Hydrolysis hydrazone

The imides, primaiy and secondary nitro compounds, oximes and sulphon amides of Solubility Group III are weakly acidic nitrogen compounds they cannot be titrated satisfactorily with a standard alkaU nor do they exhibit the reactions characteristic of phenols. The neutral nitrogen compounds of Solubility Group VII include tertiary nitro compounds amides (simple and substituted) derivatives of aldehydes and ketones (hydrazones, semlcarb-azones, ete.) nitriles nitroso, azo, hydrazo and other Intermediate reduction products of aromatic nitro compounds. All the above nitrogen compounds, and also the sulphonamides of Solubility Group VII, respond, with few exceptions, to the same classification reactions (reduction and hydrolysis) and hence will be considered together. 

Noncatalytic Reactions Chemical kinetic methods are not as common for the quantitative analysis of analytes in noncatalytic reactions. Because they lack the enhancement of reaction rate obtained when using a catalyst, noncatalytic methods generally are not used for the determination of analytes at low concentrations. Noncatalytic methods for analyzing inorganic analytes are usually based on a com-plexation reaction. One example was outlined in Example 13.4, in which the concentration of aluminum in serum was determined by the initial rate of formation of its complex with 2-hydroxy-1-naphthaldehyde p-methoxybenzoyl-hydrazone. ° The greatest number of noncatalytic methods, however, are for the quantitative analysis of organic analytes. For example, the insecticide methyl parathion has been determined by measuring its rate of hydrolysis in alkaline solutions. 

Pyrimido[4,5- f]pyrimidines may be used as pyrimidine precursors. Thus, the dihydro derivative (736) undergoes alkaline hydrolysis to the amide (737 R = PrCO) which may be deacylated in ethanolic hydrogen chloride to give 5-aminomethyl-2-propylpyrimidin-4-amine (737 R = H) (64CPB393) rather similarly, the pyrimidopyrimidinedione (738) reacts with amines to give, for example, 6-amino-5-benzyliminomethyl-l,3-dimethylpyrimidine-2,4(lFf,3Ff)-dione (739 R = CH2Ph) or the hydrazone (739 R = NH2) (74JCS(Pl)1812). 

Alloxan forms an oxime (1007) which is the same compound, violuric acid, as that formed by nitrosation of barbituric acid likewise, a hydrazone and semicarbazone. Reduction of alloxan gives first alloxantin, usually formulated as (1008), and then dialuric acid (1004 R = OH) the steps are reversible on oxidation. Vigorous oxidation with nitric acid and alkaline hydrolysis both give imidazole derivatives (parabanic acid and alloxanic acid, respectively) and thence aliphatic products. Alloxan and o-phenylenediamine give the benzopteridine, alloxazine (1009) (61MI21300). 

Both sides of acetone have been alkylated with different alkyl groups, in one operation, by treatment of the Al,lV-dimethylhydrazone of acetone with n-BuLi, followed by a primary alkyl, benzylic, or allylic bromide or iodide then another mole of n-BuLi, a second halide, and finally hydrolysis of the hydrazone. ... 

Hydrolysis of imines, oximes, hydrazones, or other C=N compounds... 

In 2-pyrazolines [103] the conjugation involves N-1 and C-3 atoms. 2-Pyrazolines may be regarded as cyclic hydrazones, which have the advantage over non-cyclic products of being stable to hydrolysis. It has been shown by Elguero and Jacquier (1965) that protonation occurs at N-1, giving cation [104], while forms with the proton at N-2 and C-3 [105] may exist in amounts of less than 1-5%. 

As proof of principle, Lehn and coworkers individually synthesized all acyl hydrazone combinations from the 13 DCL building blocks and measured their inhibition of acetylthiocholine hydrolysis by ACE in a standard assay. They then established a dynamic deconvolution approach whereby the pre-equilibrated DCL containing all members is prepared, frozen, and assayed. Thirteen sublibraries were then prepared containing all components minus one hydrazide or aldehyde component, and assayed. Active components in the DCL were quickly identified by an increase in ACE activity, observed in sublibraries missing either hydrazide 7 or dialdehyde i, pointing to the bis-acyl hydrazone 7-i-7 as the most likely active constituent. This was in line with the individual assay data recorded earlier resynthesis of this compound characterized it as a low nanomolar inhibitor of the enzyme. 

Since ketone R)-16 was prepared in a non-selective way when an achiral imino enolate was alkylated, it was considered whether alkylation of chiral enolates, such as that of oxazoline 18, with benzyl bromide 14, would provide stereoselective access to the corresponding alkylation product 19 with R-configuration at C(8) (Scheme 4). Indeed, alkylation of 18 with 14 gave the biaryl 19 and its diastereoisomer almost quantitatively, in a 14 1 ratio. However, reductive hydrolysis using the sequence 1. MeOTf, 2. NaBH4, and 3. H30", afforded hydroxy aldehyde 20 in 25% yield at best. Furthermore, partial epimerization at C(8) occurred (dr 7.7 1). An alternative route, using chiral hydrazones, was even less successful. 

The selective hthiation of 2-hexanone phenylaziridinyl-lEl-hydrazone 127 with LDA and subsequent alkylation with 8-(tert-butyldimethylsilyloxy)octyl bromide gave (Z)-hydrazone 128 in 65% yield. Its LDA-catalyzed selective decomposition followed by hydrolysis of the silyl ether yielded (Z)-9-tetradecen-l-ol, which was acetylated to afford the target compound 129 in 80% yield with a complete regioselectivity and a cisitrans ratio of 99.6/0.4. 

Ahlbrecht and coworkers showed that the stereoselective alkylation of Af-cinnamyl (5 )-2-methoxymethylpyrrolidine (STdR), followed by hydrolysis, affords enantiomerically enriched 3-substituted phenylpropionaldehydes, as shown in Scheme 45. This method is analogous to the asymmetric alkylation of S AMP/RAMP hydrazones, as the anions are isoelectronic. The mechanisms of asymmetric induction for the two systems are probably similar. For the lithio cinnamyl amine, methylation can be optimized up to 97.5% ds. Most of the procedures in this paper include potassium tert-butoxide, so the cation in these examples may be potassium. Under these conditions, methyl, primary and secondary alkyl iodides typically afford the products with selectivities in the 90-93% ds range. 

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