Chalcones, preparation

You may choose to create a multistep synthesis by linking this experiment to the Friedel-Crafts acylation reaction (Experiment 56) for the preparation of the substituted acetophenone. Experiment 56 contains suggestions for Friedel-Crafts acetophenones that work well when converted to chalcones. Following the synthesis of the chalcone in the current experiment, you can then carry out the cy-clopropanation reaction (Experiment 63) and/or the epoxidation of the chalcone (Experiment 62). If the multistep scheme is to be followed, you should ask the class to scale up the chalcone preparation in order to have enough material to complete Experiment 62 and 63. 

Pyridyl)hydrazine (Aldrich), 4-acetylpyridine (Acros), N,N,N -trimethylethylenediamine (Aldrich), methylrhenium trioxide (Aldrich), InQj (Aldrich), Cu(N0j)2-3H20 (Merck), Ni(N03)2-6Il20 (Merck), Yb(OTf)3(Fluka), Sc(OTf)3 (Fluka), 2-(aminomethyl)pyridine (Acros), benzylideneacetone (Aldrich), and chalcone (Aldrich) were of the highest purity available. Borane dimethyl sulfide (2M solution in THE) was obtained from Aldrich. Methyl vinyl ketone was distilled prior to use. Cyclopentadiene was prepared from its dimer immediately before use. (R)-l-acetyl-5-isopropoxy-3-pyrrolin-2-one (4.15) has been kindly provided by Prof H. Hiemstra (University of Amsterdam). 

More serious limitations and precautions apply to compounds in which not all three R, R, and R" groups are aromatic. Autocondensation of benzylideneacetone (111) yields an unstable chloroferrate which may be 113 or 115, according to whether a Michael addition to 112 or a crotonic condensation to 114 is first involved. Since compound 113 could readily be prepared from 2,6-dimethyl-4-phenylpyrylium and benzaldehyde, the structure of the reaction product should be easily soluble. Another equivocal product is formed from two moles of benzylideneacetone, but a definite structure (116) results from chalcone and benzylideneacetone. ... 

Potent antimicrobial l,2,4-triazolo[3,4-fc]-l,3,4-thiadiazepines derivatives were prepared from readily accessible substituted 2-mercapto-l-aminotria-zoles and substituted chalcones on basic alumina in a solvent-free microwave-assisted synthesis (Scheme 28). Exposure of the reaction mixtures to microwaves led to an important decrease of the reaction time, which has been brought down from hours to seconds, accompanied by improved yields as compared with conventional heating [36]. This facile, rapid, and economic... 

Chalcone dibromides are advantageous intermediates for the preparation of various nitrogen-containing heterocycles (refs. 1-4). In the case of exocyclic a,P-unsaturated ketones, however, only few examples are known concerning the utilization of their dibromides for such purposes (ref. 5). Our aim was, therefore, the synthesis of the dibromides of various exocyclic a,P-unsaturated ketones (ref. 6) and to study their chemical transformations. In our present paper the reaction of such dibromides with azide nucleophile is reported. 

The first enantioselective synthesis of cis- and trans- 3-hydroxyflavanones is based on the Lewis-acid-catalysed reaction of phenylmethanethiol with chalcone epoxides <96CC2747>. Further support for the intermediacy of epoxides in the Algar-Flynn-Oyamada flavone synthesis has been provided by the isolation of epoxides in the corresponding preparation of 3-hydroxy-2-phenylquinol-4-ones <96JCS(P2)269>. 

Scheme 20), these acetals could readily be converted into isofiavones. Unfortunately, very low yields of rearrangement products were obtained using thallium(III) acetate, and separation and purification of acetals such as (XXXIV) was extremely tedious. Reaction of chalcones with TTN, on the other hand, is generally complete within a few hours at room temperature 95), and Farkas et al. (J75) have developed the Ollis procedure into a simple method for the preparation of isofiavones (Scheme 21). 

Holst, S., Natural colors for food and beverages. FoodMktg. Technol, 14, 14, 2000. Sanoner, P. et al.. Colouring hydrosoluble yellow preparation derived from dehydro-chalcones. International Patent WO 2005/049598, 2005. 

Recently, the Texier-Boullet group [26] has prepared nitrocyclohexanols 10-77 by a twofold Michael addition/aldol reaction sequence (Scheme 10.19). Simply mixing chalcone 10-75 with nitromethane in the presence of a mixture of KF and A1203 under microwave irradiation gave 10-79 via the proposed intermediates 10-76, 10-77 and 10-78 as a single diastereomer in 65 % yield. One possible explanation for the stereoselectivity of the transformation is fixation of the reactive species onto the solid KF/A1203, as depicted in 10-79. 

An array of 25 600 analogues of 49a was prepared from 80 chalcones, 20 amino acids, and 16 isatins <1998T4085>. 

The readily prepared support was then used for dihydropyrimidine and chalcone synthesis (Scheme 7.29). Thus, the modified support was activated prior to reaction by treatment with tosyl chloride. Solutions of the appropriate acetophenones were then spotted onto the membrane and the support was submitted to microwave irradiation for 10 min [45]. In the next step, several aryl aldehydes were attached under microwave irradiation to form a set of corresponding chalcones through a Claisen-Schmidt condensation. 

The key step in Hu s synthesis of 51 was cyclization of 50 by heating with copper(I) iodide and sodium hydride in DME, followed by a 10% aqueous ammonia work-up. Intermediate 50 was prepared via Michael addition of ethyl acetamidocyano acetate to the appropriate chalcone followed by acid-catalyzed ring closure [42,43]. 

The imine 217, formed from acetophenone and the 1-aminoimidazole, has been transformed into the enamine 218 which is then cyclized to 219 in trifluoroacetic acid (TFA) (Equation 40) <1995SC3271 >. The diaminoimidazole 220 reacts with ynone 221 to form 222 (Equation 41) <1998CHE1189>. Bromochalcones and chalcone dibromides can also be used in place of the ynone. Similar reactions have been used to prepare the dihydro analogues of 222 <1999CHE1207>. The reaction between 1-aminoimidazoles and 1,3-diketones has been extended to prepare bis-heterocyclic compounds, for example, 223 as ligands for transition metals (Equation 42) <2005EJI4382>. 

Anomeric hydroperoxides are readily prepared by treatment of 2-deoxy sugars with H202 in the presence of acid (Fig. 59). They are used as reagents for enantioselective epoxidation of a,(Tunsaturated olefins (e.g. chalcone) in the presence of sodium hydroxide, the epoxidations showed exceptionally high asymmetric induction.76... 

The publication (70) in 1976 of the preparation of optically active epoxyketones via asymmetric catalysis marked the start of an increasingly popular field of study. When chalcones were treated with 30% hydrogen peroxide under (basic) phase-transfer conditions and the benzylammonium salt of quinine was used as the phase-transfer catalyst, the epoxyketones were produced with e.e. s up to 55%. Up to that time no optically active chalcone epoxides were known, while the importance of epoxides (arene oxides) in metabolic processes had just been discovered (71). The nonasymmetric reaction itself, known as the Weitz-Scheffer reaction under homogeneous conditions, has been reviewed by Berti (70). 

A multigram preparation of a useful chiral building block was developed, using the Beckmann rearrangement as a key synthetic step (equation 115) °. The enantiomeric addition of thiophenol to a chalcone 313, catalysed by (+)-cinchonine, provided the chiral enantiomeric carbonyl compound 314. The Beckmann rearrangement of its oxime 315 gives the anilide of (R)-(- -)-3-phenyl-3-phenylsulfanylpropanoic acid 316. Alcoholysis produced the expected enantiomerically pure ethyl ester 317. 

Figure 6.39 Cinchona alkaloid-thioureas prepared from quinine (121), dihydroquinine (122), C9-epi-quinine (123), and quinidine (124) catalytic efficiency evaluated in the Michael addition of nitromethane to tram-chalcone 1,3-diphenyl-propenone at 10mol% loading and rt.

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