Halides hydrazones

Entry Halide Hydrazone (R ) Catalyst load % Yield (% ee° )... 

Having retraced the remarkably efficient sequences of reactions which led to syntheses of key intermediates 14 and 15, we are now in a position to address their union and the completion of the synthesis of the spiroketal subunit (Scheme 6b). Regiocontrolled deprotonation of hydrazone 14 with lithium diisopropylamide (LDA), prepared from diisopropylamine and halide-free methyl-lithium in ether, furnishes a metalloenamine which undergoes smooth acylation when treated with A-methoxy-A-methylcarboxa-mide 15 to give the desired vinylogous amide 13 in 90% yield. It is instructive to take note of the spatial relationship between the... 

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. ... 

The hydrazone group is hydrolyzed (16-2) during the course of the reaction. Yields are high. Aryl iodides are converted to unsymmetrical diaryl ketones on treatment with aryImercury halides and nickel carbonyl ArH-Ar HgX-l-Ni(CO)4 ArCOAr... 

The reactions involving either benzophenone hydrazone or w-hexylamine have been studied by reaction calorimetry. The benzophenone hydrazone reaction presents zero order kinetics, while the hexylamine reaction is first order in the aryl halide and zero order in the amine. Under synthetically relevant conditions, at 90°C, the rate of the hexylamine reaction is about 30-fold higher than the rate of the benzophenone reaction. 

The heat profile shows that the reaction has zero order kinetics at first, and then switches to positive order kinetics. The benzophenone hydrazone reacts first only when it is completely consumed, the reaction involving hexylamine begins. Samples were taken and analyzed by and NMR. One sample was taken when the aryl halide conversion was low, at about 5%, and the profile was overall zero order the second when the profile had switched to positive order and the conversion of the halide was greater than 50%. 

We studied the competitive amination of two amines (benzophenone hydrazone and -hexylamine) and one aryl halide (3-bromobenzotrifluoride), catalyzed by Pd(BlNAP). We showed that, when reacting alone at the same conditions, n-hexylamine is considerably more reactive and shows positive order kinetics benzophenone hydrazone shows zero order kinetics and forms a very stable intermediate, the BlNAP(Pd)Ar(amine) we also observed by NMR. During the competitive reaction of the two amines, the benzophenone hydrazone reacts first and only when it is completely consumed, the hexylamine starts to react. In this case it is the stability of the major intermediate, and not the relative reactivity, which dictates the selectivity. 

Allylation of acyloyl-imidazoles and pyrazoles61 with allyl halide mediated by indium in aqueous media provides a facile regioselective synthesis of P, y-unsaturated ketones (Scheme 11.1), which has been applied to the synthesis of the monoterpene artemesia ketone. The same product can be obtained by indium-mediated allylation of acyl cyanide (Eq. 11.35).62 Samarium, gallium, and bismuth can be used as a mediator for the allylation of nitrones and hydrazones to give homoallylic hydroxylamine and hydrazides in aqueous media in the presence of Bu4NBr (Scheme 11.2).63 The reaction with gallium and bismuth can be increased dramatically under microwave activation. 

Clerici and Porta reported that phenyl, acetyl and methyl radicals add to the Ca atom of the iminium ion, PhN+Me=CHMe, formed in situ by the titanium-catalyzed condensation of /V-methylanilinc with acetaldehyde to give PhNMeCHMePh, PhNMeCHMeAc, and PhNMeCHMe2 in 80% overall yield.83 Recently, Miyabe and co-workers studied the addition of various alkyl radicals to imine derivatives. Alkyl radicals generated from alkyl iodide and triethylborane were added to imine derivatives such as oxime ethers, hydrazones, and nitrones in an aqueous medium.84 The reaction also proceeds on solid support.85 A-sulfonylimines are also effective under such reaction conditions.86 Indium is also effective as the mediator (Eq. 11.49).87 A tandem radical addition-cyclization reaction of oxime ether and hydrazone was also developed (Eq. 11.50).88 Li and co-workers reported the synthesis of a-amino acid derivatives and amines via the addition of simple alkyl halides to imines and enamides mediated by zinc in water (Eq. 11.51).89 The zinc-mediated radical reaction of the hydrazone bearing a chiral camphorsultam provided the corresponding alkylated products with good diastereoselectivities that can be converted into enantiomerically pure a-amino acids (Eq. 11.52).90... 

Another sequence involving an anionic and a Pd-catalyzed step was described by the groups of Rossi and Arcadi [477]. These authors prepared substituted tetrahy-dro-2H-pyrrolo[3,2-c]pyrazolones 2-934 starting from hydrazones 2-932 and aryl-halides or alkenyl triflates 2-933 (Scheme 2.208). The first step is the formation of a pyrazolone. There follows cleavage of the urea moiety with piperidine and an inter-as well as an intramolecular Heck-type reaction with 2-933. 

The enamine 141 can be cyclized to the [l,2,4]triazolopyridopyrimidine 142 upon treatment with sodium ethoxide (Scheme 40) <2002M1297>. This fused tricyclic system may also be obtained, like the pteridine analogue (cf. Scheme 38), from the reaction of hydrazonoyl halides and pyridopyrimidines such as 143, and also by treatment of the triazolopyrimidine 144 with dimethylformamide dimethylacetal (DMF-DMA) dimethylacetal and subsequent ring closure <2003MOL333, 2003HAC491> (Scheme 41). Another series of triazolopyridopyrimidines, for example, 146, can be prepared from a hydrazine-substituted pyridopyrimidine 145, in two ways either directly by reaction with an acid chloride, or via a derived hydrazone (Scheme 42) <1996MI585>. 

Nitrene intermediates are implicated in the formation of the pyrrole (64) from an azirinyl aldehyde and (65).67 Treatment of the nitrosouracil (66) with benzyl idene-ylides affords the corresponding theophylline derivatives.68 Hydrazonic halides and keto-ylides initially give betaines (67), which ring-close to (68) on heating.69... 

Acid halides react with vinylphosphoranes (56) to afford isolable N-acylaminophosphonium salts (57), which are hydrolyzed by alkali to N-vinylamides (58). By treatment with triethylamine and phenol the halogen in 57 can be nucleophilically exchanged for phenolate. Thiophenol, secondary amines, and hydrazones can be employed instead of phenol this leads to diverse 1-hetero-substituted 2-aza-1,3-dienes 59 (Scheme 31) (90TL3497). 

Hydrazinothiatriazole (133) reacts rapidly with ketones and aldehydes to give thermally relatively stable hydrazones (134) in good yields ( 80%) <85ZC136, 87JPR409). Compounds (134) are alkylated with alkyl halides exclusively at the hydrazino functionality (rather than at N(4)) to give (135) (Scheme 27). 

The metalated hydrazones are alkylated by alkyl halides, dialkyl sulfates or alkyl sulfonates at low temperatures in tetrahydrofuran (—95°C) or diethyl ether (— 110°C) to form the a-sub-stituted hydrazones in nearly quantitative yields. The ambident azaenolates react exclusively at the C-terminus side products resulting from N-, di-, or polyalkylation are not observed. The crude alkylated hydrazones can be purified by distillation or silica gel chromatography (diethyl ether/pentane) without epimerization. However, in most cases, they are pure enough to be directly cleaved to the desired alkylated carbonyl compound. 

A solution of 1 equiv of (S)- or (/ )-2-methoxymetliyl-1-[(2,2-dimethyl-l,3-dioxan-5-ylidene)amino]pyrro-lidine in THF (4 mL/mmol) is cooled to — 78 °C. 1.1 Equiv of tert-butyllithium in hexane (1.7 M) are added dropwise and the mixture is stirred for 2 h at — 78 °C. The solution of the metalated hydrazone is cooled to — 100 CC, 1.2 equiv of the alkyl halide (neat or as a solution in anhyd THF) are added dropwise, and the mixture is stirred for 1 h at —100 °C and then warmed slowly to r.t. (about 15 h). Finally, diethyl ether (30 mL/mmol) is added and the mixture is washed with pH 7 buffer (3 mL/mmol) and two 3-mL portions of brine, dried over MgSO and evaporated under reduced pressure. The Crude product is heated to 50 C for a short time if necessary (about 15 min for isomerization from the Z- to the L-isotiler monitored by TLC) and purified by silica gel column chromatography (diethyl ether/ pentane, 1 1 -2 5 Rf - > RfZ-iso-mer) to give a colorless or pale yellow product. See Table 2 for physical data. 

Anhydrides of sugars1723 have also been obtained by intramolecular displacement of halide ions. Thus, for example, treatment of 3,4-di-0-acetyl-2-bromo-2-deoxy-D-xylopyranose (133) with (p-ni-trophenyl)hydrazine affords173 3,4-di-0-acetyl-2,5-anhydro-D-lyxose (p-nitrophenyl)hydrazone (135) and 3,4-di-0-acetyl-2,5-anhydro-D-xylose (p-nitrophenyl)hydrazone (136). The formation of two (p-nitrophenyl)hydrazones can be explained by an initial displacement of the bromine atom at C-2 by 0-5, to give 3,4-di-0-acetyl-2,5-... 

An interesting extension of the reaction is the treatment of hydrazones with a-haloacyl halides under phase-transfer catalysis, when hydrazones of symmetrical l,4-diaminopiperazine-2,5-diones result (84CPB2426) (Scheme 8). 

O-Benzyllactaldehyde dimethylhydrazone 230 allows a substrate control in the addition reaction of organomagnesium halides, leading almost exclusively to the 5yn-isomer 231 (equation 155) . The resulting hydrazide can be reduced on Raney Ni to the corresponding iyw-aminoalcohol 232. The stereoselective Grignard addition to a similar A-formyl hydrazone 233 proceeds with 92% diastereoselectivity (equation 156). The silylation of the amide nitrogen by TMSCl provides the pure iyw-adduct . 

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