Monosaccharides with Phosphorus in the Sugar Ring

Abstract

In recent years attention has been directed toward the synthesis of modified sugars wherein the oxygen atom in the sugar ring is replaced by sulfur, selenium or phosphorus. Synthesis of sugar analogs with phosphorus as the ring heteroatom is interesting from the point of view of their possible biological activity.     

Chemistry of Substituted Thiazinanes and Their Derivatives

Thiazinanes and its isomeric forms represent one of the most important heterocyclic compounds, and their derivatives represented a highly potent drug in disease treatment such as, 1,1-dioxido-1,2-thiazinan-1,6-naphthyridine, which has been shown to have anti-HIV activity by a mechanism that should work as anti-AIDS treatment, while (Z)-methyl 3-(naphthalen-1-ylimino)- 2-thia-4-azaspiro[5 5]undecane-4-carbodithioate showed analgesic activity, cephradine was used as antibiotic and chlormezanone was utilized as anticoagulants. All publications were interested in the chemistry of thiazine (partially or fully unsaturated heterocyclic six-membered ring containing nitrogen and sulfur), but no one was dealing with thiazinane itself which encouraged us to shed new light on these interesting heterocycles. This review was focused on the synthetic approaches of thiazinane derivatives and their chemical reactivity.     

REACTIVITY OF SULFUR HETEROCYCLES

Abstract

The relationship between ring strain and the reactivity of alicyclic compounds has been of fundamental importance in the development of modern organic chemistry. Because of their biological interest, the reactivity and stereochemistry of cyclic phosphorus compounds have been extensively studied.^1,2 In recent years the reactivity of cyclic sulfur compounds has also begun to attract considerable interest. In 1966 it was pointed out that the common feature of sulfur-containing heterocycles is that nucleophilic attack at sulfur, be it di-, tri-, or tetra-coordinated, is always faster than the corresponding open-chain analogues.³ The present review attempts to discuss some fo the factors which affect the reactivity of cyclic sulfur compounds towards nucleophilic attack and to draw attention to some of the recently observed exceptions to this generalization.     

Schwefel als Ligandatom in aromatischen Verbindungen III. Synthese einer Isothiazol-Carbonsäure

In order to study the properties of aromatic sulfur as ligand atom and at the same time the similarity of the quinoline and the isothiazole ring, 3-phenylisothiazole-5-carboxylic acid was synthetisized in different ways, e.g. using the 3-phenylisothiazole—also unknown up to date—as starting compound.     

“Heteroglycals” As New Potential Glycosidase Inhibitors. Synthetic Approaches From D-Arabinose

Within the frame of an ongoing project on glycosidase inhibitors, we have been interested in the synthesis of “heteroglycals”, namely, glycal analogues with sulfur or nitrogen in the ring. Glycals² are well known for their applications in sugar chemistry in particular for glycosyl transfer.³ They are also known as glycosidase inhibitors through a slow chemical reaction with the enzyme. Recently exo-glycals emerged as a new class of glycals⁴ which showed interesting features as glycosidase inhibitors but also as precursors of glycomimetics such as C-glycosides.⁵ We have undertaken investigations on related heteroglycals: such compounds are of interest because they combine a planar geometry at the anomeric center and a possible charge site - both elements known to be important to mimic the transition state of the enzymatic glycoside hydrolysis process.⁶     

2H-Pyran-2-ones and their annelated analogs as multifaceted building blocks for the fabrication of diverse heterocycles

2H-Pyran-2-ones are widely present in nature and found as either isolated or in fused form. Depending on the fusion of benzene ring, pyran can give coumarins, isocoumarins, dibenzopyrans etc. This class of molecules exhibit excellent biological activity and photophysical properties. Apart from these, 2H-pyran-2-one also acts as very good Michael acceptor, therefore act as very important synthetic precursor. Suitably functionalized 2H-pyran-2-one has been widely explored for their synthetic potential. In this review, we have focused on use of different nucleophiles based on carbon, nitrogen, oxygen and sulfur to generate vast molecular diversity. The functionalized 2H-pyran-2-ones exhibit three electrophilic centres with different electrophilicity. Use of suitable nucleophiles can act on either of the position based on its reactivity to generate new chemical entity. 2H-Pyran-2-one has been explored as precursor for the synthesis of various biologically important nucleuses like pyridine, pyrimidine, quinolines, isoquinolines, fused quinolines, pyrazole, pyrroles, imidazopyridine, thiazole, oxazole, fused and isolated pyrans, coumarins, isocoumarins, benzothiophenes, dibenzohiophenes, dibenzofurans, diazapines, oxahelicines, thia-oxa helicines, and various other heterocycles under base mediated conditions. Use of suitably substituted 2H-pyran-2-one and nucleophile can generate new molecular entity. In this review, we have discussed the properties, synthesis and their synthetic applications to generate various classes of heterocycles.     

π-Conjugated Macrocycles Bearing Angle-Strained Alkynes

Angle-strained alkyne-containing π-conjugated macrocycles are attractive compounds both in functional materials chemistry and biochemistry. Their interesting reactivity as well as photophysical and supramolecular properties have been revealed in the past three decades. This review highlights the recent advances in angle-strained alkyne-containing π-conjugated macrocycles, especially their synthetic methods, the bond angles of alkynes (∠_sp at C≡C−C), and their functions. The theoretical and experimental research on cyclo[n]carbons and para-cyclophynes consisting of ethynylenes and para-phenylenes are mainly summarized. Related macrocycles bearing other linkers, such as ortho-phenylenes, meta-phenylenes, heteroaromatics, biphenyls, extended aromatics, are also overviewed. Bond angles of strained alkynes in π-conjugated macrocycles, which are generable, detectable, and isolable, are summarized at the end of this review.     

Impact of replacement of the central benzene ring in anthracene by a heterocyclic ring on electronic excitations and reorganization energies in anthratetrathiophene molecules

The impact of changing the central benzene ring on the electronic excitations and reorganization energies (λ) of the anthratetrathiophene (ATT) molecules is studied by density functional theory (DFT) and time‐dependent DFT (TD‐DFT) quantum chemical calculations. The effect of changing the position of the sulfur atom at the periphery of anthracene on the optical and charge transfer properties is also studied. The calculated results suggest that the HOMO, LUMO, HOMO–LUMO energy gap, ionization potential (IP), electron affinity (EA), hole extraction potential (HEP), electron extraction potential (EEP), and reorganization energies (λ) are affected by replacing the central ring with different heterocyclic rings and the position of the sulfur atom. In addition, all molecules show good hole‐ and electron‐transport properties. This work may be helpful for future design and preparation of high‐performance charge‐transport materials.     

噻唑类化合物应用研究新进展

噻唑环是一类重要的含氮硫杂原子的五元芳杂环,其特殊的结构使得噻唑类化合物在化学、药学、生物学和材料科学等诸多领域具有广阔的应用前景,显示出巨大的开发价值,受到广泛关注.本文结合作者的研究工作,参考国内外近五年文献,系统地综述了噻唑类化合物在医药、农药、材料、生物染色剂和超分子化学领域应用研究进展.     

Letter to the Editor Industrial Mixed Acid Nitration

Abstract

Biochemistry — including molecular biology — constituted a major part of Dutch chemical research over the period from 1940 to 1980. However, the Netherlands did not occupy a strong position in that field of research after the Second World War. The present paper seeks to explain the successful development of biochemistry in the Netherlands into an independent discipline of international standing. Formulating the goal of biochemistry as “science for its own sake” played an important role in this development. Post-doctoral positions, senior fellowships and editorships of journals were crucial for biochemistry in the Netherlands in building a network of international contacts that could keep researchers informed about current developments. Westenbrink and Slater were key participants in the development of these networks. These two scientists developed international contacts via fellowships and as editors of major biochemical journals. It was through these forms of communication that the hitherto peripheral Dutch biochemical research community gained a more central position.     

Theoretical and Quantitative Structural Relationship Studies of Electrochemical Properties of the Nanostructures of Cis-Unsaturated Thiocrown Ethers and Their Supramolecular Complexes [X-UT-Y][M@C82] (M˭Ce,Gd)

The endohedral lanthanidofullerenes, an important type of organolanthanides, are stabilized by the delocalization of the negative charges on the cages of fullerenes. Since the discovery of these classes of carbon compounds and their unusual structures and properties of these molecules, many potential applications have been suggested. Unsaturated thiocrown ethers with cis-geometry are a group of crown ethers that, in light of the size of their cavities and their conformational restriction compared to a corresponding saturated system (1–9), demonstrate interesting properties for physicochemical studies. Endohedral lanthanidofullerenes M@C_x (x = 82 and M = Ce, Gd) were introduced as a new class of the spherical fullerene group with unique properties. Formation of endohedral metallofullerenes is thought to involve the transfer of electrons from the encapsulated metal atom(s) to the surrounding fullerene cage. Two of these molecules are the Ce@C₈₂ (10) and Gd@C₈₂ (11). The supramolecular complexes of 1–9 with Ce@C₈₂ (10) and Gd@C₈₂ (11) have been shown to possess a host–guest interaction for electron transfer processes, and these behaviors have previously been reported. Topological indices have been successfully used to construct effective and useful mathematical methods for finding good relationships between structural data and the various chemical and physical properties. To establish a good structural relationship between the structures of 1–9 and M@C_x that were introduced here, an index that is represented as μ_cs was utilized. This index is the ratio of summation of the number of carbon atoms (n_c ) and the number of sulfur atoms (n_s ) to the product of these two numbers for 1–9. In this study, the relationship between this index and oxidation potential ( ^oxE₁ ) of 1–9, as well as the free energy of electron transfer (ΔG_et , by the Rehm-Weller equation) between 1–9 and 10 and 11 as [X-UT-Y][Ce@C₈₂] (12) and [X-UT-Y][Gd@C₈₂] (13) complexes, is presented.

Supplemental materials are available for this article. Go to the publisher's online edition of Phosphorus, Sulfur, and Silicon and the Related Elements to view the free supplemental file.     

Supramolecular complexes based on cyclodextrins

A summary of the application of cyclodextrins (CDs) in the field of supramolecular chemistry has been given. Unique structural features of CDs, namely the separation of hydrophilic and hydrophobic groups, cause unusual physical and chemical properties of these molecules. The most important property of natural or chemically modified CDs is the ability to reversibly and selectively bind organic, inorganic, and biological molecules, forming inclusion complexes (ICs) of the “guest-host” type or nanostructured supramolecular assemblies. The most interesting examples of the application of ICs with CDs in pharmaceutical, food, and chemical industry, spectrometric analysis, separation technologies, of the use of CDs as models for molecular recognition in biology, as well as the cyclical component in the construction of supramolecular architectures (rotaxanes, pseudorotaxanes) are given in the review. The mechanism and methods of the formation of ICs, their properties and the methods of analysis have been described. Particular attention has been paid to molecular necklaces. One of the new promising directions of the application of CDs, namely, the preparation of nanosized materials, has been considered.     

Flavonoids: biological activities and therapeutic potential

Abstract

Flavonoids have aroused much interest in research, since they present a great diversity of biological activities observed in vitro, such as: antioxidant effect, modulation of the enzymatic activity and inhibition of cellular proliferation, exerting beneficial effects on the organism, as well as the use of its therapeutic potential. With wide distribution in the plant kingdom represent a class of phenolic compounds that differ in their chemical structure and particular characteristics. The objective of this review was to describe the relevant aspects of flavonoids, reporting the different known groups, the probable mechanisms by which they act, their pharmacological properties and to gain a better understanding of the reported beneficial health effects of these substances. This systematic review consisted of research using scientific databases such as Scopus, Science Direct, PubMed, SciVerse and SciELO, without time limitation. Some pharmacological properties of some flavonoids and their health benefits have been confirmed by previous studies.     

Cleavage of Diethyl Chromonyl α-Aminophosponate with Nitrogen and Carbon Nucleophiles: A Synthetic Approach and Biological Evaluations of a Series of Novel Azoles,Azines, and Azepines Containing α-Aminophosphonate and Phosphonate Groups

A convenient synthetic approach leading to a series of novel substituted azoles, azines, and azepines linked to the α-aminophosphonate moiety was achieved. The methodology depends on ring opening and ring closure (RORC) of the chromone ring of diethyl chromonyl α-aminophosphonate 1 via its reaction with nitrogen nucleophiles such as primary amines and 1,2-, 1,3-, and 1,4-bi-nucleophiles in ethanolic sodium ethoxide. Also, treatment of compound 1 with some acyclic and cyclic active methylene compounds under the same reaction conditions afforded interesting novel isolated and fused pyridine systems bearing phosphonate groups at the α-position. The screening of antimicrobial activity for the synthesized compounds indicates that connection of pyrazole, oxazepine, and benzodiazepine rings with α-aminophosphonate moiety exhibited good antimicrobial effects. Also, evaluation of their antioxidant properties shows that the compounds having 1,5-benzoxazepinyl and 1,5-benzodiazepinyl units in combination with α-aminophosphonic diester moiety are the most powerful antioxidant agents.     

An overview of the chemistry of homo and heteropolynuclear platinum complexes containing bridging acetylide (μ-C≡CR) ligands

Different aspects of transition metal alkynyl chemistry have been widely studied over the past decades because of their interesting structures, chemical reactivity and properties. This review describes the chemistry of homo and heteropolynuclear platinum complexes containing bridging ligands, with special emphasis in synthetic routes, structural aspects and photoluminescence properties.     

Electroanalysis at Diamond‐Like and Doped‐Diamond Electrodes

Diamond as a high performance material occupies a special place due to its in many ways extreme properties, e.g., hardness, chemical inertness, thermal conductivity, optical properties, and electric characteristics. Work mainly over the last decade has shown that diamond also occupies a special place as an electrode material with interesting applications in electroanalysis. When made sufficiently electrically conducting for example by boron‐doping, ‘thin film' and ‘free–standing' diamond electrodes exhibit remarkable chemical resistance to etching, a wide potential window, low background current responses, mechanical stability towards ultrasound induced interfacial cavitation, a low ‘stickiness' in adsorption processes, and a high degree of ‘tunability' of the surface properties. This review summarizes some of the recent work aimed at applying conductive (boron‐doped) diamond electrodes to improve procedures in electroanalysis.     

黄铜矿及其复合材料在电化学储能领域的研究进展

黄铜矿(CuFeS₂)是一种具有特殊金色光泽的天然矿物,具有四方结构,其中Fe、Cu离子与晶格中的硫形成四面体配位,相较于其他硫化物和其相对应的氧化物,CuFeS₂具有较高的电导率和优异的电化学性能,且拥有成本低廉、存在天然矿物且自然储量丰富、无毒等优势,使其具有应用于电化学储能体系电极材料的潜能。本文详细介绍了CuFeS₂的物理化学性质、几种简单的不同形貌的合成方法以及其作为电化学储能电极材料方面的研究,并对CuFeS₂材料未来的研究方向进行了展望。     

Non-covalent strategy for activating separation and detection functionality by use of the multifunctional host molecule thiacalixarene

This review article proposes a non-covalent strategy for activating separation and detection functionality; this strategy acts not through extensive organic synthesis to a covalently constructed molecular receptor, but by combining a simple molecular platform with a chemical “field” or functional component. For such a platform, we employed thiacalixarenes—calixarenes in which the bridging methylene groups are replaced with sulfur—to demonstrate usefulness of the non-covalent strategy and the multifunctionality of thiacalixarene. Thiacalixarene exhibits inherent abilities to recognize metal ions by coordinating with the bridging sulfur and adjacent phenol oxygen, as well as to include organic guest molecules in the cavity. Moreover, the non-covalent coupling of thiacalixarene provides systems with functions higher than thiacalixarene by itself. The functions described in this paper are as follows: (1) a 200-fold pre-concentration of heavy metal ions such as Cu^II, Cd^II, and Pb^II; (2) a pre-column derivatization reagent for the highly selective and sensitive determination of Ni^II, Al^III, Fe^III, and Ti^IV at sub-ppb levels with reversed-phase HPLC; (3) the self-assembled formation of a luminescence receptor with Tb^III ions for the detection of 10^?10 M levels of 1-ethylquinolinium guest; and (4) a sensing system for 10^?9 M levels of Ag^I ions by the formation of the Ag^I-Tb^III-thiacalixarene ternary supramolecular complex. These examples support the non-covalent strategy as a highly promising way to obtain functions beyond that of a molecular platform. In addition, these diverse functions indicate the multifunctionality of thiacalixarene as well as its suitability to the non-covalent strategy, since the inherent functional groups—such as the bridging sulfur, phenol oxygen, p-substituent, aromatic ring, and hydrophobic cavity—synergistically perform the functions.     

Ab Initio Study of Ring Flipping of the Overcrowded Peri-Substituted Naphthalenes

Ab inintio molecular orbital and density functional theory method were used to investigate the structural and dynamic behavior of 1,8-di-tert-butyl naphthalene (1), 1,8-bis(trimethylsilyl)naphthalene (2), 1,8-bis(trimethylgermyl)naphthalene (3), and 1,8-bis(trimethylstannyl)naphthalene (4). HF/3-21G//HF/3-21G results revealed that the ring flipping barrier height of compound 1–4 is 92.59, 32.13, 26.76, and 15.46 kJ mol^?1 respectively. The obtained results show that the transition state structure for ring flipping of the bulky-groups is in a planar form with naphthalene ring. Contrary to compound 1, the ring flipping of compounds 2–4 occurred easily at room temperature. Also, MP2/3-21G//HF/3-21G energy calculation, show that the enantiomerization energy of compounds 1–4 are 97.99, 33.24, 26.80, and 15.38 kJ·mol^?1 respectively. The required energy for ring inversion of compounds 1–4 are 85.09, 27.26, 21.54, and 10.21 kJ mol^?1 respectively, as calculated by B3LYP/3-21G//HF/3-21G method. It can be concluded that the lower energy barrier of the ring flipping of compounds 2–4 is related to the increasing of the bond lengths of Si—C, Ge—C, and Sn—C, in contrast to C—C bond.