Mona Sharafi scite author profile

Chirality-assisted synthesis (CAS) is a general approach to control the shapes of large molecular strips. CAS is based on enantiomerically pure building blocks that are designed to strictly couple in a single geometric orientation. Fully shape-persistent structures can thus be created, even in the form of linear chains. With CAS, selective recognition between large host and guest molecules can reliably be designed de novo. To demonstrate this concept, three C-shaped strips that can embrace a pillar[5]arene macrocycle were synthesized. The pillar[5]arene bound to the strips was a better host for electron-deficient guests than the free macrocycle. Experimental and computational evidence is provided for these unique cooperative interactions to illustrate how CAS could open the door towards the precise positioning of functional groups for regulated supramolecular recognition and catalysis.

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Anodic Methods for Covalent Attachment of Ethynylferrocenes to Electrode Surfaces: Comparison of Ethynyl Activation Processes

Sheridan

Lam

Sharafi

et al. 2016

Langmuir

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The electrochemical oxidation of ferrocenes having an H- or Li-terminated ethynyl group has been studied, especially as it relates to their covalent anchoring to carbon surfaces. The anodic oxidation of lithioethynylferrocene (1-Li) results in rapid loss of Li(+) and formation of the ethynyl-based radical FeCp(η(5)-C5H4)(C≡C), (1, Cp = η(5)-C5H5), which reacts with the electrode. Chemically modified electrodes (CMEs) were thereby produced containing strongly bonded, ethynyl-linked monolayers and electrochemically controlled multilayers. Strong attachments of ethynylferrocenes to gold and platinum surfaces were also possible. The lithiation/anodic oxidation process is a mirror analogue of the diazonium/cathodic reduction process for preparation of aryl-modified CMEs. A second method produced an ethynylferrocene-modified electrode by direct anodic oxidation of the H-terminated ethynylferrocene (1-H) at a considerably more positive potential. Both processes produced robust modified electrodes with well-defined ferrocene-based surface cyclic voltammetry waves that remained unchanged for as many as 10(4) scans. Ferrocene derivatives in which the ethynyl moiety was separated from the cyclopentadienyl ring by an ether group showed very similar behavior. DFT calculations were performed on the relevant redox states of 1-H, 1-Li, and 1, with emphasis on the ferrocenyl vs ethynyl character of their high valence orbitals. Whereas the HOMOs of both 1-H and 1-Li have some ethynyl character, the SOMOs of the corresponding monocations are strictly ferrocenium in makeup. Predominant ethynyl character returns to the highest valence orbitals after loss of Li(+) from [1-Li](+) or loss of H(+) from [1-H](2+). These anodic processes hold promise for the controlled chemical modification of carbon and other electrode surfaces by a variety of ethynyl or alkynyl-linked organic and metal-containing systems.

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Size-Selective Catalytic Polymer Acylation with a Molecular Tetrahedron

Sharafi

McKay

Ivancic

et al. 2020

Chem

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We report an original catalytic molecular tetrahedron. By threading through the cavity of the tetrahedron, polymeric substrates are unfolded or broken apart. Our catalyst distinguishes between polymer chains of different lengths, functionalizing the shorter polymers selectively over the longer ones-as a proof of concept for selective catalysis to modify polymers. Our findings advance the fundamental understanding of the thermodynamic and kinetic phenomena controlling the interactions between molecular cages and synthetic polymers, offering valuable ability to create complex materials in the future.

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Glutathione-S-transferase P promotes glycolysis in asthma in association with oxidation of pyruvate kinase M2

et al. 2021

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Enantioselective Electrophilic Aromatic Nitration: A Chiral Auxiliary Approach

et al. 2018

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Enantioselective electrophilic aromatic nitration methodology is needed to advance chirality-assisted synthesis (CAS). Reported here is an enantioselective aromatic nitration strategy operating with chiral diester auxiliaries,and it provides an enantioselective synthesis of aC 3v -symmetric tribenzotriquinacene (TBTQ). These axially-chiral structures are much sought-after building blocks for CAS, but they were not accessible prior to this work in enantioenriched form without resolution of enantiomers.T his nitration strategy controls the stereochemistry of threefold nitration reactions from above the aromatic rings with chiral diester arms.Dicarbonyl-to-arenium chelation rigidifies the reaction systems,s ot hat remote stereocenters position the ester-directing groups selectively over specific atoms of the TBTQ framework. Closely guided by computational design, am ore selective through-space directing arm was first predicted with density functional theory (DFT), and then confirmed in the laboratory,t o outperform the initial structural design. This enantio-and regioselective TBTQ synthesis opens anew pathwaytoaccess building blocks for CAS.Classical electrophilic aromatic nitration reactions are among the best known and most frequently employed aromatic transformations. [1] They readily proceed [2] with unactivated aromatic substrates and provide exquisite control over the number of NO 2 groups introduced, unlike for instance most Friedel-Crafts alkylations and aromatic brominations. [1b-d, 3] Nevertheless,r esolution-free,e nantioselective electrophilic aromatic nitration processes (even with chiral auxiliaries) have yet to be reported. While enantioselective Friedel-Crafts-type reactions [4] and enantioselective aromatic brominations [5] have been studied extensively,o nly the enantioselective nitration of crotylsilanes, [6] but not of aromatic substrates,h as been described.To advance the growing field of chirality-assisted synthesis [7] (CAS), we now describe an enantioselective nitration strategy which makes use of chiral diester auxiliaries with remote stereocenters to induce axial chirality upon trifold nitration. We employ our chiral auxiliaries to achieve the first enantioselective synthesis of a C 3v -symmetric tribenzotriqui-nacene (TBTQ) [8] derivative,w hich is not based on either ak inetic, [9] crystallization-based, [10] or chromatographic [11] resolution. Directing arms with remote stereocenters are positioned at equal distances from the favored and disfavored sites of reactivity to provide for an enantioselective nitration methodology after removal (Figure 1b)ofthe through-space directing groups.T he success of our strategy stems from 1) chelation (Figure 1b)o ft wo ester carbonyl groups to the cationic Wheland intermediates positioned underneath these diester directing arms as well as 2) A 1, 3 strain (Figure 3b), which can be controlled by the size of the alkyl substituents attached to the remote chirality centers of the through-space directing groups.T his combination of A 1,3 strain with ...

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Mona Sharafi

Regulating Molecular Recognition with C‐Shaped Strips Attained by Chirality‐Assisted Synthesis

Anodic Methods for Covalent Attachment of Ethynylferrocenes to Electrode Surfaces: Comparison of Ethynyl Activation Processes

Size-Selective Catalytic Polymer Acylation with a Molecular Tetrahedron

Glutathione-S-transferase P promotes glycolysis in asthma in association with oxidation of pyruvate kinase M2

Enantioselective Electrophilic Aromatic Nitration: A Chiral Auxiliary Approach

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