Pyridine diacid

However, preorganization by reversible interactions via hydrogen bonds does not necessarily need a further template such as an anion. Direct intermolecular hydrogen bonds between derivatives of isophthalic acid and 2,6-pyridine diacid were used to synthesize a series of new catenanes [17,18], rotaxanes [18c,19], and trefoil knots [20]. The interaction of dibenzylammonium cations and dibenzo[24]crown[8] [21] led to the preparation of rotaxanes by the attachment of stoppers to the thread ends (Scheme 5.5) [22], or similarly by clipping of the crown ether chain wrapped around the ammonium dumbbell [23]. Recently, several novel catenanes were synthesized via the macrocydic connection of three ammonium cations threaded through three crown ether rings attached to a triptycene core [24]. 

Due to the large affect chemistry has on the properties of PBI membranes, Xiao et al. [22] investigated the properties of PBI membranes that contained a pyridine moiety in the repeat unit rather than a phenyl moiety. Four different PBI homopolymers were synthesized that contained pyridine moieties in the repeat unit. These homopolymers were synthesized by reacting TAB with a pyridine diacid, (3,5-, 2,4-, 2,5-, and 2,6-pyridine dicarboxylic acid). Figure 10.12 shows the repeat unit of each of the four pyridine PBIs. 2,5-Pyridine PBI differs from the other three chemistries in that it is the... 

Methyl Ester of 2,5-Pvridine Dicarboxvlic Acid 2,5-Pyridine diacid chloride (50 g.) was added slowly to 600 ml. of methanol with stirring. The solution was warmed on a steam bath for 4 hours and then allowed to stand overnight without heating. A white crystalline product formed. The alcohol was reduced to half volume by evaporation and the product collected and dried m.p. 161-162°. 

Solution reactions between diacid chlorides and diols or diphenols are carried out in THF or CH2C12 at —10 to 30°C in die presence of tertiary amines such as triethylamine or pyridine, which play a role of both reaction catalyst and HC1 acceptor (Scheme 2.26). This synthetic mediod is also termed acceptor-catalytic polyesterification.295-297 High-temperature solution reactions have also been reported for a number of less soluble, generally semicrystalline, aromatic polyesters.6 They yield high-molar-mass polyesters exhibiting good mechanical properties and thermal stability. 

This method involves the direct polycondensation of aromatic diamines with aromatic diacids in the presence of an aryl phosphite (triphenyl phosphite) and an organic base like pyridine.7,9 70 71 The addition of salts improves die solubility of the polymer and, with this, the maximum attainable molecular weight.71 The concentrations are, however, lower than by the dichloride method. 

The rate of polymer erosion in the presence of incorporated anhydride and release of an incorporated drug depends on the pK of the diacid formed by hydrolysis of the anhydride and its concentration in the matrix (20). This dependence is shown in Fig. 7 for 2,3-pyridine dicarboxylic anhydride and for phthaUc anhydride. In this study, methylene blue was used as a marker. The methylene blue release rate depends both on the pK and on the concentration of diacid hydrolysis product in the matrix. However, at anhydride concentrations greater than 2 wt%, the erosion rate reaches a limiting value and further increases in anhydride concentration have no effect on the rate of polymer hydrolysis. Presumably at that point Vj, the rate of water intrusion into the matrix, becomes rate limiting. 

Decarboxylative condensations of this type are sometimes carried out in pyridine, which cannot form an imine intermediate, but has been shown to catalyze the decarboxylation of arylidene malonic acids.215 The decarboxylation occurs by concerted decomposition of the adduct of pyridine to the a, 3-unsaturated diacid. 

Shown in Figure 6-A are EELS spectra of the entire series of pyridine carboxylic acids and diacids adsorbed at Pt(lll) from acidic solutions at negative electrode potential. Under these conditions all of the meta and para pyridine carboxylic acids and diacids exhibit prominent 0-H vibrations (OH/CH peak ratio near unity). In contrast, at positive potentials only the para-carboxylic acids display pronounced 0-H vibrations, Figure 6-B. All of the 0-H vibrations are absent under alkaline conditions, Figure 6-C. This situation is illustrated by the reactions of adsorbed 3,4-pyridine dicarboxylic acid ... 

Table 9.5. Anodic decarboxylation of vic-diacids to form alkenes in pyridine, water containing triethylamine.

Reaction of 1,2 -dicarboxylic acids has been used for the formation of a number of strained alkenes and also applied to the Diels-Alder addition products from maleic anhydride (Table 9.5). Both cis- and tr s-diacids take part in the process. Aqueous pyridine containing, triethylamine as a strong base, is considered the best solvent and higher yields are obtained at temperatures of around 80 "C [130]. Use of a divided cell avoids a possibility of electrocatalytic hydrogenation of the product at the cathode. The addition of /a/-butylhydroquinone as a radical scavenger prevents polymerization of the product [127], An alternative chemical decarboxylation process is available which uses lead tetraacetate [131] but problems can arise because of reaction between the alkene and lead tetraacetate. 

Numerous condensation polymers such as polyamides (75MI11103) containing the pyridine nucleus in the backbone have been prepared from the corresponding pyridine diesters or diacid chlorides. The Knoevenagel condensation (Scheme 32) has provided another way of incorporating the pyridine nucleus into a condensation framework. Poly(styrylpyridines) (116) have been found to exhibit exceptional flame resistance and are useful in reinforced composites (79USP4163740). 

Quinolinic acid (133) was prepared by methods similar to those described for the monocarboxylic acids.182,183,189-191,196-202 In many cases the resulting diacid was decarboxylated to nicotinic acid (126). Quinoline (130) was simultaneously oxidized to the diacid (133) and reduced to tetrahy-droquinoline (134) in one of the rare reports of paired synthesis of pyridine compounds (Scheme 44).189 An attempt was made to delineate some of the electrode processes for the diacid (133).200... 

Compound 85 was dehydrogenated at 300° over palladium black under reduced pressure to a pyridine derivative 96 which was independently synthesized by the following route. Anisaldehyde (86) was treated with iodine monochloride in acetic acid to give the 3-iodo derivative 87. The Ullmann reaction of 87 in the presence of copper bronze afforded biphenyldialdehyde (88). The Knoevenagel condensation with malonic acid yielded the unsaturated diacid 91. The methyl ester (92) was also prepared alternatively by a condensation of 3-iodoanisaldehyde with malonic acid to give the iodo-cinnamic acid (89), followed by the Ullmann reaction of its methyl ester (90). The cinnamic diester was catalytically hydrogenated and reduced with lithium aluminium hydride to the diol 94. Reaction with phosphoryl chloride afforded an amorphous dichloro derivative (95) which was condensed with 2,6-lutidine in liquid ammonia in the presence of potassium amide to yield pyridine the derivative 96 in 27% yield (53). 

Oxidation of the iV-alkoxycarbonyl-2-azabicyclo[2.2.0]hex-5-ene 158 with ruthenium tetroxide followed by esterification with diazomethane affords the cis-2,3-diester of azetidine 159 (R = Me) in 67% overall yield. The N-protecting group can be easily removed from the diacid by acidic hydrolysis to give acidic amino acid 160 in 85% yield. Strangely, the 2,3-diester 159 (R = Me) upon acidic hydrolysis failed to give any of the amino acid. This approach to azetidines is useful because 158 is readily available from pyridine in three steps <2003CPB96>. 

Pyridine-2,3-dicarboxylic acids containing a halogen in the 5- or 6-position were prepared by oxidation of the corresponding quinolines using either ozone/H202 or catalytic R.UO4. Diacids substituted in the 6-position by Cl or Br, or in the 5-position by F, Cl, or Br, respectively, were isolated in 46-71% yields. The yields of 6-fluoro and 6- or 5-iodo diacids were low (<30%) (Equation 40) <2001S2495>. 

The reaction of compound (86) with hydroxylammonium chloride in acetic anhydride in the presence of pyridine gave the corresponding cyano-substituted compound (252). Alkaline hydrolysis of compound (252) gave the diacid (253), and reaction with sodium azide and ammonium chloride in DMF led to the tetrazole (254). The compounds (8i), (82), (84), (85), and (87) reacted similarly <93CCC2139, 94MI 701-01). 

A similar procedure was used with co-dicarboxy-PMMA macromonomers 105). They were mixed with another diacid (sebacic acid) and reacted stoichiometrically with a diamine (p,p -diaminodiphenylmethane and others) at 100 °C in N-methyl-pyrrolidone/pyridine mixtures. The formed polyamide was shown to contain PMMA grafts although the proportion of MMA was slightly lower than in the feed. 

Polymeric 1,3,4-oxadiazoles can be prepared by the action of diacid chlorides on bistetrazoles.105 The products, obtained after several days heating of the reactants in pyridine, have a low degree of polymerization but high thermal stability. 

---