivative with one molar equivalent of benzylthiocarbonyl chloride has also been noted 40% of the 2,3-diester and 40% of the starting material were isolated.40 Similarly, unimolar benzoylation of phenyl 4,6-0-benzylidene-/3-D-glucopyranoside gave only 9% of the 3-ester, together with 47% of the 2,3-diester.41 Acylation of benzyl 4,6-0-benzylidene-/8-D-glucopyranoside with acetic anhydride-pyridine-pyridine hydrochloride yielded,42 in contrast to the reaction with the... 

The method described is adapted from the procedures of Kym 3 and Engelhardt, Latschinoff, and Malyscheff.4 Thio-benzoic acid has been prepared by the reaction of benzoyl chloride with potassium sulfide,4 hydrogen sulfide in pyridine,6 6 and magnesium bromide hydrosulfide.7 It is formed from dibenzoyl disulfide with potassium hydrosulfide,4 potassium hydroxide,4 8 and ammonia.9 It is also formed from dibenzoyl sulfide, from phenyl benzoate, and from benzoic anhydride with alcoholic potassium hydrosulfide.4 It has been obtained from dibenzoyl sulfide and hydrogen sulfide,10 carbon oxysulfide and phenyl-magnesium bromide,11 12 dibenzyl disulfide and sodium ethoxide,13 benzyl chloride and sulfur in the presence of potassium hydroxide,14 and benzylthiosulfuric acid and alkali.18 16... 

Tertiary aliphatic alcohol linkers have only occasionally been used in solid-phase organic synthesis [73], This might be because of the vigorous conditions required for their acylation. Esterification of resin-bound linker 4 with /V-Fmoc-prolinc [72,74] could not be achieved with the symmetric anhydride in the presence of DMAP (20 h), but required the use of /V-Fmoc-prolyl chloride (10-40% pyridine in DCM, 25 °C, 10-20 h [72]). A further problem with these linkers is that they can undergo elimination, a side reaction that cannot occur with benzyl or trityl linkers. Hence, for most applications in which a nucleophile-resistant linker for carboxylic acids is needed, 2-chlorotri-tyl- or 4-acyltrityl esters will probably be a better choice than ferf-alkyl esters. 

The alcohol 177 was converted to starting substrates oxazolidinone 178 by acylation followed by reduction of the azide function along with cyclization. Oxazolidinone 178 was protected with f-butylpyrocarbonate-4-(dimethylamino) pyridine (DMAP) and triethylamine, which was further subjected to reductive cleavage of the benzyl ester unit to afford carboxylic acid 179. The treatment of 179 with solution of l-chloro-/V./V,2-trimethyl-1-propenv I airline resulted in the easy formation of the corresponding acid chloride which on reaction with imine in the presence of triethylamine provided the stereoselective formation of spiro-p-lactam 180. 

Benzyl acetate was prepared by addition of benzyl chloride (containing 0.6% pyridine as stabiliser) to preformed sodium acetate at 70°, followed by heating at 115°, then finally up to 135°C to complete the reaction. On one occasion, gas began to be evolved at the end of the dehydration phase, and the reaction accelerated to a violent explosion, rupturing the 25 mm thick cast iron vessel. This was attributed to presence of insufficient pyridine to maintain basicity, dissolution of iron by the acidic mixture, and catalysis by ferric chloride of a Friedel-Craft type polycondensation reaction to polybenzyls, with evolution of hydrogen chloride, which at 130°C would produce an overpressure approaching 100 bar. Previously the chloride had been supplied in steel drums containing 10% sodium carbonate or 3% sodium hydroxide solutions as... 

The acid 350 was demethylated with pyridine hydrochloride, then realkylated with benzyl bromide in aqueous potassium hydroxide to give 351. The latter was converted to the diazoketone 352 by the sequential treatment of 351 with oxalyl chloride and etheral diazomethane. Reaction of 352 with concentrated hydrobromic acid gave the bromoketone 353. The latter was reduced with sodium borohydride at pH 8 -9 to yield a mixture of diastere-omeric bromohydrins 354. Protection of the free hydroxyl as a tetrahydro-pyranyl ether and hydrogenolysis of the benzyl residue afforded 355. The phenol 355 was heated under reflux with potassium m/V-butoxide in tert-butyl alcohol for 5 hr to give a 3 1 epimeric mixture of dienone ethers 356 and 357 in about 50% yield. Treatment of this mixture with dilute acid gave the epimeric alcohols 358 and 359. This mixture was oxidized with Jones reagent to afford the diketone 349. 

Trichloromethylarenes are found to activate the pyridine ring via N-alkylation such that 4-chloropyridines are formed (Scheme 20) <1995TL5075>. In the case of nicotinamide, the dihydropyridine intermediate 121 undergoes an intermolecular redox reaction with hydride transferred to the benzylic position to give 122. Subsequent displacement of the C-4 chloride with nicotinamide affords the bispyridinium salts 123. 

Benzyl and p-nitrobenzyl esters are usually made by classical methods such as reaction of benzyl alcohol with an acid chloride in the presence of pyridine or with a carboxylic acid in the presence of a carbodiimide (see general esterification methods). We have already shown the conversion of the cesium salt of a carboxylic acid to its benzyl ester by reaction with benzyl bromide [Scheme 6.40] ... 

TABLE 1. Polymer properties from four 50 minute anionic polymerization reactions using n-hexyl isocyante in THE with sodium A-phenyl benzyl amine as initiator and then quenching for 10 minntes using methacryloyl chloride dissolved in pyridine. 

Fig. 37 More O Ferrall-Jencks diagram for the Menschutkin reactions of 1-phenylethy] and benzyl chlorides with pyridine. The structures of transition states were optimized by ab initio MO calculation (RHF/b-Sf G ). O, substituted 1-phenylethyl chlorides with pyridine , benzyl chlorides with pyrindine , with 4-nitropyridine O, methyl and A, ethyl chlorides with pyridine (Fujio et al, unpublished).

The present theories of the effects of solvents on the rates of polar (ionic) reactions do not permit a quantitative analysis of the above cited results. Fractions of AHp and ASp, due to solvation, apparently compensate each other, because the increase in the energy needed for desolvation is just compensated by equal contributions of the entropy (a more firmly bound or larger number of molecules are desol-vated). This compensation phenomenon is well known in organic chemistry. For instance, the difference between the activation enthalpies (AAH ) of the reaction of benzyl chloride with pyridine in DMF and CH3OH is equal to -5.3 kcal mole". ... 

The reaction of tetra- -butylammonium salt of the zinc complex 418 with electrophilic reagents such as methyl iodide, 3-bromopropionitrile, or benzyl chloride in the presence of pyridine hydrochloride as well as 3-chloromethyl-pyridine hydrochloride and 4-chloromethylpyridine hydrochloride led to formation of the difficultly accessible thiones 419 and 420 (Scheme 58) <20010L1941>. 

Both benzyl bromide and benzyl chloride have been successfully employed in the reaction with the sodium derivatives. A tertiary base, often pyridine, is added at the end of the reaction to remove unreacted benzyl halide by quarternary salt formation. 

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