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Relevant academic research and scientific papers

Unexpected Formation of 2,2-Dichloro-N-(chloromethyl)acetamides during Attempted Staudinger 2,2-Dichloro-β-lactam Synthesis

In the quest for 3,3-dichloro-β-lactam building blocks, the serendipitous formation of 2,2-dichloro-N-(chloromethyl)acetamides was observed. This peculiar reactivity was investigated in detail, both experimentally and computationally by means of Density Functional Theory (DFT) calculations. 2,2-Dichloro-N-(chloromethyl)acetamides were thus shown to be formed experimentally through reaction of 2,2-dichloroacetyl chloride with glyceraldehyde-derived imines, i. e. (2,2-dimethyl-1,3-dioxolan-4-yl)methanimines, bearing aromatic N-substituents, in the presence as well as in the absence of a base. Deployment of aliphatic imines, however, resulted in complex reaction mixtures, pointing to the importance of a stabilizing aromatic substituent at nitrogen. The DFT results indicate that the substituents can alter the governing equilibria on the one hand and intrinsic barrier heights for the different routes on the other hand, showing that these are controlling the reaction outcome. Furthermore, the 2,2-dichloro-N-(chloromethyl)acetamides proved to be rather unstable in solution and thus difficult to isolate. Nonetheless, their molecular structure was confirmed by means of NMR analysis of several purified analogs and X-ray study of a 4-methoxyphenyl derivative.

Dichloromeldrum's acid (DiCMA): A practical and green amine dichloroacetylation reagent

Dichloromeldrum's acid is introduced as a bench-stable, nonvolatile reagent for the dichloroacetylation of anilines and alkyl amines to produce α,α-dichloroacetamides, which are important motifs for medicinal chemistry. Products are formed in good to excellent yields with reagent grade solvents, and, as the only byproducts are acetone and CO2, no column chromatography is required. Thus, this reagent is practical, efficient, and green for the dichloroacetylation of primary amines.

Zwitterion-Catalyzed Deacylative Dihalogenation of β-Oxo Amides

α,α-Dihalo-N-arylacetamides are commonly used as intermediates in various organic reactions. In the study described here, a catalytic synthesis of α,α-dihalo-N-arylacetamides from β-oxo amides was developed using zwitterionic catalysts and N-halosuccinimi

Novel N-phenyl dichloroacetamide derivatives as anticancer reagents: Design, synthesis and biological evaluation

A current study shows that sodium dichloroacetate (DCA) can induce cancer cell apoptosis and inhibit tumor growth, but its cytotoxic activity is low (IC50 > 1000 μM for A549). In this paper, a variety of DCA derivatives were synthesized, and their cytotoxic activities were evaluated. The result showed that the N-phenyl-2,2-dichloroacetamide analogues had satisfactory potencies. Among them, N-(3-iodophenyl)-2,2-dichloroacetamide (3e), an optimized lead compound, has an IC50 against A549 as low as 4.76 μM. Furthermore, it can induce cancer cell apoptosis and has a low toxicity in mice (LD50 = 1117 mg/kg). N-phenyl-2,2-dichloroacetamide analogues has higher cytotoxic activity and N-(3-iodophenyl)-2,2-dichloroacetamide (3e) is an optimized lead compound.

Synthesis and characterization of N-acylaniline derivatives as potential chemical hybridizing agents (CHAs) for wheat (Triticum aestivum L.)

Induction of male sterility by deployment of chemical hybridizing agents (CHAs) are important in heterosis breeding of self-pollinated crops like wheat, wherein the male and female organs are in the same flower. Taking a lead from the earlier work on rice, a total of 25 N-acylanilines comprising of malonanilates, acetoacetanilides, and acetanilides (including halogenated acetanilides) were synthesized and screened as CHAs on three genotypes of wheat, viz., PBW 343, HD 2046, and HD 2733 at 1500 ppm in the winter of 2001-2002. The N-acylanilines containing variations at the acyl and aromatic domain were synthesized by condensation of substituted anilines with appropriate diesters, acid chlorides, or monoesters. The test compounds with highly electronegative groups such as F/Br at the para position of the aryl ring were identified as the most potent CHAs, causing higher induction of male sterility. A variation of N-substitution at the side chain generally furnished analogues like 4′-fluoroacetoacetanilide (7) and ethyl 4′-fluoromalonanilate (1), which induced 89.12 and 84.66% male sterility, respectively, in PBW 343. Among halogenated acetanilides, the increasing number of chlorine atoms in the side chain led to an increase in the activity of 4′-fluoro (23) and 4′-bromo (24) derivatives of trichoroacetanilides, which induced >87% male sterility. Quantitative structure-activity relationship (QSAR) models indicated the positive contributions of the field effect exemplified by the Swain-Lupton constant (Fp) and negative contributions of the Swain-Lupton resonance constant (R) for the aromatic substitution. The positive influences of parachor (P) for the acyl domain have been underlined. These leads will be significant in explaining the CHA fit in the macromolecular receptor site. The CHAs appeared to act by causing an imbalance in the acid-base equilibrium in pollen mother cells resulting in dissolution of the callose wall by premature callase secretion.

N-acylanilines, herbicide-CHA chimera, and amino acid analogues as novel chemical hybridizing agents for wheat (Triticum aestivum L.)

In the absence of viable alternative technology of hybrid wheat development, chemical induction of male sterility mediated technology based on chemical hybridizing agents (CHAs) holds a great potential. N-Acylaniline derivatives, namely, ethyl 4′-fluoro oxanilate (1) and ethyl 4′-trifluoromethyl oxanilate (2) containing halogen atoms in the para position of the aryl ring and substituted amide linkage (-CO-NH-) in the acyl side chain induced >98% spikelet sterility on three genotypes of wheat, namely, PBW 343, HD 2046 and HD 2733, at 1500 ppm. The active moieties were incorporated in the form of herbicide-CHA chimera and amino acid analogues using glycine and alanine as templates. The target activity was made more selective by synthesizing chimeric structure of herbicide (2,4-dichlorophenoxyacetic acid and dalapon) and the most active CHA templates, namely, 4-fluoroanilinyl and β-ethoxycarbonyl moieties. Among herbicide-CHA chimera ethyl 2′,4′-dichlorophenyl oxalate (14) induced 79.11% male sterility, whereas benzyl methyl 2-oxo-3-azaadipate (20) was the best, inducing 73.87% male sterility in HD 2733, among amino acid analogues. The CHAs were found to modify the reproductive biology to ensure cross-pollination in the cleistogamous wheat flowers, increasing the probability for the development of hybrids.