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1. gem-Difluoroallylation of Aryl Halides and Pseudo Halides with Difluoroallylboron Reagents in High Regioselectivity

   https://doi.org/10.1002/anie.202111476  

   Sakamoto, Shu; Butcher, Trevor W.; Yang, Jonathan L.; Hartwig, John F. (October 2021, Angewandte Chemie)

   We report the palladium-catalyzed gem-difluoroallylation of aryl halides and pseudo halides with 3,3-difluoroallyl boronates in high yield with high regioselectivity, and we report the preparation of the 3,3-difluoroallyl boronate reactants by a copper-catalyzed defluorinative borylation of inexpensive gaseous 3,3,3-trifluoropropene with bis(pinacola-to) diboron. The gem-difluoroallylation of aryl and heteroaryl bromides proceeds with low catalyst loading (0.1 mol% [Pd]) and tolerates a wide range of functional groups, including primary alcohols, secondary amines, ethers, ketones, esters, amides, aldehydes, nitriles, halides, and nitro groups. This protocol extends to aryl iodides, chlorides, and triflates, as well as substituted difluoroallyl boronates, providing a versatile synthesis of gem-difluoroallyl arenes that we show to be valuable intermediates to a series of fluorinated building blocks 

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2. A Hammett Study of Clostridium acetobutylicum Alcohol Dehydrogenase (CaADH): An Enzyme with Remarkable Substrate Promiscuity and Utility for Organic Synthesis

   https://doi.org/10.1055/s-0039-1691576  

   Kudalkar, Gaurav P.; Tiwari, Virendra K.; Lee, Joshua D.; Berkowitz, David B. (January 2020, Synlett)

   Described is a physical organic study of the reduction of three sets of carbonyl compounds by the NADPH-dependent enzyme Clostridium acetobutylicum alcohol dehydrogenase (CaADH). Previous studies in our group have shown this enzyme to display broad substrate promiscuity, yet remarkable stereochemical fidelity, in the reduction of carbonyl compounds, including α-, β- and γ-keto esters (d-stereochemistry), as well as α,α-difluorinated-β-keto phosphonate esters (l-stereochemistry). To better mechanistically characterize this promising dehydrogenase enzyme, we report here the results of a Hammett linear free-energy relationship (LFER) study across three distinct classes of carbonyl substrates; namely aryl aldehydes, aryl β-keto esters and aryl trifluoromethyl ketones. Rates are measured by monitoring the decrease in NADPH fluorescence at 460 nm with time across a range of substrate concentrations for each member of each carbonyl compound class. The resulting v 0 versus [S] data are subjected to least-squares hyperbolic fitting to the Michaelis–Menton equation. Hammett plots of log(V max) versus σX yield the following Hammett parameters: (i) for p-substituted aldehydes, ρ = 0.99 ± 0.10, ρ = 0.40 ± 0.09; two domains observed, (ii) for p-substituted β-keto esters ρ = 1.02 ± 0.31, and (iii) for p-substituted aryl trifluoromethyl ketones ρ = –0.97 ± 0.12. The positive sign of ρ indicated for the first two compound classes suggests that the hydride transfer from the nicotinamide cofactor is at least partially rate-limiting, whereas the negative sign of ρ for the aryl trifluoromethyl ketone class suggests that dehydration of the ketone hydrate may be rate-limiting for this compound class. Consistent with this notion, examination of the 13C NMR spectra for the set of p-substituted aryl trifluo­romethyl ketones in 2% aqueous DMSO reveals significant formation of the hydrate (gem-diol) for this compound family, with compounds bearing the more electron-withdrawing groups showing greater degrees of hydration. This work also presents the first examples of the CaADH-mediated reduction of aryl trifluoromethyl ketones, and chiral HPLC analysis indicates that the parent compound α,α,α-trifluoroacetophenone is enzymatically reduced in 99% ee and 95% yield, providing the (S)-stereoisomer, suggesting yet another compound class for which this enzyme displays high enantioselectivity. 

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3. Transition-State Stabilization by Secondary Orbital Interactions between Fluoroalkyl Ligands and Palladium During Reductive Elimination from Palladium(aryl)(fluoroalkyl) Complexes

   https://doi.org/10.1021/acscatal.3c02648  

   Kalkman, Eric D.; Qiu, Yehao; Hartwig, John F. (October 2023, ACS Catalysis)

   Palladium-catalyzed fluoroalkylations of aryl halides are valuable reactions for the synthesis of fluorinated, biologically active molecules. Reductive elimination from an intermediate Pd(aryl)(fluoroalkyl) complex is the step that forms the C(aryl)–C(fluoroalkyl) bond, and this step typically requires higher temperatures and proceeds with slower rates than the reductive elimination of nonfluorinated alkylarenes from the analogous Pd(aryl)(alkyl) complexes. The experimental rates of this step correlate poorly with common parameters, such as the steric property or the electron-withdrawing ability of the fluoroalkyl ligand, making the prediction of rates and the rational design of Pd-catalyzed fluoroalkylations difficult. Therefore, a systematic study of the features of fluoroalkyl ligands that affect the barrier to this key step, including steric properties, electron-withdrawing properties, and secondary interactions, is necessary for the future development of fluoroalkylation reactions that occur under milder conditions and that tolerate additional types of fluoroalkyl reagents. We report computational studies of the effect of the fluoroalkyl (RF) ligand on the barriers to reductive elimination from Pd(aryl)(RF) complexes (RF = CF2CN, CF2C(O)Me, etc.) containing the bidentate ligand di-tert-butyl(2-methoxyphenyl)phosphine (L). The computed Gibbs free-energy barriers to reductive elimination from these complexes suggest that fluoroalkylarenes should form quickly at room temperature for the fluoroalkyl ligands we studied, excluding RF = CF3, CF2Me, C2F5, CF2CFMe2, CF2Et, CF2iPr, or CF2tBu. Analyses of the transition-state structures by natural bond orbital (NBO) and independent gradient model (IGMH) approaches reveal that orbital interactions between the Pd center and a hydrogen atom or π-acid bonded to the α-carbon atom of the RF ligand stabilize the lowest-energy transition states of Pd(aryl)(RF) complexes. Comparisons between conformers of transition-state structures suggest that the magnitude of such stabilizations is 4.7–9.9 kcal/mol. In the absence of these secondary orbital interactions, a more electron-withdrawing fluoroalkyl ligand leads to a higher barrier to reductive elimination than a less electron-withdrawing fluoroalkyl ligand. Computations on the reductive elimination from complexes containing para-substituted aryl groups on palladium reveal that the barriers to reductive elimination from complexes containing more electron-rich aryl ligands tend to be lower than those to reductive elimination from complexes containing less electron-rich aryl ligands when the fluoroalkyl ligands of these complexes can engage in secondary orbital interactions with the metal center. However, the computed barriers to reductive elimination do not depend on the electronic properties of the aryl ligand when the fluoroalkyl ligands do not engage in secondary orbital interactions with the metal center. 

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4. Diastereoselective Synthesis of Aryl C ‐Glycosides from Glycosyl Esters via C−O Bond Homolysis

   https://doi.org/10.1002/anie.202014991  

   Wei, Yongliang; Ben‐zvi, Benjamin; Diao, Tianning (March 2021, Angewandte Chemie International Edition)

   Abstract C‐aryl glycosyl compounds offer better in vivo stability relative toO‐ andN‐glycoside analogues.C‐aryl glycosides are extensively investigated as drug candidates and applied to chemical biology studies. Previously,C‐aryl glycosides were derived from lactones, glycals, glycosyl stannanes, and halides, via methods displaying various limitations with respect to the scope, functional‐group compatibility, and practicality. Challenges remain in the synthesis ofC‐aryl nucleosides and 2‐deoxysugars from easily accessible carbohydrate precursors. Herein, we report a cross‐coupling method to prepareC‐aryl and heteroaryl glycosides, including nucleosides and 2‐deoxysugars, from glycosyl esters and bromoarenes. Activation of the carbohydrate substrates leverages dihydropyridine (DHP) as an activating group followed by decarboxylation to generate a glycosyl radical via C−O bond homolysis. This strategy represents a new means to activate alcohols as a cross‐coupling partner. The convenient preparation of glycosyl esters and their stability exemplifies the potential of this method in medicinal chemistry. 

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5. Selective Ni-Catalyzed Cross-Electrophile Coupling of Heteroaryl Chlorides and Aryl Bromides at 1:1 Substrate Ratio

   https://doi.org/10.1021/jacs.4c10776  

   Su, Zhi-Ming; Zhu, Jieru; Poole, Darren L; Rafiee, Mohammad; Paton, Robert S; Weix, Daniel J; Stahl, Shannon S (January 2025, Journal of the American Chemical Society)

   Nickel-catalyzed cross-electrophile coupling (XEC) reactions of (hetero)aryl electrophiles represent appealing alternatives to palladium-catalyzed methods for biaryl synthesis, but they often generate significant quantities of homocoupling and/or proto-dehalogenation side products. In this study, an informer library of heteroaryl chloride and aryl bromide coupling partners is used to identify Ni-catalyzed XEC conditions that access high selectivity for the cross-product when using equimolar quantities of the two substrates. Two different catalyst systems are identified that show complementary scope and broad functional-group tolerance, and time-course data suggest the two methods follow different mechanisms. A NiBr2/terpyridine catalyst system with Zn as the reductant converts the aryl bromide into an aryl-zinc intermediate that undergoes in situ coupling with 2-chloropyridines, while a NiBr2/bipyridine catalyst system with tetrakis(dimethylamino)ethylene as the reductant uses FeBr2 and NaI as additives to achieve selective cross-coupling. 

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