Mario Ordóñez

Bio: Mario Ordóñez is an academic researcher from Universidad Autónoma del Estado de Morelos. The author has contributed to research in topics: Enantioselective synthesis & Catalysis. The author has an hindex of 19, co-authored 129 publications receiving 1739 citations. Previous affiliations of Mario Ordóñez include University of Seville & Spanish National Research Council.

Recent progress on the stereoselective synthesis of cyclic quaternary α-amino acids

Abstract: The most recent papers describing the stereoselective synthesis of cyclic quaternary α-amino acids are collected in this review The diverse synthetic approaches are classified according to the size of the ring and taking into account the bond that is formed to complete the quaternary skeleton

Stereoselective synthesis of γ-amino acids

Abstract: γ-Amino acids have attracted considerable attention as biologically active compounds in the central nervous system (CNS) of mammals. Over the last few years, significant interest in the stereoselective synthesis and practical application of linear and cyclic chiral γ-amino acids in the synthesis and design of α,β- and β,γ-hybrid peptides with definite secondary structures and design of nanotubes has been reported, thus demonstrating the theoretical interest and the practical importance of γ-amino acids. An overview of synthetic approaches to linear and cyclic chiral γ-amino acids and derivatives is presented. Data on the practical applications of γ-amino acids are also discussed.

Enantioselective synthesis of sulfoxides: 2000-2009.

Abstract: 1.2.2. Davis Oxaziridines 4305 1.2.3. Metal Complexes in Enantioselective Oxidation 4305 1.3. New Applications 4307 1.3.1. Chiral Sulfinate Method 4307 1.3.2. Oxidation with Chiral Oxaziridines 4309 1.3.3. Oxidation Using Metal Complexes 4310 1.4. New Systems 4313 1.4.1. C-S Bond Formation 4314 1.4.2. Organic Oxidants 4315 1.4.3. Oxidations Catalyzed by Metal Complexes 4316 1.5. Diastereoselective Oxidations 4330 1.6. Heterogenized Systems 4332 1.7. Summary 4335 2. Biological Oxidations 4336 2.

Squaramide‐Catalyzed Enantioselective Michael Addition of Diphenyl Phosphite to Nitroalkenes

Abstract: Horiguchi and Kandatsu’s isolation of 2-amino ethylphosphonic acid from the rumen protozoa in 1959 demonstrated for the first time the occurrence of a C-P bond in nature.[1] Such β-amino phosphonic acids, as phosphorus analogs of β-amino acids, have been the subject of intense interest due to their diverse biological activities.[2] In contrast to the armamentarium of methods for the asymmetric synthesis of α-amino phosphonic acid derivatives,[3, 4] the enantioselective synthesis of β-amino phosphonic acids remains a considerable challenge.[5] A logical solution to this problem is through the enantioselective Michael addition of diaryl or dialkyl phosphites to nitroalkenes to provide β-nitro phosphonates, wherein reduction of the nitro group would produce chiral β-amino phosphonates.[6–8] To date, only two reports describe the use of metal-free catalysts for the conjugate addition reaction of phosphites.[9–11] Wang and coworkers showed in 2007 that quinine promotes this reaction and affords the addition products in modest to very good ee’s.[9] Significantly higher enantioselectivities were obtained by Terada and coworkers, who used an intricate, axially-chiral biaryl guanidine to promote this conjugate addition reaction.[10, 12] In connection with our interest in hydrogen-bond donor promoted enantioselective reactions,[13, 14] we have developed a new family of chiral catalysts based on the squaramide scaffold.[15] The modular nature of this scaffold allows quick access to a wide range of catalysts, tuned with regard to the chiral environment as well as the pKa of the donor hydrogens, and opens up opportunities for the exploration of new reactions and the development of highly effective catalysts for known reactions. We report here that a simple, easily prepared squaramide catalyst promotes the Michael addition reaction of diphenyl phosphite to a broad range of nitroalkenes, both aryl- and alkyl-substituted, affording the products in high yields and uniformly excellent enantioselectivities. Despite the plethora of successful reactions promoted by various thiourea-based catalysts,[16] the only reported use of a chiral thiourea to promote the addition of diphenyl phosphite to trans-β-nitrostyrene is that by Wang, who obtained the addition product in 21% yield and 8% ee after a reaction time of 24 h.[9] Given the structural differences between thioureas and squaramides, particularly the spacing between the two donor hydrogen atoms,[15] we expected to see differences in their reactivity. Indeed, addition of the dimethyl-substituted squaramide 4a[17] to a solution of trans-β-nitrostyrene (1a) and diphenyl phosphite (2) at room temperature promoted a rapid reaction that went to 98% conversion after just 45 minutes and afforded the addition product in 81% ee (Table 1, entry 1). Table 1 Michael addition of diphenyl phosphite (2) to trans-β-nitrostyrene (1a) catalyzed by 4 or 5[a]. In order to optimize the catalyst, a brief study of the structure-enantioselectivity relationship was carried out (Table 1). The effect of various substituents on the amino group of the catalyst was examined first (entries 2–4). Catalyst 4b bearing the bulkier n-propyl groups on the nitrogen improved the enantioselectivity slightly, with accompanying diminution in the reaction rate (entry 2). Higher enantioselectivities were observed when the amine substituents constitute a ring. Thus, the pyrrolidine-substituted catalyst 4c gave the product in 88% ee, and the corresponding piperidine-substituted catalyst 4d catalyst gave the product in 95% ee (entries 3, 4). The improved enantioselectivities from the cyclic substituents, particularly piperidine, are attributed to the relative conformational rigidity of these groups, which allows a more organized transition state, one that better differentiates the two sides of trans-β-nitrostyrene. After a brief survey of different substituents on the aryl moiety, we chose catalyst 5 for further studies, due to its ease of preparation and better catalytic selectivity (entry 5). Catalyst 5 is prepared in 3-steps from commercial starting materials (Scheme 1). Scheme 1 Synthesis of catalyst 5. A survey of solvents showed the phosphite conjugate addition reaction to be relatively insensitive to the solvent used (Table 2). The enantioselectivity obtained in toluene was essentially the same as that obtained in ether solvents, including THF (entries 1–4).[18] Even very polar solvents such as acetonitrile and acetone afforded the addition product in 90% or greater ee (entries 5,6). The best solvent was found to be CH2Cl2, in which, as noted earlier, the room temperature reaction gave the product in 96% ee (entry 7). As expected, the enantioselectivity increased steadily as the reaction temperature was lowered (entries 8–10). Taking into account the practical advantages of carrying out the reaction at 0 °C, this temperature was used for evaluating the scope of the methodology. Table 2 Michael addition of diphenyl phosphite (2) to trans-β-nitrostyrene (1a) catalyzed by 5[a]. A diverse range of aryl-substituted nitroalkene substrates were selected to evaluate the scope of the squaramide catalyzed conjugate addition reaction. As shown in Table 3, the enantioselective conjugate addition reaction is remarkably general: under the optimized conditions, the full spectrum of substrates underwent the reaction in 30 minutes or less and afforded the products in good yields with 96–99% ee, regardless of the electronic properties and locations of substituents. The parent reaction can be scaled up without untoward effect on either the yield or enantioselectivity (entry 1). It is worth noting that even substrates with acidic protons capable of forming competing hydrogen bonds, such as 1l and 1q, were tolerated and afforded the expected products in 98% ee (entries 12, 17). Table 3 Enantioselective Michael addition reaction of diphenyl phosphite (2) to trans-nitroalkenes (1, R = aromatic substituent) catalyzed by 5[a]. Among the most challenging substrates for the organocatalyzed phosphite conjugate addition reaction are alkyl-substituted nitroalkenes.[9, 10] The highest enantioselectivity recorded for such substrates is 87% ee.[19] To evaluate the effectiveness of catalyst 5 in these reactions, several alkyl-substituted nitroalkenes were subjected to the optimized conditions. As summarized in Table 4, excellent enantioselectivities were obtained even for aliphatic nitroalkenes (95–97% ee). Compared to aryl-substituted substrates, the reactions of alkyl substrates were slower, presumably due to steric and electronic factors. To circumvent the slow rate of substrates with secondary and tertiary alkyl groups, the catalyst loading was increased to 20 mol% (entries 4–6). With this modification, even the highly hindered t-butyl-containing substrate 3w reacted to completion, giving the phosphite addition product in 83% yield and 96% ee (entry 6). Table 4 Enantioselective Michael addition reaction of diphenyl phosphite (2) to trans-nitroalkenes (1, R = aliphatic substituent) catalyzed by 5[a]. The results above show squaramide 5 to be a remarkably effective catalyst for the enantioselective Michael addition reactions of diphenyl phosphite to nitroalkenes. The reaction provides a simple, highly enantioselective synthesis of chiral β-nitro phosphonates, which are precursors to biologically active β-amino phosphonic acids. The high yields and uniformly excellent enantioselectivities obtained for both aryl- and alkyl-substituted nitroalkenes, including those bearing acidic protons or sterically-demanding substituents, point to the unique capability of the squaramide scaffold. Given the simple, modular assembly of squaramides, and the ready availability of its precursors, this scaffold is expected to provide many further opportunities in asymmetric catalysis.