Syntheses and properties of tetraaza‐, diaza‐, tetraoxa‐, and dioxa‐metacyclophanes

Metacyclophanes were prepared by cyclization reactions between bis(chloromethyl) compounds and piperazine, primary amines, or ethylene glycol. The ¹H nmr relaxation time (T₁) measurements indicated that the macrocycles feature the up and down motion of the aromatic units around the XCH₂Ar (X = N, O) methylene moieties as the axes. Metacyclophanes incorporating piperazine units showed high complexation ability for alkaline metal cations.     

Synthesis and complexing properties of double armed diaza‐15‐crown‐5 and diaza‐18‐crown‐6 ethers having 4′‐hydroxy‐3′,5′‐disubstituted benzyl groups

A series of double armed diaza‐15‐crown‐5 ethers (9a ‐ 16a) and diaza‐18‐crown‐6 ethers (9b ‐ 16b) have been prepared by the Mannich reaction of 2,6‐disubstituted phenols with the corresponding N,N'‐dimethoxymethyldiaza‐crown ethers in benzene. The crystal structures of the diaza‐18‐crown‐6 ethers having iso‐propyl (10b) , tert‐butyl (11b) , and mixed methyl and tert‐butyl groups (12b) at positions 3′ and 5′ of the phenolic side arms were determined using X‐ray diffraction methods. Competitive transport by these ligands for sodium, potassium and cesium cations were measured under basic‐source phase and acidic‐receiving phase conditions.     

Potassium‐, Ammonium‐, Hydrazinium‐, Guanidinium‐, Aminoguanidinium‐, Diaminoguanidinium‐, Triaminoguanidinium‐ and Melaminiumnitroformate – Synthesis,Characterization and Energetic Properties

Energetic salts containing the nitroformate (trinitromethanide) anion with several nitrogen‐rich cations were investigated, including ammonium nitroformate (ANF), melaminium nitroformate (MNF), guanidinium nitroformate monohydrate (GNFH), aminoguanidinium nitroformate (AGNF), diaminoguanidinium nitroformate (DAGNF) as well as triaminoguanidinium nitroformate (TAGNF). All salts were characterized using vibrational spectroscopy (IR, Raman), mass spectrometry, multinuclear NMR spectroscopy and elemental analysis. The thermal decomposition of the salts was monitored using differential scanning calorimetry. In addition, the impact, friction and electrostatic sensitivity data were determined. Theoretical calculations were carried out in order to predict performance data such as detonation velocities and detonation pressures. The crystal structures of ANF, MNF, GNFH, AGNF, DAGNF and TAGNF were determined using single crystal X‐ray diffraction. In addition, a second polymorph of MNF was determined crystallographically as well as the crystal structures of MNF with methanol and MNF with dimethylsulfoxide. Finally, new polymorphs of potassium nitroformate (KNF) and hydrazinium nitroformate (HNF) were characterized using single crystal X‐ray diffraction.     

Synthesis and properties of oxygen‐, methylene‐, and alkylene‐bridged poly(dithiafulvene)s

Polymerization by cycloaddition between aldothioketene and its alkynethiol tautomer (derived in situ from a diyne) leading to the formation of dithiafulvene unit‐linked polymers has been studied. Two aromatic diynes [bis(4‐ethynyldiphenyl)methane ( 1a ) and 4,4′‐diethynyldiphenyl ether) ( 1b )] were used as starting materials with the aim of obtaining non‐π‐conjugated methylene‐ and oxygen‐bridged aromatic poly(dithiafulvene)s. The poly(dithiafulvene) derived from bis(4‐ethynyldiphenyl)methane can be considered as an interesting precursor to a small band‐gap polymer having alternating aromatic and quinonoid moieties. Further, two aliphatic diynes [1,7‐octadiyne ( 3a ) and 1,9‐decadiyne ( 3b )] were subjected to cycloaddition polymerization to obtain aliphatic poly(dithiafulvene)s containing localized electron‐rich dithiafulvene units. The polymers obtained were characterized by IR, ¹H NMR, gel permeation chromatography, and cyclic voltammetry. The electron‐donating property of the polymers was evident from the charge‐transfer (CT) complex formation with an electron acceptor 7,7,8,8‐teracyanoquinodimethane. The CT complexes were characterized by IR, ¹H NMR, and ultraviolet–visible spectroscopies. © 2001 John Wiley & Sons, Inc. J Polym Sci Part A: Polym Chem 39: 3593–3603, 2001     

Enantio‐, Regio‐, and Chemoselective Lipase‐Catalyzed Polymer Synthesis

In contrast to chemical routes, enzymatic polymerization possesses favorable characteristics of mild reaction conditions, few by‐products, and high activity toward cyclic lactones which make it a promising technique for constructing polymeric materials. Meanwhile, it can avoid the trace residue of metallic catalysts and potential toxicity, and thus exhibits great potential in the biomedical fields. More importantly, lipase‐catalyzed polymer synthesis usually shows favorable enantio‐, regio‐, and chemoselectivity. Here, the history and recent developments in lipase‐catalyzed selective polymerization for constructing polymers with unique structures and properties are highlighted. In particular, the synthesis of polymeric materials which are difficult to prepare in a chemical route and the construction of polymers through the combination of selective enzymatic and chemical methods are focused. In addition, the future direction is proposed especially based on the rapid developments in computational chemistry and protein engineering techniques.     

Synthesis,Characterization, and Crystal Structure of 1,3‐Dipentafluorophenyl‐2,2,2,4,4,4‐hexazido‐1,3‐diaza‐2,4‐diphosphetidine

1,3‐Dipentafluorophenyl‐2,2,2,4,4,4‐hexazido‐1,3‐diaza‐2,4‐diphosphetidine ( 1 ) was synthesized by the reaction of [(C₆F₅)NPCl₃]₂ with trimethylsilyl azide in CH₂Cl₂ and characterized by multinuclear NMR and vibrational spectroscopy. The molecular structure of the compound was determined by single‐crystal X‐ray structure analysis. [(C₆F₅)NP(N₃)₃]₂ crystallizes in the monoclinic space group P2₁/n with a = 9.6414(2), b = 7.4170(1) and c = 15.9447(4) Å, β = 94.4374(9)°, with 2 formula units per unit cell. The bond situation in [(C₆F₅)NP(N₃)₃]₂ has been studied on the basis of NBO analysis. The antisymmetric stretching vibration of the azide groups is discussed. The structural diversity of 1 and 1,3‐diphenyl‐2,2,2,4,4,4‐hexazido‐1,3‐diaza‐2,4‐diphosphetidine in solution and in the solid state depending on the aryl substituent at the nitrogen atom is discussed.     

Synthesis and comparative solution properties of single‐, twin‐, and triple‐tailed associating ionic polymers based on diallylammonium salts

The cycloterpolymerizations of single‐, twin‐, and triple‐tailed hydrophobes with hydrophilic monomer N,N‐diallyl‐N‐carboethoxymethylammonium chloride and sulfur dioxide afforded a series of cationic polyelectrolytes (CPEs) in excellent yields. These CPEs, upon the acidic hydrolysis of the pendent ester groups, gave the corresponding pH‐responsive cationic acid salts, which, upon a treatment with sodium hydroxide, were converted to polybetaines (PBs), anionic polyelectrolytes (APEs), and PB/APE polymers containing various proportions of zwitterionic (PB) and anionic fractions (APE) in the polymer chain. At a shear rate of 0.36 s⁻¹ at 30 °C, salt‐free water solutions of the CPEs (2 g/dL) containing 8, 4, and 2.67 mol % of the single‐, twin‐, and triple‐tailed hydrophobes (all having 8 mol % octyloxy tails) had apparent viscosity values of 70, 2800, and 396,000 cps, respectively. The PB/APE polymer with a ratio of 33:67 for the zwitterionic and anionic fractions in the polymer chain gave the highest viscosity value. The superior viscosity behavior of the polymers containing the triple‐tailed hydrophobe was attributed to the blocky nature of the comonomer. © 2006 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 44: 5480–5494, 2006     

Novel Synthesis of Some Imidazolyl‐, Benzoxazinyl‐, and Quinazolinyl‐2,4‐dioxothiazolidine Derivatives

2‐(2,4‐Dioxothiazolidin‐5‐yl)acetic acid 1 and its chloride derivative 2 were allowed to react with different aromatic amines such as o‐phenylenediamine, o‐aminothiophenol, p‐aminoacetophenone, and anthranilic acid to give the biologically active nuclei such as imidazoles, thiazoles, benzoxazines, and quinazolines incorporated with the thiazolidindione nucleus. The antimicrobial activity of five of the synthesized compounds was examined against one gram positive bacteria (Staphylococcus aureus), one gram negative bacteria (Escherichia coli), and two fungi (Aspergillus flavus and Candida albicans). Four compounds showed moderate antibacterial and antifungal activities.     

Synthesis of New Gluco‐, Galacto‐, and Mannopyranosylthiazoles,Thiazolidinones, and Pyranosylthiazlidin‐4‐ones from Sugar Thiosemicarbazone Derivatives

A new series of potentially biological active derivatives, namely alkyl‐2‐((4‐oxo‐2‐(phenylimino)‐3‐(β‐d ‐pyranosyl‐2‐ylamino)thiazolidine‐5‐ylidene)acetate ( 5a–f ), 4‐(4‐bromophenyl)thiazol‐2(3H)‐ylidene)hydrazinyl)‐β‐d ‐pyranosyl ( 4a–c ), and 5‐(4‐bromophenyl)‐2‐(phenylimino)‐3‐(β‐d ‐pyranosyl‐2‐ylamino)thiazolidine‐4‐one ( 6 ) were synthesized via a reaction of the sugar thiosemicarbazone derivatives with 2,4′‐dibromoacetophenone, dialkylacetylenedicarboxylate, and ethylbromoacetate, respectively. The structures of the synthesized compounds were established by spectroscopic methods (FT‐IR, ¹H NMR, ¹³C NMR, and 2D NMR) and elemental analyses. Furthermore, the effect of various solvents at reflux and also ambient temperature on the reactions of the sugar thiosemicarbazone with 2,4′dibromoacetophenone, diethyl acetylenedicarboxylate, and dimethyl acetylenedicarboxylate was investigated. © 2013 Wiley Periodicals, Inc. Heteroatom Chem 24:200–207, 2013; View this article online at wileyonlinelibrary.com . DOI 10.1002/hc.21083     

Synthesis and Reactivity of Mono‐, Di‐, and,Triiron Selenocarboxylate Complexes

Treatment of the iron selenide (μ‐Se)[CpFe(CO)₂]₂ with one equivalent of 1, 3, 5‐C₆H₃(COCl)₃ gave the organoiron selenocarboxylate complex CpFe(CO)₂SeCO‐3, 5‐C₆H₃(COCl)₂ ( 1 ), which contains two free acid chloride groups. Complex 1 reacted with amines, thiols, and phenols to produce the corresponding amides CpFe(CO)₂SeCO‐3, 5‐C₆H₃(CONR₂)₂ ( 2 ), thioesters CpFe(CO)₂SeCO‐3, 5‐C₆H₃(COSR)₂( 3 ), and aromatic esters CpFe(CO)₂SeCO‐3, 5‐C₆H₃(CO₂Ar)₂ ( 4 ), respectively. Complex 1 was converted into the diacid CpFe(CO)₂SeCO‐3, 5‐C₆H₃(COOH)₂ ( 5 ) or the diamide CpFe(CO)₂SeCO‐3, 5‐C₆H₃(CONH₂)₂ ( 6 ) complexes by reactions with NaOH or NaNH₂, respectively. The bis(seleno)‐1, 3‐(CpFe(CO)₂SeCO)₂‐5‐C₆H₃(COCl) ( 7 ) and tris(seleno)‐carboxylate 1, 3, 5‐(CpFe(CO)₂SeCO)₃C₆H₃ ( 8 ) complexes were also prepared by controlled reaction of 1, 3, 5‐C₆H₃(COCl)₃ with the iron selenide (μ‐Se)[CpFe(CO)₂]₂. Complexes 1 – 8 were characterized by spectroscopic techniques (IR, ¹H‐NMR) and by elemental analysis as well. The X‐ray structures of CpFe(CO)₂SeCO‐3, 5‐C₆H₃(COCl)₂ ( 1 ) and CpFe(CO)₂SeCO‐3, 5‐C₆H₃(COSCH₂Ph)₂ ( 3b ) were determined.     

Synthesis,Photophysics and PDT Evaluation of Mono‐, Di‐, Tri‐ and Hexa‐PEG Chlorins for Pointsource Photodynamic Therapy

Pointsource photodynamic therapy (PSPDT) is a newly developed fiber optic method aimed at the delivery of photosensitizer, light and oxygen to a diseased site. Because of a need for developing photosensitizers with desirable properties for PSPDT, we have carried out a synthetic, photophysical and phototoxicity study on a series of PEGylated sensitizers. Chlorin and pheophorbide sensitizers were readily amenable to our synthetic PEGylation strategy to reach triPEG and hexaPEG galloyl pheophorbides and mono‐, di‐, triPEG chlorins. On screening these PEG sensitizers, we found that increasing the number of PEG groups, except for hexaPEGylation, increases phototoxicity. We found that three PEG groups but not less or more were optimal. Of the series tested, a triPEG gallyol pheophorbide and a triPEG chlorin were the most efficient at generating singlet oxygen, and produced the highest phototoxicity and lowest dark toxicity to Jurkat cells. A detailed kinetic analysis of the PEGylated sensitizers in solution and cell culture and media is also presented. The data provide us with steps in the development of PSPDT to add to the PDT tools we have in general.     

Benign‐by‐Design Solventless Mechanochemical Synthesis of Three‐, Two‐, and One‐Dimensional Hybrid Perovskites

Organic–inorganic hybrid perovskites have attracted significant attention owing to their extraordinary optoelectronic properties with applications in the fields of solar energy, lighting, photodetectors, and lasers. The rational design of these hybrid materials is a key factor in the optimization of their performance in perovskite‐based devices. Herein, a mechanochemical approach is proposed as a highly efficient, simple, and reproducible method for the preparation of four types of hybrid perovskites, which were obtained in large amounts as polycrystalline powders with high purity and excellent optoelectronics properties. Two archetypal three‐dimensional (3D) perovskites (MAPbI₃ and FAPbI₃) were synthesized, together with a bidimensional (2D) perovskite (Gua₂PbI₄) and a “double‐chain” one‐dimensional (1D) perovskite (GuaPbI₃), whose structure was elucidated by X‐ray diffraction.     

Synthesis and Antimicrobial Evaluations of Some Novel Mono‐, Bis‐, and Tris‐Nitro‐1,2,4‐Triazines

Substituted‐1,2,4‐triazines were conveniently synthesized in one pot by the cyclization of arylnitroformaldehyde hydrazone derivatives 1 and 5 with different primary amines in ~37% formaldehyde solution. The synthesized compounds were arranged into novel mono‐, bis‐, and tris‐nitro‐1,2,4‐triazine derivatives 2 , 3 , 4 , 6 , and 7 . The antibacterial and antifungal activity of the synthesized compounds were screened against bacterial strains Escherichia coli (as Gram − ve) and Staphylococcus aureus (as Gram + ve), and fungal strains Aspergillus flavus and Candida albicans . All the synthesized compounds exhibit various patterns of inhibitory activity on the two pathogenic bacterial strains. However, the same compounds showed no activity against the tested fungal strains.     

Synthesis and Reactivity of 2‐Pyrrolidino‐, 2‐N‐Methylpiperazino‐, 2‐Piperidino‐, and 2‐Morpholino‐1,3,4‐thiadiazines

A variety of 2‐pyrrolidino‐, 2‐N‐methylpiperazino‐, 2‐piperidino‐, and 2‐morpholino‐1,3,4‐thiadiazines were prepared by cyclocondensation of phenacyl halides with thiosemicarbazides. Heating of the products resulted in desulfurization and formation of pyrazoles. The rate of this process strongly depends on the substitution pattern of the 1,3,4‐thiadiazines.     

Mono‐, bis‐, and trismaleimides having electron‐donating chromophores: Fluorescence,electrochemical properties,polymerization, and cure monitoring

Mono‐, bis‐, and trismaleimides (MM‐2, BM‐4, and TM‐6, respectively) bearing electron‐donating chromophores generally displayed strong fluorescence quenching. The quenching mechanism of fluorescence was revealed by electrochemical studies. On the basis of the electrochemical data, an energy level diagram was established for these maleimides. The electron‐donating ability increased in the order of TM‐6 < BM‐4 < MM‐2. The electron‐accepting ability increased in the opposite order, that is, from MM‐2 to BM‐4 to TM‐6. The copolymerization of multimaleimides with diamine could be well monitored by fluorescence spectroscopy. Compared with fluorescence probe techniques, the fluorescence monitoring could directly reflect the consumption of C?C bonds. Furthermore, a novel trismaleimide resin was preliminarily studied, in which TM‐6 was a dual‐purpose functional monomer acting not only as a crosslinker but also as an intrinsic fluorophore to monitor its crosslinking or cure process. © 2005 Wiley Periodicals, Inc. J Polym Sci Part A: Polym Chem 44: 304–313, 2006     

Synthesis of Functionalized Mono‐, Bis‐, and Trisethynyltriptycenes for One‐Dimensional Self‐Assembly on Surfaces

This paper describes the synthesis of triptycene‐based building blocks that are able to interact through hydrogen bonds to form one‐dimensional self‐assembled motifs on surfaces. We designed 9,10‐diethynyltriptycene derivatives functionalized at the ethynyl end groups by a variety of hydrogen‐bonding groups for homomolecular recognition and complementary building blocks for heteromolecular recognition. We also present the synthesis of bis‐ and trisethynyltriptycenes with terminal alkyne functional groups available for on‐surface azide–alkyne cycloaddition reaction to expand the potential of the triptycene building block.