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- Published 18 Apr 2019
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Scheme 1: Chiral biphenyl diol organocatalysts 1–6.
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Scheme 2: Synthesis of 3.
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Figure 1: (a) Single crystal X-ray structure of 3: showing intra- and intermolecular hydrogen bonds (green da...
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Scheme 3: Synthesis of 4.
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Scheme 4: Synthesis of 6.
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Figure 2: X-ray crystal structure of (P)-(S,S)-6 at two different orientations to show (a) P atropselectiviti...
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Figure 1: Tetravalent XB acceptor, Hex-NARBr 1, Cy-NARCl 2, divalent XB donor DIOFB, and guests MeCN, MeOH an...
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Figure 2: The previously reported halogen-bonded complexes CHCl3@1&DIOFB (a), and MeOH@1&DIOFB (b). (c)The fi...
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Figure 3: The two dimerization modes in the MeOH-MeCN@1&DIOFB complex. In both modes, the cavities are shown ...
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Figure 4: (a) The halogen bonding (blue broken lines), hydrogen bonding (red broken lines) and the host–guest...
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Figure 5: 19F NMR in CDCl3 at 298 K of: a) DIOFB (10 mM); b) 1:2 mixture of DIOFB and 1; 1:2:1 mixture of DIO...
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Figure 6: 1H NMR in CDCl3 at 298 K of: a) 1 (10 mM), b) 1:2 mixture of 1 and DIOFB, c) 1:2:1 mixture of 1, DI...
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- Published 17 Apr 2019
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Figure 1: Structure of the β-thiols 1a and 1b and of the commercial alkenes 2a and 2b.
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Scheme 1: Synthesis of the n-alkyl thioglycosides 3–5, 7 and 8. Detailed reaction conditions are reported in ...
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Scheme 2: Synthesis of the lipophilic scaffold 6; DMAP = N,N-dimethylaminopyridine.
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Figure 2: Periodic monitoring by 1H NMR (300 MHz, DMF-d7) of the formation of product 8 from a mixture compou...
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Figure 3: Micrographs of giant vesicles and lipid aggregates obtained from the gentle hydration (in PBS, pH 7...
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Figure 4: A simplified (and not in scale) representation of the ELLA assay, to study the interaction between ...
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Figure 5: Inhibition curves for the binding of WGA-HRP to PAA-GlcNAc by D-GlcNAc The symbols (■), (
![[Graphic 2]](/bjoc/content/inline/1860-5397-15-90-i4.svg?max-width=637&scale=0.472728)
) and (○) ...
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Figure 6: Main poses obtained from docking experiments. WGA (PDB 2UVO) surface is shown in white for monomer ...
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- Letter
- Published 16 Apr 2019
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Scheme 1: The reaction of CSI with olefins.
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Figure 1: The dipolar intermediate formed in the reaction of CSI with olefins.
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Scheme 2: The synthesis of imide 9.
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Scheme 3: The synthesis of ylidene sulfamoyl chloride 10.
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Figure 2: (a) Molecular structure of racemic molecule 10 (asymmetric unit). Thermal ellipsoids are drawn at t...
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Scheme 4: Mechanism for the formation of ylidenesulfamoyl chloride 10.
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Figure 3: Relative energy profile of the reaction mechanism shown in Scheme 4.
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Synthesis of (macro)heterocycles by consecutive/repetitive isocyanide-based multicomponent reactions
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- Published 15 Apr 2019
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Scheme 1: Comparison between a normal sequential reaction and an MCR.
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Scheme 2: Synthesis of tetrazoles and hydantoinimide derivatives by consecutive Ugi reactions [17].
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Scheme 3: Synthesis of tetrazole-ketopiperazines by two consecutive Ugi reactions [19].
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Scheme 4: Synthesis of acylhydrazino bis(1,5-disubstituted tetrazoles) through two hydrazine-Ugi-azide reacti...
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Scheme 5: Synthesis of substituted α-aminomethyltetrazoles through two consecutive Ugi reactions (U-4CR and U...
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Scheme 6: Synthesis of tetrazole peptidomimetics by direct use of amino acids in two consecutive Ugi reaction...
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Scheme 7: One-pot 8CR based on 3 sequential IMCRs [25].
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Scheme 8: Combination of IMCRs for the synthesis of substituted 2H-imidazolines [25].
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Scheme 9: 6CR involving a tandem combination of Groebke–Blackburn–Bienaymé and Ugi reaction for the synthesis...
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Scheme 10: 5CR involving a tandem combination of Groebke–Blackburn–Bienaymé and Passerini reaction for the syn...
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Scheme 11: Synthesis of tubugis via three consecutive IMCRs [27].
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Scheme 12: Synthesis of telaprevir through consecutive IMCRs [28].
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Scheme 13: Another synthesis of telaprevir through consecutive IMCRs [29].
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Scheme 14: a) Synthetic sequence for accessing diverse macrocycles containing the tetrazole nucleus by the uni...
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Scheme 15: a) Synthetic sequence for the tetrazolic macrocyclic depsipeptides using a combination of two IMCRs...
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Scheme 16: Synthesis of cyclic pentapeptoids by consecutive Ugi reactions [32].
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Scheme 17: Synthesis of a cyclic pentapeptoid by consecutive Ugi reactions [32].
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Scheme 18: MW-mediated synthesis of a cyclopeptoid by consecutive Ugi reactions [33].
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Scheme 19: Synthesis of six cyclic pentadepsipeptoids via consecutive isocyanide-based IMCRs [34].
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Scheme 20: Microwave-mediated synthesis of a cyclic heptapeptoid through four consecutive IMCRs [35].
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Scheme 21: Macrocyclization of bifunctional building blocks containing diacid/diisonitrile and diamine/diisoni...
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Scheme 22: Synthesis of steroid-biaryl ether hybrid macrocycles by MiBs [38].
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Scheme 23: Synthesis of biaryl ether-containing macrocycles by MiBs [39].
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Scheme 24: Synthesis of natural product-inspired biaryl ether-cyclopeptoid macrocycles [40].
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Scheme 25: Synthesis of cholane-based hybrid macrolactams by MiBs [41].
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Scheme 26: Synthesis of macrocyclic oligoimine-based DCL using the Ugi-4CR-based quenching approach [42].
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Scheme 27: Dye-modified and photoswitchable macrocycles by MiBs [43].
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Scheme 28: Synthesis of nonsymmetric cryptands by two sequential double Ugi-4CR-based macrocyclizations [44].
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Scheme 29: Synthesis of steroid–aryl hybrid cages by sequential 2- and 3-fold Ugi-4CR-based macrocyclizations [46]....
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Scheme 30: Ugi-MiBs approach towards natural product-like macrocycles [47].
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Scheme 31: a) Bidirectional macrocyclization of peptides by double Ugi reaction. b) Ugi-4CR for the generation...
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Scheme 32: MiBs based on the Passerini-3CR for the synthesis of macrolactones [49].
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Scheme 33: Template-driven approach for the synthesis of macrotricycles 170 [50].
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- Letter
- Published 12 Apr 2019
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Scheme 1: Reaction scheme for the one-pot reaction of C60Cl6 to produce Janus-type fullerenols (OH)19+/−3C60(...
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Figure 1: Characterization of fullerenol amphiphile with substituent 1. a) ESIMS in positive mode, molecular ...
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- Published 12 Apr 2019
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Figure 1: A generalized overview of coordination-driven self-assembly.
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Figure 2: Examples of self-assembly or self-sorting and subsequent substitution.
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Figure 3: Synthesis of salen-type ligand followed by metal-complex formation in the same pot [55].
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Figure 4: Otera’s solvent-free approach by which the formation of self-assembled supramolecules could be acce...
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Figure 5: Synthesis of a Pd-based metalla-supramolecular assembly through mechanochemical activation for C–H-...
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Figure 6: a) Schematic representation for the construction of a [2]rotaxane. b) Chiu’s ball-milling approach ...
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Figure 7: Mechanochemical synthesis of the smallest [2]rotaxane.
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Figure 8: Solvent-free mechanochemical synthesis of pillar[5]arene-containing [2]rotaxanes [61].
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Figure 9: Mechanochemical liquid-assisted one-pot two-step synthesis of [2]rotaxanes under high-speed vibrati...
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Figure 10: Mechanochemical (ball-milling) synthesis of molecular sphere-like nanostructures [63].
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Figure 11: High-speed vibration milling (HSVM) synthesis of boronic ester cages of type 22 [64].
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Figure 12: Mechanochemical synthesis of borasiloxane-based macrocycles.
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Figure 13: Mechanochemical synthesis of 2-dimensional aromatic polyamides.
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Figure 14: Nitschke’s tetrahedral Fe(II) cage 25.
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Figure 15: Mechanochemical one-pot synthesis of the 22-component [Fe4(AD2)6]4− 26, 11-component [Fe2(BD2)3]2− ...
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Figure 16: a) Subcomponent synthesis of catalyst and reagent and b) followed by multicomponent reaction for sy...
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Figure 17: A dynamic combinatorial library (DCL) could be self-sorted to two distinct products.
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Figure 18: Mechanochemical synthesis of dynamic covalent systems via thermodynamic control.
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Figure 19: Preferential formation of hexamer 33 under mechanochemical shaking via non-covalent interactions of...
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Figure 20: Anion templated mechanochemical synthesis of macrocycles cycHC[n] by validating the concept of dyna...
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Figure 21: Hydrogen-bond-assisted [2 + 2]-cycloaddition reaction through solid-state grinding. Hydrogen-bond d...
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Figure 22: Formation of the cage and encapsulation of [2.2]paracyclophane guest molecule in the cage was done ...
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Figure 23: Formation of the 1:1 complex C60–tert-butylcalix[4]azulene through mortar and pestle grinding of th...
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Figure 24: Formation of a 2:2 complex between the supramolecular catalyst and the reagent in the transition st...
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Figure 25: Halogen-bonded co-crystals via a) I···P, b) I···As, and c) I···Sb bonds [112].
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Figure 26: Transformation of contact-explosive primary amines and iodine(III) into a successful chemical react...
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Figure 27: Undirected C–H functionalization by using the acidic hydrogen to control basicity of the amines [114]. a...
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- Full Research Paper
- Published 11 Apr 2019
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Figure 1: Selected examples of bioactive molecules based on the pyrazolopyridine framework.
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Scheme 1: Synthesis of pyrazolopyridines containing chromone 4a–m through a multicomponent reaction.
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Figure 2: ORTEP Structure of compound 4a and intermolecular hydrogen bonding; the ellipsoid probability level...
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Figure 3: Structures of synthesized pyrazolopyridines 4a–m. Reaction conditions: 3-formylchromone derivatives...
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Scheme 2: The proposed mechanism for the synthesis of pyrazolopyridines derivatives 4a–m and 5a–d.
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Figure 4: Structures of synthesized compounds 5a–d.
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- Published 10 Apr 2019
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Scheme 1: Photochemical generation of TEMPO radical.
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Scheme 2: Synthesis of caged nitroxides 2a and 2b.
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Figure 1: Photochemical generation of TEMPO from 2a and 2b. EPR spectra acquired during the photolysis of 2a ...
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Figure 2: Time profile for photochemical generation of TEMPO radical from 2 (5 mM) at ≈298 K in benzene: (a) ...
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Scheme 3: Photochemical generation of TEMPO radical and photoproducts 6 and 7 under air atmosphere.
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Figure 3: Time profile, ln([2a]/[2a]0) versus irradiation time, of two-photon uncaging reaction of TEMPO in t...
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Figure 4: ESR spectra acquired during the photolysis of 2a (5 mM) in benzene using 365 nm light.
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Scheme 4: Isodesmic reaction from BRa and 5b to 5a and BRb.
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Figure 5: Irradiation time-dependent decline in viability of LLC cells with compound 2a.
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Figure 6: Detection of intracellular ROS only in irradiated LLC cells with 2a-containing medium.
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- Published 09 Apr 2019
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Figure 1: Structures of the sesquiterpene (−)-isoguaiene (1) and the trisnorsesquiterpene clavukerin A (2).
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Scheme 1: Retrosynthetic analysis for (−)-isoguaiene (1).
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Scheme 2: Synthesis of 1 by relay metathesis of trienyne 3. a) HC(OMe)3, 4 mol % LiBF4, MeOH, reflux, 80%; b)...
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Scheme 3: Attempted preparation of 1 by domino metathesis of enediyne 7. a) (i) O3, CH2Cl2, MeOH, pyridine, −...
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Scheme 4: Conversion of 28 to 1 by relay metathesis of dienediyne 8. a) (i) 21, THF, rt to reflux, (ii) BuLi,...
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- Published 04 Apr 2019
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Scheme 1: Synthesis of amino acid-based isocyanides starting from α-amino acids.
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Scheme 2: Synthesis of pseudo-peptides using levulinic acid, isocyanide esters and amines.
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Figure 1: Synthesis of functionalized 5-membered lactams using Ugi reaction. aIsolated yield for mixture of d...
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Scheme 3: Proposed mechanism for Ugi-4C-3CR.
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Figure 2: ORTEP representation of compound (R*,S*)-4a with thermal ellipsoids at 50% probability. Opposite en...
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Figure 1: Left: Mixed ligand complexes of the type [M2L(μ-L')]n+ supported by the macrocyclic ligand H2L (M =...
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Figure 2: Synthesized compounds and their labels.
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Scheme 1: Synthesis of complexes 1–9.
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Figure 3: 1H NMR spectrum of 6 in CD3CN at 295 K (1.0–8.0 ppm). The resonances and assignments are listed in Table 2...
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Figure 4: Structure of the [Zn2L(μ-azo-OH)]+ cation in crystals of [Zn2L(μ-azo-OH)][Zn2L(μ-azo-O)]·4MeCN·3H2O...
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Figure 5: Space filling representation of the packing of two symmetry-related [Zn2L(μ-azo-NMe2)]+ cations in ...
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Figure 6: Structure of the [Cd2L(μ-azo-NMe2)]+ cation in crystals of [Cd2L(μ-azo-NMe2)]ClO4·0.5MeOH (6·0.5MeO...
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Figure 7: Space filling representation of the packing of four [Cd2L(μ-azo-NMe2)]+ cations in crystals of 6·0....
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Figure 8: Structures of the two crystallographically independent [Ni2L(μ-azo-NMe2)]+ cations A (left) and B (...
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Figure 9: Left: ORTEP representation of the molecular structure of the [Cd2L(μ-azo-CO2Me)]+ cation in crystal...
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Figure 10: Plots of the effective magnetic moment μeff for 2 (open circles), 4 (open squares), and 7 (open tri...
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Figure 11: UV–vis spectra of Hazo-H (red line), [Cd2L(μ-Cl)](ClO4) (black line) and [Cd2L(μ-azo-H)]ClO4 (1, bl...
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Figure 12: UV–vis spectra of Hazo-NMe2 (red line), [Ni2L(μ-Cl)](ClO4) (black line) and [Ni2L(μ-azo-NMe2)]ClO4 (...
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Figure 13: UV–vis spectra of solutions of [Cd2L(μ-azo-H)]ClO4 (1) in acetonitrile irradiated with a UV LED lam...
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Scheme 2: Cis/trans isomerization process of the bound azo-carboxylato co-ligand in [Cd2L(μ-azo-H)]ClO4 (1) i...
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- Published 01 Apr 2019
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Figure 1: Schematic cone-shaped (a) and structure representations (b) of α-CD (six glucopyranoside units) and...
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Figure 2: Common cinchona alkaloids (cinchonine, cinchonidine, quinine, quinidine).
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Scheme 1: CuAAC click reaction of propargylated cinchona alkaloids 3a–d with 6I-azido-6I-deoxy-α-CD (1) and 6I...
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Scheme 2: CuAAC click reaction of per-Me-N3-α-CD (6) or per-Me-N3-β-CD (7) and propargylated cinchona alkaloi...
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Scheme 3: Synthesis of difunctionalized α-CD 11 with quinine moieties.
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Figure 3: Representative 1H NMR spectrum of the non-methylated quinidine–α-CD derivative 4d.
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Figure 4: Representative 13C NMR spectrum and parts of the HMBC spectrum of the non-methylated quinidine–α-CD...
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Scheme 4: AAA reaction of MBH carbamate 12 catalyzed by the prepared CD derivatives 4a–d, 5a–d, 8a–d, 9a–d, 11...
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Figure 1: Conformations of cis-2-halocyclohexylamines, where X = F, Cl, Br and I.
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Figure 2: Variable-temperature 1H NMR spectra (500.13 MHz) for cis-2-chlorocyclohexylamine in dichloromethane-...
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Figure 3: Potential energy surfaces (PESs) for cis-2-halocyclohexylamines for the C2–C1–N–H dihedral angle ro...
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Figure 4: Populations of rotamers a, gX e gH in ae (top) and ea (bottom) conformers of cis-2-halocyclohexylam...
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Figure 5: Nitrogen lone pair in rotamers gX (ae) and a (ea) oriented towards the halogen, making these rotame...
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Figure 6: PCA for 22 variables corresponding to the hyperconjugative interactions for all rotamers in ae and ...
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Figure 7: Sum of bonding (donor) and antibonding (acceptor) orbitals interactions of C1–H, C2–X and C3–Hax bo...
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Figure 8: Orbitals overlap of σC1–H → σ*C2–X (left) and σC3–Hax → σ*C2–X (right) hyperconjugations in ea conf...
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- Published 29 Mar 2019
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Figure 1: Biologically relevant molecules made, used or derivatized by mechanochemistry.
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Figure 2: Isomeric diacyl-sn-glycerols (DAGs).
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Scheme 1: Synthetic route to access protected DAGs; PG = protecting group.
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Scheme 2: Protection of glycidol (1) with TBDMSCl in the ball mill. MM = mixer mill, PBM = planetary ball mil...
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Scheme 3: Cobalt-catalyzed epoxide ring-opening in the ball mill.
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Scheme 4: Mechanosynthesis of DAGs 5.
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Scheme 5: Conjugation of DAG 5a with 7-hydroxycoumarin (9).
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Figure 3: UV−vis spectra of DAG 6a (dotted line) and conjugated DAGs 10a and 10a’ as a mixture (10a/10a’ 72:2...
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Figure 1: Adefovir (1) and its prodrug 2.
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Scheme 1: Literature syntheses of 1.
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Figure 2: Retrosynthetic analysis of 6 to synthons 9 and 10.
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Scheme 2: Forward synthesis of 6 from 9 and 10.
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Figure 3: Retrosynthesis of 6 to synthons 14 and 3.
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Scheme 3: Application of related alkyl iodide 15 [52].
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Scheme 4: Synthesis of 6 and 20 via iodide 14.
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Scheme 5: Synthesis of phosphonate 6 using novel salt 21.
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Scheme 6: Application of iodide 14 in the synthesis of adefovir analogues.
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Figure 4: HMBC spectrum confirms N7-selectivity for the major product 29.
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Scheme 7: Attempted synthesis of adefovir dipivoxil (2) exploiting phosphonate 33.
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- Published 28 Mar 2019
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Scheme 1: Reaction design.
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Scheme 2: Scope of electrochemical synthesis of axially chiral biaryls. Reaction conditions: undivided cell, 2...
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Scheme 3: Proposed reaction mechanism for the electrochemical synthesis of 3a.
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Scheme 4: Computation investigation on the vinyl radical cyclization. DFT (M06-2X/6-31G*) calculated energeti...
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- Published 27 Mar 2019
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Figure 1: Structures of achiral terpenes: (E)-β-farnesene (1), α-humulene (2), 1,8-cineol (3) and sodorifen (4...
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Figure 2: A) Total ion chromatogram of a hexane extract from the incubation of FPP with BbS and B) EI mass sp...
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Scheme 1: Cyclisation mechanism to 5 involving either the intermediates (R)-NPP and (S)-A (path A) or (S)-NPP...
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Figure 3: Total ion chromatograms of hexane extracts from incubation experiments with BbS and A) (R)-NPP, B) (...
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Figure 4: Hypothetical BbS active site comparable conformational folds of A) FPP, B) (R)- and C) (S)-NPP expl...
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Scheme 1: Approach of the direct azologization of reported [60,61] serotonin 5-HT3R antagonists via replacement of a...
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Scheme 2: Synthesis of the differently substituted quinoxaline azobenzene derivatives 5a and 5b via Baeyer [62]–M...
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Scheme 3: Synthesis of the methoxy-substituted quinoxaline derivative 12a via diazotization [66-69].
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Scheme 4: General procedure for the synthesis of purine- and thienopyrimidine-substituted arylazobenzenes and...
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Scheme 5: Synthesis of the thiomethyl-linked purine azobenzene 23 [62,63,72-74].
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Scheme 6: Synthesis of the amide-linked azobenzene purine 28 [62,63,75-77].
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Figure 1: UV–vis absorption spectra measured at 50 µM in DMSO. Left: purine derivative 16c; right: azo-extend...
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Figure 2: On the left panel representative traces of currents induced by the application of 3 µM 5HT (black t...
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Figure 1: Commercially available ruthenium catalysts for metathesis reactions.
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Figure 2: Retrosynthesis of the ruthenium catalysts.
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Scheme 1: Efficient multigram synthesis of N,N-dialkyl-2-vinylbenzylamines 4 (R1X = Me2SO4, Et2SO4 or BnCl, s...
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Scheme 2: Synthesis of N-(2-ethenylbenzyl)heterocycles 5.
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Scheme 3: Synthesis of N-monoalkyl-2-vinylbenzylamine 7.
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Scheme 4: Synthesis of Hoveyda–Grubbs-type catalysts 11.
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Scheme 5: Synthesis of the “chloroform adduct” 9.
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Figure 3: Selected X-ray data for ruthenium complexes 11a–c. All hydrogen atoms were deleted for clarity (exc...
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Scheme 6: Catalytic activity of compounds 11 in the metathesis reactions.
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Figure 1: Structure of biaryl bicyclic peptides 1–3.
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Scheme 1: Retrosynthetic analysis for the biaryl bicyclic peptide 1.
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Scheme 2: Synthesis of the biaryl bicyclic peptide 1 incorporating a Phe-Phe linkage. Reagents and conditions...
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Scheme 3: Synthesis of the biaryl bicyclic peptide 2 incorporating a Phe-Tyr linkage. Reagents and conditions...
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Scheme 4: Synthesis of the biaryl bicyclic peptide 3 incorporating a Tyr-Tyr linkage. Reagents and conditions...
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Scheme 1: Various strategies leading to the formation of cyclopropanols.
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Scheme 2: General approach to the preparation of cyclopropanol and cyclopropylamine derivatives.
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Figure 1: Prerequisite for a regio- and diastereoselective carbometalation.
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Scheme 3: Preparation of cyclopropenyl methyl ethers 3a–d.
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Scheme 4: Regio- and diastereoselective carbocupration of cyclopropenyl methyl ethers 3a,c.
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Scheme 5: Diastereoselective formation of cyclopropanols.
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Scheme 6: Diastereoselective carbometalation/oxidation of nonfunctionalized cyclopropenes 6.
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Scheme 7: Preparation of diastereoisomerically pure and enantioenriched cyclopropanols and cyclopropylamines.
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Figure 1: Reagents for acetal protections.
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Scheme 1: Synthesis of 2-alkoxyprop-2-yl-protected thymidines. Reagents and conditions (i) 7 equiv 1a–e, 0.5 ...
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Figure 2: Enol ether 8a: R1 = TBS and 8b: R1 = H.
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Scheme 2: Proposed acetal hydrolysis pathways.
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Figure 1: Absorption spectra in the UV and visible spectral region: 1) bis(cyclopentadienyl)titan dichloride (...
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Figure 2: Absorption spectra in the visible spectral region: 1) Cp2TiCl2·AlEt2Cl (toluene, 10 mmol/L, Ti/Al r...
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Figure 3: 1Н NMR spectra of tricyclopentadiene (a) and the interaction product between Cp2TiCl2 and AlEt2Cl w...
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Scheme 1: Mechanism of alkylation of Cp2TiCl2.
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Figure 4: Visible spectra of a mixture of Cp2TiCl2 and AlEt2Cl as function of time.
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Figure 5: Thermometric curve of DCPD polymerization using the catalyst system based on Cp2TiCl2 (a) and its s...
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Scheme 2: The structures formed as a result of the cationic polymerization of dicyclopentadiene.
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Scheme 3: The units resulting from ROMP of dicyclopentadiene.
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Scheme 4: Mechanism of ROMP dicyclopentadiene.
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Figure 6: FTIR spectrum of PDCPD obtained in toluene with the catalyst system based on Cp2TiCl2 and AlEt2Cl.
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Figure 7: 1Н NMR spectrum of PDCPD obtained with the catalytic system based on Cp2TiCl2 and AlEt2Cl.
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Figure 8: GPC traces for two samples of DCPD polymers obtained at a concentration of Cp2TiCl2/AlEt2Cl complex...
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Figure 9: IR spectra of cationic polymerized dicyclopentadiene taken after certain periods of time exposed to...
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Figure 10: Correlation of intensities of vibrational bands at 1620 and 700 cm−1 and layer exposure time in air...
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Figure 11: DSC exotherm for PDCPD subjected to air oxidation for 700 hours.
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Figure 12: DSC exotherm for PDCPD subjected to unexposed film: 1) in air atmosphere; 2) in argon.
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Scheme 5: Possible radical formation in the reaction (1).
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Scheme 6: The first step of the chain propagation.
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Figure 13: Dependence of intensities of adsorption bands at 1410 and 700 cm−1 and dwell time of the layer in a...
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Figure 14: Semi-logarithmic kinetic curve of PDCPD oxidation in air (thin layer on silicon) with respect to in...
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Figure 15: The distribution of oxygen concentration in the polymer layer: 1 – a layer of oxidized cross-linked...
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Figure 16: Dependence of the ratio of adsorption bands at 1700 and 700 cm−1 on the exposure time of the layer ...
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Figure 17: Infrared spectra (a) of products of cationic polymerization of DCPD, stabilized with an antioxidant...
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Figure 1: (a) Isomerization of parent diazocine 1. Distances of carbon atoms para to the ethylene bridge were...
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Figure 2: Synthesized target diazocines 4–7 for applications in responsive materials.
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Scheme 1: Key reactions in diazocine synthesis.
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Scheme 2: Syntheses of the functionalized diazocines 4–7. Reaction conditions: i) Isobutylene, sulfuric acid,...
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Figure 3: UV–vis spectra of 3,3’-diaminodiazocine 2 (left), 3,3’-di(aminomethyl)diazocine 6a (center), and 3,...
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