23356-96-9Relevant articles and documents
Asymmetric Synthesis. Metal Complex Mediated Synthesis of Chiral Glycine by Enantioselective Proton Exchange
Dokuzovic, Zdravko,Roberts, Nicholas K.,Sawyer, Jeffery F.,Whelan, John,Bosnich, B.
, p. 2034 - 2039 (1986)
The complex (1+), a species containing a chiral tridentate triamine ligand, (S,S)-proam, and a tridentate ligand incorporating a glycine residue, picgly, has been prepared.The α-protons of the coordinated glycine residue exchange at different rates in basic D2O solutions.The difference in rate was found to be 7.8:1 in favor of the pro-S proton at pD 11.2 at 25 deg C with a NaHCO3/Na2CO3 buffer.It is proposed that the origins of this enantiosection arise from both steric and hydrogen-bonding effects as inferred from the determined crystal structure of the complex.A kinetic analysis of the exchange process shows that the system is essentially that of an asymmetric synthesis (CH2 -> CHD) followed by a reinforced kinetic resolution (CHD -> CD2).As such, the optical purity of the chiral glycine (NH2CHDCO2H) continuously increases with the extent of reaction.This was confirmed.It is suggested that the present kinetic relationships are representative of the majority of asymmetric syntheses involving enantiotopic atoms or groups, and it follows that, for such systems, quoting an enantiomeric excess has meaning only when the extent of reaction is specified.
Chiral recognition of amino acid derivatives by 1,1′-binaphthalene-8,8′-diol
Kawabata, Takeo,Kuroda, Akio,Nakata, Eizo,Takasu, Kiyosei,Fuji, Kaoru
, p. 4153 - 4156 (1996)
Optically active 1,1′-binaphthalene-8,8′-diol is found to bind a variety of amines in CDCl3 or C6D6 solution. Significant chiral recognition (ΔΔGo = ~1.2 kcal/mol) was observed in the valine derivative 4. A three-point binding motif is assumed. Copyright
London Dispersion Interactions Rather than Steric Hindrance Determine the Enantioselectivity of the Corey–Bakshi–Shibata Reduction
Eschmann, Christian,Song, Lijuan,Schreiner, Peter R.
supporting information, p. 4823 - 4832 (2021/02/01)
The well-known Corey–Bakshi–Shibata (CBS) reduction is a powerful method for the asymmetric synthesis of alcohols from prochiral ketones, often featuring high yields and excellent selectivities. While steric repulsion has been regarded as the key director of the observed high enantioselectivity for many years, we show that London dispersion (LD) interactions are at least as important for enantiodiscrimination. We exemplify this through a combination of detailed computational and experimental studies for a series of modified CBS catalysts equipped with dispersion energy donors (DEDs) in the catalysts and the substrates. Our results demonstrate that attractive LD interactions between the catalyst and the substrate, rather than steric repulsion, determine the selectivity. As a key outcome of our study, we were able to improve the catalyst design for some challenging CBS reductions.
l -Proline as a Valuable Scaffold for the Synthesis of Novel Enantiopure Neonicotinoids Analogs
Bonilla-Landa, Israel,Cuapio-Mu?oz, Ulises,Luna-Hernández, Axel,Reyes-Luna, Alfonso,Rodríguez-Hernández, Alfredo,Ibarra-Juarez, Arturo,Suarez-Mendez, Gabriel,Barrera-Méndez, Felipe,Caram-Salas, Nadia,Enríquez-Medrano, J. Francisco,Díaz De León, Ramón E.,Olivares-Romero, José Luis
, p. 1455 - 1465 (2021/02/16)
In this research, six neonicotinoid analogs derived from l-proline were synthesized, characterized, and evaluated as insecticides against Xyleborus affinis. Most of the target compounds showed good to excellent insecticidal activity. To the best of our knowledge, this is the first report dealing with the use of enantiopure l-proline to get neonicotinoids. These results highlighted the compound 9 as an excellent candidate used as the lead chiral insecticide for future development. Additionally, molecular docking with the receptor and compound 9 was carried out to gain insight into its high activity when compared to dinotefuran. Finally, the neurotoxic evaluation of compound 9 showed lower toxicity than the classic neonicotinoid dinotefuran.
Understanding the Alkylation Mechanism of 3-Chloropiperidines – NMR Kinetic Studies and Isolation of Bicyclic Aziridinium Ions
Helbing, Tim,Georg, Mats,St?hr, Fabian,Carraro, Caterina,Becker, Jonathan,Gatto, Barbara,G?ttlich, Richard
, p. 5905 - 5913 (2021/10/29)
The present study describes the kinetic analysis of the 3-chloropiperidine alkylation mechanism. These nitrogen mustard-based compounds are expected to react via a highly electrophilic bicyclic aziridinium ion, which is readily attacked by nucleophiles. Halide abstraction using silver salts with weakly coordinating anions lead to the isolation of these proposed intermediates, whereas their structure was confirmed by single crystal XRD. Kinetic studies of the aziridinium ions also revealed notable reactivity differences of the C5 gem-methylated compounds and their unmethylated counterparts. The observed reactivity trends were also reflected by NMR studies in aqueous solution and DNA alkylation experiments of the related 3-chloropiperidines. Therefore, the underlying Thorpe-Ingold effect might be considered as another option to adjust the alkylation activity of these compounds.
Production of professional linoleic, complex metal compounds and manufacturing method thereof
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Paragraph 0081-0085, (2021/11/26)
[A] a method of manufacturing a novel professional linoleic. Also, suitable for producing a professional linoleic, complex metal compound and its manufacturing method. The manufacturing method of the present invention [a] professional linoleic, selected from Rh metal or Pt, selected from the group consisting of one or more metal oxide Mo and 1 is supported by a carrier in the presence of a composite metal compound, by reacting with hydrogen containing proline. The present invention is a composite metal compound, or a metal selected from Rh Pt, selected from the group consisting of one or more metal oxide Mo and 1 compound, Al2 O3 Carried by the carrier. Figure 3 [drawing]
Basicities and Nucleophilicities of Pyrrolidines and Imidazolidinones Used as Organocatalysts
An, Feng,Maji, Biplab,Min, Elizabeth,Ofial, Armin R.,Mayr, Herbert
supporting information, p. 1526 - 1547 (2020/02/04)
The Br?nsted basicities pKaH (i.e., pKa of the conjugate acids) of 32 pyrrolidines and imidazolidinones, commonly used in organocatalytic reactions, have been determined photometrically in acetonitrile solution using CH acids as indicators. Most investigated pyrrolidines have basicities in the range 16 aH aH aH 12.6) and the 2-imidazoliummethyl-substituted pyrrolidine A21 (pKaH 11.1) are outside the typical range for pyrrolidines with basicities comparable to those of imidazolidinones. Kinetics of the reactions of these 32 organocatalysts with benzhydrylium ions (Ar2CH+) and structurally related quinone methides, common reference electrophiles for quantifying nucleophilic reactivities, have been measured photometrically. Most reactions followed second-order kinetics, first order in amine and first order in electrophile. More complex kinetics were observed for the reactions of imidazolidinones and several pyrrolidines carrying bulky 2-substituents, due to reversibility of the initial attack of the amines at the electrophiles followed by rate-determining deprotonation of the intermediate ammonium ions. In the presence of 2,4,6-collidine or 2,6-di-tert-butyl-4-methyl-pyridine, the deprotonation of the initial adducts became faster, which allowed the rate of the attack of the amines at the electrophiles to be determined. The resulting second-order rate constants k2 followed the correlation log?k2(20 °C) = sN(N + E), where electrophiles are characterized by one parameter (E) and nucleophiles are characterized by the two solvent-dependent parameters N and sN. In this way, the organocatalysts A1-A32 were integrated in our comprehensive nucleophilicity scale, which compares n-, -, and σ-nucleophiles. The nucleophilic reactivities of the title compounds correlate only poorly with their Br?nsted basicities.
Selective hydrogenation of primary amides and cyclic di-peptides under Ru-catalysis
Subaramanian, Murugan,Sivakumar, Ganesan,Babu, Jessin K.,Balaraman, Ekambaram
supporting information, p. 12411 - 12414 (2020/10/30)
A ruthenium(II)-catalyzed selective hydrogenation of challenging primary amides and cyclic di-peptides to their corresponding primary alcohols and amino alcohols, respectively, is reported. The hydrogenation reaction operates under mild and eco-benign conditions and can be scaled-up.
Behind the Mirror: Chirality Tunes the Reactivity and Cytotoxicity of Chloropiperidines as Potential Anticancer Agents
Carraro, Caterina,Francke, Alexander,Sosic, Alice,Kohl, Franziska,Helbing, Tim,De Franco, Michele,Fabris, Daniele,G?ttlich, Richard,Gatto, Barbara
supporting information, p. 552 - 557 (2019/03/07)
The pressing demand for sustainable antitumor drugs prompted us to investigate 3-chloropiperidines as potential mustard-based anticancer agents. In this study, an explorative set of variously decorated monofunctional 3-chloropiperidines (M-CePs) was efficiently synthesized through a fast and affordable route providing high yields of pure racemates and enantiomers. Consistently with their reactivity, M-CePs were demonstrated to alkylate DNA in vitro. On a panel of carcinoma cell lines, M-CePs exhibited low nanomolar cytotoxicity indexes, which showed their remarkable activity against pancreatic cancer cells and in all cases performed strikingly better than the chlorambucil control. Very interestingly, stereochemistry modulated the activity of M-CePs in unexpected ways, pointing to additional molecular mechanisms of action beyond the direct damage of genomic DNA. This encouraging combination of efficacy and sustainability suggests they are valid candidates for anticancer agent development.
Pyrrolidine-Oxadiazolone Conjugates as Organocatalysts in Asymmetric Michael Reaction
Mahato, Chandan K.,Mukherjee, Sayan,Kundu, Mrinalkanti,Pramanik, Animesh
, p. 1053 - 1063 (2019/01/14)
Pyrrolidine-oxadiazolone based organocatalysts are envisaged, synthesized, and utilized for asymmetric Michael reactions. Results of the investigations suggest that some of the catalysts are indeed efficient for stereoselective 1,4-conjugated Michael additions (dr: >97:3, ee up to 99%) in high chemical yields (up to 97%) often in short reaction time. As an extension, one enantiopure Michael adduct has been utilized to synthesize optically active octahydroindole.
