2,6-pyridine dialdehyde

Pyridine derivatives with additional donor functions and sterically demanding substituents have been used with the intention of producing complexes of Cd (and of other metals) with low coordination number one of these ligands is the tridentate, planar-bonding 2,6-bis[(2,6-dimethyl-phenylimino)methyl] pyridine (pydim a Schiff base derived from 2,6-pyridine dialdehyde), which with Cd(BF4)2 and thiocyanate gives a dinuclear complex [(pydim)Cd(/x-NCS-S,N)]2(BF4)2 with N-dominated coordination sphere.191 As centrosymmetric Plijc, Z= 2), the complex has an antiparallel /x-1,3 NCS double bridge with Cd—N and Cd—S bonds (224.6 pm and 255.5 pm, respectively) the Cd—N(py) bond is clearly shorter than the Cd—N(imino) bonds (225.6 pm and 245.0 pm,... 

Figure 7.13 The reaction of a pyridine dialdehyde with several diamines forms a dynamic combinatorial library. From this library, several diimine macrocycles can be obtained in good yield when template ions (symbolized by polygons) of proper size are added. Magnesium ions give a ring size of 15, calcium ions one of 18, and barium ions stabilize the 21-membered rin ...

A head to head double calix[4]arene system linked at the 1 -distal upper rim positions of tetrapropyloxy calix[4]arene with 2,6-diamino-pyridine groups was obtained by condensation of l,3-diaminocalix[4]-arene with pyridine dialdehyde and showed binding abihty toward viologen type guest molecules (2002T9019). 

Finally, dynamic combinatorial chemistry (DCC) opens new perspectives for templated syntheses. Early work was accomplished by the late M. Nelson, who studied in detail the condensations between diamines and 2.6-diacetyl-pyridine in the presence of various metal cations. To conclude, he found that the macrocyciic compounds formed depend on the overall proportions of the reactants and the type of cation used as the template. Related studies were accomplished using pyridine dialdehyde and several diamines (Fig. 22). ... 

The Kixnig reaction (Fig. 5) has been used to determine the amount of nicotinic acid and niacinamide. In this procedure, quatemization of the pyridine nucleus by cyanogen bromide is followed by ring opening to generate the putative dialdehyde intermediate. Reaction of this compound with an appropriate base, such as p-rr ethyl am in oph en o1 sulfate (47) or sulfanilic acid (48), generates a dye. The concentration of this dye is deterrnined c olo rime trie ally. 

Dimethylquinoxaline reacts with pyridine and iodine to form quinoxaline-2,3-bis(methylenepyridinium iodide) (55). Condensation of (55) with p-nitrosodimethylaniline in the presence of potassium carbonate yields the bis-(p-dimethylaminonitrone) (56) and this on acid hydrolysis gives quinoxaline 2,3-dialdehyde (57) in high over-all yield. The dialdehyde is also obtained by selenium dioxide oxidation of 2,3-dimethylquinoxaline. ... 

The transformation of isoquinoline has been studied both under photochemical conditions with hydrogen peroxide, and in the dark with hydroxyl radicals (Beitz et al. 1998). The former resulted in fission of the pyridine ring with the formation of phthalic dialdehyde and phthalimide, whereas the major product from the latter reaction involved oxidation of the benzene ring with formation of the isoquinoline-5,8-quinone and a hydroxylated quinone. 

Biological. Heukelekian and Rand (1955) reported a 5-d BOD value of 1.31 g/g which is 58.7% of the ThOD value of 2.23 g/g. A Nocardia sp. isolated from soil was capable of transforming pyridine, in the presence of semicarbazide, into an intermediate product identified as succinic acid semialdehyde (Shukla and Kaul, 1986). 1,4-Dihydropyridine, glutaric dialdehyde, glutaric acid semialdehyde, and glutaric acid were identified as intermediate products when pyridine was degraded by Nocardiastiain Z1 (Watson and Cain, 1975). 

The titanium-mediated photocatalytic oxidation of a pyridine solution was conducted by Low et al. (1991). They proposed that the reaction of OH radicals with pyridine was initiated by the addition of a OH radical forming the 3-hydro-3-hydroxypyridine radical followed by rapid addition of oxygen forming 2,3-dihydro-2-peroxy-3-hydroxypyridine radical. This was followed by the opening of the ring to give At-(formylimino)-2-butenal which decomposes to a dialdehyde and formamide. The dialdehyde is oxidized by OH radicals yielding carbon dioxide and water. Formamide is unstable in water and decomposes to ammonia and formic acid. Final products also included ammonium, carbonate, and nitrate ions. 

A large number of concave pyridines 3 have been synthesized starting from pyridine-2,6-dicarbaldehydes 4, heteroatom containing a,o>-diamines 5 and diacyl dichlorides 8 (Scheme 1). In the first macrocyclization, the dialdehyde 4 and the diamine 5 were condensed in the presence of an alkaline earth metal ion to give a complex of a macrocyclic diimine 6 which was then reduced to the macrocyclic diamine 7. The yields of this reaction are excellent ( > 90%) when the size of the metal ion is adjusted to the size of the macrocycle formed. Mg was used for the formation of 15-membered, Ca for 18-membered and Sr for 21-membered rings. The macrocyclic diamines 7 were oils which could be purified in some cases. However, for the synthesis of the concave pyridines 3 the purity of the crude diamines 7 was sufficient. 

The synthetic strategy used for the construction of concave pyridine bislactams 3 (Scheme 1) can also be applied to other concave bases. When instead of a pyridine-2,6-dialdehyde 4, l,10-phenanthroline-2,9-dicarbaldehyde (9) was used in a metal ion template directed synthesis of macrocyclic diimines, after reduction, also macrocyclic 1,10-phenanthroline diamines 10 could be obtained in good yields. Here too, the crude diamines 10 were used in the next reaction step. Bridging of 10 with diacyl dichlorides 8 gave concave 1,10-phenanthroline bislactams 11. Scheme 2 summarizes the synthesis and lists the synthesized bimacrocycles 11 [18]. 

Pyridines are more susceptible to reduction than benzenes. Sodium in ethanol or in liquid ammonia evidently reduces pyridine to 1,4-dihydropyridine (or a tautomer) because hydrolysis of the reaction mixture affords glutaric dialdehyde (318 — 317 — 316). Reduction of pyridines with sodium and ethanol can proceed past the dihydro stages to A3-tetrahydropyridines and piperidines (318 — 319 and 320). 

The most common procedure is ozonolysis at -78 °C (P.S. Bailey, 1978) in methanol or methylene chloride in the presence of dimethyl sulfide or pyridine, which reduce the intermediate ozonides to aldehydes. Unsubstituted cydohexene derivatives give 1,6-dialdehydes, enol ethers or esters yield carboxylic acid derivatives. Oxygen-substituted C—C bonds in cyclohexene derivatives, which may also be obtained by Birch reduction of alkoxyarenes (see p. 103f.), are often more rapidly oxidized than non-substituted bonds (E.J. Corey, 1968 D G. Stork, 1968 A,B). Catechol derivatives may also be directly cleaved to afford conjugated hexa-dienedioic acid derivatives (R.B. Woodward, 1963). Highly regioselective cleavage of the more electron-rich double bond is achieved in the ozonization of dienes (W. KnOll, 1975). 

Pyridyl alkanol [41], diol [42], and ferrocenyl alcohol [43] were the first asymmetric autocatalysts found by Soai and co-workers in the enantioselective alkylation of pyridine-3-carbaldehyde, dialdehyde, and ferrocenecarbaldehyde, respectively, with dialkylzincs. 

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