2-Chloro-3- pyridine, reaction with

The reaction of the three chloro pyridines 244 with lithium in the presence of a catalytic amount of naphthalene (4%) and different electrophiles in THF at —78°C gave, after hydrolysis, the expected functionalized pyridines 245 (Scheme 82) . 

Picolinafen is built on the partial hydrolysis of 2-chloro-6-trichlormethyl-pyridine, reaction with 4-fluoroaniline and subsequent nucleophilic substitution with 3-hydroxybenzotrifluoride [79]. 

Carbon tetrachloride was also found to react with pyrryl potassium to give 3-chloropyridine, however the mechanism is obscure and would justify further investigation. In a preparatively useful reaction, pyrrole and chloroform in the vapor phase at 500-550° gave 3-chloro-pyridine (33%) and a little 2-chloropyridine (2-5%). No interconversion of the isomers occurred under these conditions, though pyrolytic rearrangement of N-alkylpyrrole to 3-substituted pyridines is considered to involve 2-alkylpyrroles as intermediates. There is some independent evidence that dichlorocarbene is formed in the vapor phase decomposition of chloroform. ... 

A similar kinetic effect was reported for the reaction of 4-chloro-pyridine 1-oxide with methoxide ion at 50°, and still larger effects were obtained with the 2- and 3-isomers at the same temperature. ... 

The order NO2 > Cl, which is known for the reactions of nitro-activated aromatic compounds, is also found for pyridine and quinoline derivatives. In the reaction of 2-chloro-4-nitroquinoline with methoxide ion, only the 4-methoxide derivative is formed, as shown by gas-chromatography, whereas 2,4-dichloroquinoline yields a mixture of the isomeric chloro-methoxy derivatives in comparable amounts. ... 

The indirect deactivation in 2-amino-4-chloroquinoline (187) requires vigorous conditions (potassium hydroxide in hot ethylene glycol, or boiling propanolic propoxide for 16 hr) to displace the chloro group, which is stable to aqueous alkali and to hydriodic acid. The direct deactivation in 5-amino-2-chloro-3-cyano-6-methyl-pyridine (188) prevents reaction with alkoxide ion under conditions which produce smooth reaction of the des-amino analog. 

Relative reactivity wiU vary with the temperature chosen for comparison unless the temperature coefficients are identical. For example, the rate ratio of ethoxy-dechlorination of 4-chloro- vs. 2-chloro-pyridine is 2.9 at the experimental temperature (120°) but is 40 at the reference temperature (20°) used for comparing the calculated values. The ratio of the rate of reaction of 2-chloro-pyridine with ethoxide ion to that of its reaction with 2-chloronitro-benzene is 35 at 90° and 90 at 20°. The activation energy determines the temperature coefficient which is the slope of the line relating the reaction rate and teniperature. Comparisons of reactivity will of course vary with temperature if the activation energies are different and the lines are not parallel. The increase in the reaction rate with temperature will be greater the higher the activation energy. 

The inferior activation in the 3- or 6eto-position is illustrated by the very large difference in reactivity in the following aminations and alkoxylations. In the reaction of 2-chloro-5-iodopyridine or 2,3-dibromopyridine (cf. 295) with boiling methanolic methoxide, only the 2-halogen is displaced as is also the case in the amination of 2-chloro-3,5-diiodopyridine and of 2,3,6-tribromopyridine. 4-Amination of 3,4-dibromo-, 2,3,4,5-tetrabromo-, and 3-bromo-4-chloro-pyridine occurred. Only 2-amination (aqueous NH3, 190°, 36 hr) occurred with 2,3-dichloropyridine (295) and only 4-ethoxyla-tion (alcoholic ethoxide, 160°, 4 hr) with 3,4-dichloropyridine. ... 

The rate of amination and of alkoxylation increases 1.5-3-fold for a 10° rise in the temperature of reaction for naphthalenes (Table X, lines 1, 2, 7 and 8), quinolines, isoquinolines, l-halo-2-nitro-naphthalenes, and diazanaphthalenes. The relation of reactivity can vary or be reversed, depending on the temperature at which rates are mathematically or experimentally compared (cf. naphthalene discussion above and Section III,A, 1). For example, the rate ratio of piperidination of 4-chloroquinazoline to that of 1-chloroisoquino-line varies 100-fold over a relatively small temperature range 10 at 20°, and 10 at 100°. The ratio of rates of ethoxylation of 2-chloro-pyridine and 3-chloroisoquinoline is 9 at 140° and 180 at 20°. Comparison of 2-chloro-with 4-chloro-quinoline gives a ratio of 2.1 at 90° and 0.97 at 20° the ratio for 4-chloro-quinoline and -cinnoline is 3200 at 60° and 7300 at 20° and piperidination of 2-chloroquinoline vs. 1-chloroisoquinoline has a rate ratio of 1.0 at 110° and 1.7 at 20°. The change in the rate ratio with temperature will depend on the difference in the heats of activation of the two reactions (Section III,A,1). 

A thioamide of isonicotinic acid has also shown tuberculostatic activity in the clinic. The additional substitution on the pyridine ring precludes its preparation from simple starting materials. Reaction of ethyl methyl ketone with ethyl oxalate leads to the ester-diketone, 12 (shown as its enol). Condensation of this with cyanoacetamide gives the substituted pyridone, 13, which contains both the ethyl and carboxyl groups in the desired position. The nitrile group is then excised by means of decarboxylative hydrolysis. Treatment of the pyridone (14) with phosphorus oxychloride converts that compound (after exposure to ethanol to take the acid chloride to the ester) to the chloro-pyridine, 15. The halogen is then removed by catalytic reduction (16). The ester at the 4 position is converted to the desired functionality by successive conversion to the amide (17), dehydration to the nitrile (18), and finally addition of hydrogen sulfide. There is thus obtained ethionamide (19)... 

An alternate scheme for preparing these compounds starts with a prefabricated pyrimidone ring. Aldol condensation of that compound (95), which contains an eneamide function, with pyridine-3-aldehyde (80), gives the product 96. Catalytic hydrogenation gives the product of 1,4 reduction. The resulting pyrimidinedione, of course exists in the usual tautomeric keto (97a) and enol (97b) forms. Reaction with phosphorus oxyxchloride leads to the chloro derivative 98. Displacement with methoxide gives 99. Reaction of this last intermediate with the furylalkylamine derivative 92 leads to the H-2 blocker lupitidine (100) [22]. 

By taking advantage of the C(2) activation, 2-allyloxy-3-iodopyridine (173) was prepared by an SNAr displacement of 2-chloro-3-iodopyridine with sodium allyloxide [137]. 2-Chloro-3-iodopyridine was prepared by orrto-lithiation of 2-chloropyridine followed by iodine quench. The intramolecular Heck reaction of allyl ether 173 under Jeffery s ligand-free conditions resulted in 3-methylfuro[2,3-6]pyridine (174). 

Deprotonation readily occurs at C-7, and the resulting anion can further react with various electrophiles. Thus, treatment with BuLi at — 78 °C followed by reaction with diiodoethane was used to prepare the 7-iodo derivatives depicted in Table 2, while the 7-chloro derivatives were prepared by lithiation with lithium diisopropylamide (LDA), followed by reaction with CCI4. The 7-formyl derivative of the parent pyrazolo[l,5- ]pyridine has been prepared in 82% yield by reaction of the BuLi-generated anion with ethyl formate <2001JME2691>. 

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