Pyridines, conjugated

An unusual Sonogashira coupling between an alkynyl bromide and a 4-ethynylpyridine 142 was reported to produce a new complexing agent 143 containing a highly-conjugated pyridine subunit [116]. In addition, alkynylpyridines, as important intermediates in medicinal chemistry,... 

The abnormal metallation is also favored when the conjugated pyridine-imid-azolylidene precursor (with a smaller bite angle) is used. For these precursors, an abnormal binding is produced even with a small wingtip group, as shown in Scheme 3.12. Under the same conditions, the pyridine-benzimidazolium analogue afforded the C2 carbene complex (Scheme 3.12) [27]. 

Preparation of Polyaromatic Ether Containing a Conjugated Pyridine... 

Han FS, Higuchi M, Kurth DG (2008) Synthesis of Jt-conjugated pyridine ring functionalized bis-terpyiidines with efficient green, blue and purple emission. Tetraherdon 64 9108-9116. doi 10.1016/j.tet.2008.06.106... 

The 2-nitration of 3-hydroxy- and 3-methoxy-pyridine in 85-96% sulphuric acid involves the conjugate acids, whilst the 3-nitration of 6-hydroxy and 6-methoxy-2-pyridone in 70-77 % sulphuric acid involves the free bases, which react at, or near to the encounter rate. ... 

The pyridine-like nitrogen of the 2H-pyrrol-2-yiidene unit tends to withdraw electrons from the conjugated system and deactivates it in reactions with electrophiles. The add-catalyzed condensations described above for pyrroles and dipyrromethanes therefore do not occur with dipyrromethenes. Vilsmeier formylation, for example, is only successful with pyrroles and dipyrromethanes but not with dipyrromethenes. 

The oxidative coupling of toluene using Pd(OAc)2 via />-tolylmercury(II) acetate (428) forms bitolyl[384]. The aryl-aryl coupling proceeds with copper and a catalytic amount of PdCl2 in pyridine[385]. Conjugated dienes are obtained by the coupling of alkenylmercury(II) chlorides[386]. 

The protonation of the nitrogen atom of thiazole induces a large increase in reactivity of the 2-position (193, 194). This is in contrast to the pyridine series, where the reactivity of both positions adjacent to the nitrogen atom are enhanced (194). The phenylation of conjugate acid of 5-alkylthiazoles may then be considered as a preparative route to alkyl-thiazoles. The results (isomer percent and overall reactivity) are indicated in Tables III-31 (196) and 01-32 (196). 

The stronger base is derived from the weaker conjugate acid Therefore add a proton to ammonia to give its conjugate acid (ammonium ion) and a proton to pyridine to give its conjugate acid (pyridimum ion) then look up the values for each... 

Interesting structures can be formed by combinations of ring and side-chain substituents in special relative orientations. As indicated above, structures (28) contain the elements of azomethine or carbonyl ylides, which are 1,3-dipoles. Charge-separated species formed by attachment of an anionic group to an azonia-nitrogen also are 1,3-dipoles pyridine 1-oxide (32) is perhaps the simplest example of these the ylide (33) is another. More complex combinations lead to 1,4-dipoles , for instance the pyrimidine derivative (34), and the cross-conjugated ylide (35). Compounds of this type have been reviewed by Ramsden (80AHCl26)l). 

Substituents cannot directly conjugate with /3-pyridine-like nitrogen atoms. Azole substituents which are not a or y to a pyridine-like nitrogen react as they would on a benzene ring. Conjugation with an a-pyridine-like nitrogen is much more effective across a formal double bond thus the 5-methyl group in 3,5-dimethyl-l,2,4-oxadiazole (323) is by far the more reactive. 

The data discussed above can be summarized as follows NaBH4 is more prone to saturate conjugated double bonds than LiAlH4 the double bond in a l-en-3-one steroid is especially sensitive use of pyridine as a solvent favors formation of the saturated alcohol use of methanol with NaBH4, Na(OCH3)3BH in tetrahydrofuran, Li[OC(CH3)3]3AIH and aluminum hydride favor formation of the allylic alcohol. 

Until recently, pyridine-type bases have been commonly used to produce conjugated enones from 2-halo ketones yields are usually poor °° and these reactions are frequently accompanied by rearrangement, reduction and salt formation. Thus, Warnhoff found that dehydrobromination of (28) with 2,4-lutidine gave a mixture of (29), (30) and (31) in the ratio 55 25 20. Collidine gave a ratio of 38 25 37, whereas pyridine gave mainly the salt (32). 

The striking effect of the catalyst is exemplified by the reaction of pregna-4, 16-diene-3,20-dione (10) with benzyl mercaptan. In the presence of piperidine only conjugate addition occurs to give (11) whereas with pyridine hydrochloride only the 3-benzyl thioenol ether (12) is formed. In the presence of p-toluenesulphonic acid both reactions take place to yield (13). 

Selective hydroxylation with osmium tetroxide (one equivalent in ether-pyridine at 0 ) converts (27) to a solid mixture of stereoisomeric diols (28a) which can be converted to the corresponding secondary monotoluene-sulfonate (28b) by treatment with /7-toluenesulfonyl chloride in methylene dichloride-pyridine and then by pinacol rearrangement in tetrahydrofuran-lithium perchlorate -calcium carbonate into the unconjugated cyclohepte-none (29) in 41-48 % over-all yield from (27). Mild acid-catalyzed hydrolysis of the ketal-ketone (29) removes the ketal more drastic conditions by heating at 100° in 2 hydrochloric acid for 24 hr gives the conjugated diketone (30). 

These rate constants are for the hydrolysis of cinnamic anhydride in carbonate buffer, pH 8.45, total buffer concentration 0.024 M, in the presence of the catalysts pyridine, A -methylimidazole (NMIM), or 4-dimethylaminopyridine (DMAP). In the absence of added catalyst, but the presence of buffer, the rate constant was 0.005 24 s . You may assume that only the conjugate base form of each catalyst is catalytically effective. Calculate the catalytic rate constant for the three catalysts. What is the catalytic power of NMIM and of DMAP relative to pyridine ... 

CaveU and Chapman made the interesting observation that a difference exists between the orbital involved in the quatemization of aromatic nitrogen heterocycles and aromatic amines, which appears not to have been considered by later workers. The lone pair which exists in an sp orbital of the aniline nitrogen must conjugate, as shown by so many properties, with the aromatic ring and on protonation or quatemization sp hybridization occurs with a presumed loss of mesomerism, whereas in pyridine the nitrogen atom remains sp hybridized in the base whether it is protonated or quaternized. Similarly, in a saturated compound, the nitrogen atom is sp hybridized in the base and salt forms. 

It is interesting to speculate why the basicities of the substituted pyridines are well correlated by normal a-values, rather than by a+-values. Writing the resonance structures for the conjugate acid (5<->6)... 

The methods outlined, of course, are readily applicable to a wide variety of substituted heterocycles like the carboxyl, hydroxy and mercapto derivatives of pyridines, pyridine 1-oxides, pyrroles, etc. The application to amines and to diaza compounds such as pyrimidine, where the two centers are basic, is obvious except that now 23 takes the role of the neutral compound, 21 and 22 the roles of the tautomeric first conjugate bases, and 20 the role of the second conjugate base. Extensions to molecules with more than two acidic or basic centers, such as aminonicotinic acid, pyrimidinecarboxylic acids, etc., are obvious although they tend to become algebraically cumbersome, involving (for three centers) three measurable Kg s, four Ay s, and fifteen ideal dissociation constants (A ), a total of twenty-two constants of which seven are independent. 

---