1,1-dioxonaphtho[1,2-b]thiophene-2-methyloxycarbonyl (alpha-Nsmoc) and 3,3-dioxonaphtho[2,1-b]thiophene-2-methyloxycarbonyl (beta-Nsmoc) amino-protecting groups

Of the three theoretically possible, Bsmoc-related, naphthothiophene sulfone-based amino-protecting groups, the two most readily available derivatives, the alpha- and beta-Nsmoc analogues, have been examined as substitutes for the Bsmoc residue in cases where the latter lead to oily protected amino acids or amino acid fluorides. All of the naphtho systems gave easily handled solid amino acid derivatives. The intermediate sulfone alcohol 11 used as the key reagent for introduction of the alpha-Nsmoc protecting group was readily made from alpha-tetralone (Scheme 1). The corresponding beta-analogue 17 was made similarly on a small scale, but due to the high cost of beta-tetralone, an alternate route involving reaction of rhodanine with alpha-naphthaldehyde was used for large-scale work (Scheme 2). All proteinogenic amino acids were converted to their alpha- and beta-Nsmoc derivatives. Deblocking studies showed that the reactivity toward deblocking by piperidine followed the order alpha-Nsmoc > Bsmoc > beta-Nsmoc. 1H NMR experiments showed that deblocking of the two new systems was mechanistically similar to that previously established for the Bsmoc derivative in that the reaction is initiated by Michael addition to the beta-carbon atom of the alpha,beta-unsaturated sulfone system. Application of alpha- and beta-Nsmoc amino acids to the solid-phase synthesis of two model peptides was examined. An advantage of the alpha-Nsmoc system over the long-known Bsmoc system proved to be the milder conditions needed for the deblocking step relative to the Bsmoc case, which is itself more readily deblocked than the classic Fmoc analogue.     

Synthesis of an N-Acetylated Heparin Pentasaccharide and its anticoagulant activity in comparison with the heparin pentasaccharide with high anti-factor-Xa activity

The synthesis of tri-N-acetylated heparin pentasaccharide 2 is described. It was assembled from five suitably blocked monosaccharide units ( 3 – 7 ). Glucuronic-acid building block 4 was prepared from glucose by direct Jones oxidation of the 6-O-trityl derivative 18 . The resulting acid 16 was esterified to 17 in large mounts using methyl chloroformate/base. Trimethylsilyl bromide proved to be an excellent reagent for the hydrolysis of a prop-1-enyl glycoside ( 19 →21 ). The pentasaccharide 29 was obtained by a [2 + 2] + 1 synthesis, the glycosylation reactions furnished good to very good yields. The identity of protected oligosaccharides was confirmed by ¹H-NMR spectroscopy. Sequential deblocking of the pentasaccharide, O-sulfation, and N-acetylation gave 2 which was shown to exhibit ca. 600 times lower anticoagulant activity than pentasaccharide 1 .     

A highly efficient chemical synthesis of Rp and Sp adenyl(3′-5′)adenyl-o,o-phosphorothioate

A method is described for the chemical synthesis of the title compounds (Ap(S)A) via addition of elemental sulfur to a phosphite triester intermediate. Separation of the diastereomers of phosphorus could be accomplished on silica gel after removal of the terminal 5′-hydroxyl protecting group or on DEAE cellulose after complete deblocking. The triester to terminal 5′-hydroxyl. The overall yield of the synthesis (one coupling and four deblocking steps) is 30%.     

Understanding the "tailoring synthesis" of CdS nanorods by O2

Parameters such as solution concentrations and composition of the ambient atmosphere are known to be important in phase and morphology control in the solvothermal synthesis of CdS semiconductor nanorods (NRs), but a clear understanding of the underlying mechanisms involved is lacking. In this work, a series of experiments were performed to demonstrate that the key factor affecting the phase and morphology of CdS NRs is the amount of O(2) in the space above the reaction solution in the sealed vessel relative to the amount of precursors in solution: O(2)-depleted conditions resulted in more cubic phase CdS and thick polycrystalline NRs with an aspect ratio usually less than 3, which have small blue shifts in band-edge emission and little surface trap emission, while O(2)-rich conditions resulted in more hexagonal-phase CdS and slim single-crystal NRs, which have significantly blue shifted band-edge emission and relatively strong surface trap emission. Thus, increasing the amount of solution in the vessel, changing the ambient atmosphere from air to N(2), and increasing the reagent concentration all lower the molar ratio of O(2) to reagents and lead to more cubic phase and thicker NRs. The results indicate that the composition of the "empty" section of the reaction vessel plays as important a role as the composition of the liquid in determining the phase and morphology, something that has been overlooked in earlier work. A mechanism to explain the effect of oxygen on the nucleation and growth stages has been proposed on the basis of those results and further supported by shaking experiments and ZnS NR synthesis manipulation. The CdS NRs synthesized under different conditions showed obvious differences in photocatalytic activity, which indicated that controlling the synthetic process can lead to materials with tailored photocatalytic activity.     

Synthesis,characterization, and analytical applications of 1,3-dimethyl-4-acetyl-2-pyrazolin-5-one

The synthesis of a new chelating reagent, 1,3-dimethyl-4-acetyl-2-pyrazolin-5-one (DMAP), is described. The reagent is characterized by physical, spectral and thermal methods. The reagent is soluble in water and forms neutral, water-soluble complexes with a number of metal ions, including Zr(IV), Th(IV), and U(VI). The complexed metal ions can be concentrated from dilute aqueous solution by adsorption onto a small column of Amberlite XAD-4 resin. The synthesis and characterization of the uranium (VI) complex of DMAP are described. The complex has the formula UO₂ (DMAP)₂, with a logarithmic formation constant of 8.64. A procedure is given for concentrating trace levels of U(VI) from solution by complexation with DMAP and sorption on XAD-4 resin. The method shows good recovery and precision for the concentration of trace U(VI) from artificial seawater.     

Chemical synthesis of a pentaribonucleoside tetraphosphate constituting the 3'-acceptor stem sequence of E. coli tRNAIle using 2'-O-(3-methoxy-1,5-dicarbomethoxypentan-3-yl)-ribonucleoside building blocks. Application of a new achiral and acid-labile 2'-hydroxyl protecting group in tRNA synthesis

A synthesis of a pentaribonucleotide fragment constituting the residues 59-63 of 3'-terminus of E. coli tRNAIle, 5'-ApGpUpCpC-3', has been carried out using a new, easily accessible and achiral 2'-ketal protecting group. The new 2'-ketal group has an additional advantage in that it is easily functionalized to the diamide with aqueous ammonia in the penultimate step of deblocking of fully protected oligoribonucleotides. Such a functionalization of the 2'-ketal group at the penultimate step of deblocking of the fully protected tRNA molecule enhances its relative rate of removal under an acidic condition with a minimum of damage of the target tRNA molecule.     

Fluoride‐Catalyzed Deblocking: A Route to Polymeric Urethanes

We report a fluoride‐catalyzed deblocking of urethanes as “blocked” isocyanates. Organic and inorganic sources of fluoride ion proved effective for deblocking urethanes and for converting polyurethanes to small molecules. Distinct from conventional deblocking chemistry involving organometallic compounds and high temperatures, the method we describe is metal‐free and operates at or slightly above room temperature. The use of fluorescent blocking agents enabled visual and spectroscopic monitoring of blocking/deblocking reactions, and the selected conditions proved applicable to urethanes containing a variety of blocking groups. The method additionally enabled a one pot deblocking and polymerization with α,ω‐diols. Overall, this deblocking/polymerization strategy offers a convenient and efficient solution to problems that have limited the breadth of applications of polyurethane chemistry.     

Synthesis of oligonucleotides with sequences identical with or analogous to the 3'-end of 16s ribosomal rna of escherichia coli: preparation op U-C-C-U-U-A and A-C-C-U-C-C-U-U-A via the modified phosphotriester method

The synthesis of oligoribonucleotides U-C-C-U-U-A and A-C-C-U-C-C-U-U-A, which are located at the 3'-terminus of 16S rRNA of E. coli, is described. The key-intermediates in the synthesis of these compounds are the fully-protected mononucleotides 5a-c, which can be rapidly (2–4 min) functionalized by either of the two following specific deblocking procedures: (i) at the 3'-tenninus with zinc in pyridine-2,4,6-triisopropylbenzenesul-phonic acid and (ii) at the 5'-terminus with 0.5M hydrazine in pyridine-acetic acid. The fully-protected hexamer 17a and nonamer 19, prepared by utilizing these deblocking conditions, were completely deprotected by the action of fluoride ion, followed by treatment with base and acid to give the required oligonucleotides in high yield.     

Generation of arylnitrenium ions by nitro-reduction and gas-phase synthesis of <Emphasis Type="Italic">N</Emphasis>-Heterocycles

Nitro-reduction by the vinyl halide radical cation CH2 = CH-X+* (X = Cl or Br) converts nitroaromatics into arylnitrenium ions, significant intermediates in carcinogenesis, and the present study reports on the scope and regioselectivity of this versatile reaction. The reaction is general for different kinds of substituted nitroaromatics; para/meta substitutents have little effect on the reaction while ortho substitutents result in low yields of arylnitrenium ions. The phenylnitrenium ion PhNH+ can be generated by chemical ionization (CI) of nitrobenzene using 1,2-dichloroethane as the reagent gas or by atmospheric pressure chemical ionization (APCI) of 1,2-dichloroethane solution doped with nitrobenzene. The chemical reactivities of the arylnitrenium ions include one-step ion/molecule reactions with nucleophiles ethyl vinyl ether and 1,3-dioxolanes, respectively, involving the direct formation of new CN bonds and synthesis of indole and benzomorpholine derivatives. The indole formation reaction parallels known condensed phase chemistry, while the concise morpholine-forming reaction remains to be sought in solution. The combination of collision-induced dissociation (CID) with novel ion/molecule reactions should provide a selective method for the detection of explosives such as TNT, RDX and HMX in mixtures using mass spectrometry. In addition to the reduction of the nitro group, reduction of methyl phenyl sulfone PhS(O)2Me to the thioanisole radical cation PhSMe+* occurs using the same chemical ionization reagent 1,2-dichloroethane. This probably involves an analogous reduction reaction by the reagent ion CH2 = CH-Cl+*.     

Structure and reactivity of bis(iodozincio)methane solution

Bis(iodozincio)methane, which has been shown to be an efficient reagent for organic synthesis, is obtained as THF solution. The structural information about the reagent as THF solution was corrected by small angle neutron scattering and by anomalous X-ray scattering. Those scattering experiments implied that the prepared bis(iodozincio)methane exists without forming any oligomer or aggregate. A coordination of tetrahydrothiophene to bis(iodozincio)methane enhances the nucleophilicity of the reagent and stabilizes its monomeric structure in the solution.     

C-Nucleosides. 8. Synthesis of 5-hydroxy-2-(β-D-ribofuranosyl)pyridine

The synthesis of 5-hydroxy-2-(β-D-ribofuranosyl)pyridine ( 12 ) from 2-(2,3,5-tri-O-benzoyl-β-D-ribofuranosyl)furan ( 1 ) is described. Treatment of 1 with α-methoxycarbamate in the presence of p-toluenesulfonic acid in benzene at reflux temperature afforded furfurylcarbamate ( 2 ) and its α-isomer in a 5/1 ratio. The anomerization was circumvented by treatment of 1 with α-methoxycarbamate in the presence of boron trifluoride in benzene at room temperature. Compound 2 was electrochemically oxidized to give dihydrofuran 4 . However, conversion of 4 into 11 was unsuccessful. Treatment of azide 8 with bromine and methanol afforded 9 . Reduction of 9 with zinc powder gave dihydrofurfurylamine 10 , in 80% yield. Treatment of this with concentrated hydrochloric acid in methanol yielded 11 , which on deblocking with 5% sodium hydroxide aqueous solution gave 12.     

Fluorimetric determination of boron at microgram level

The synthesis, characterization and application of 2-(2-hydroxybenzylidenimine)benzene-arsonic acid (HBBA) as a reagent for the fluorimetric determination of boron are described. This reagent reacts with boric acid in 85% w/w sulphuric acid medium to yield a fluorescent compound. The reagent is not fluorescent in those conditions. Heating at 90 degrees for 45 min is needed for the compound to be formed. The linear calibration range is 0.1-8 microg/ml in the solution measured. The detection limit of the method is 0.01 microg/ml. The method has been applied to determine boron in vegetal material.     

A Practical,Water‐Soluble,Ionic Scavenger for the Solution‐Phase Syntheses of Amides

A new ionic, water‐soluble scavenger for acyl chlorides, 1‐(2‐aminoethyl)pyridinium bromide ( 1 ), has been investigated. Compound 1 was used for the rapid and simple purification of a series of benzamides and sulfonamides (Table) obtained by solution‐phase synthesis from the corresponding amines (Scheme). The inexpensive scavenger, which can be prepared on large scale, was shown to readily ‘eliminate’ excess acyl chlorides (reagent) by simple aqueous extraction. The amides purified in this way were obtained in excellent yields and purities (Table), which makes 1 a versatile new reagent, especially for the combinatorial solution‐phase synthesis of amide libraries.     

A new crystal engineering approach for the synthesis of {[K.18-Crown-6]I3}n as a nanotube-Like and recyclable catalyst for the chemoselective silylation of alcohols

Reaction of 18-crown-6 with KI in ethanol solution followed by addition of iodine (I₂) afforded a unique triiodide salt with a nanotube-like structure ({[K.18-Crown-6]I₃}_n). It is shown that this reagent may be used for the chemoselective trimethylsilylation of alcohols. The synthesis of the crystalline reagent is a good example of crystal engineering. Reagent was recycled and reused.     

Reversible dimethylamine addition as a protecting reaction for α,β-unsaturated methylene groups of γ-lactones and its regeneration by basic elimination of quaternary ammonium salts: A convenient synthesis of dehydrosaussurea lactone

The blocking and deblocking sequence pertaining to the α,β-unsaturated methylene γ-lactone unit of costunolide is described. Utilizing this approach a simple and practical synthesis of dehydrosaussurea lactone is reported.     

含磷高分子马来酸酐共聚物的阻垢性能

研究了以水为溶剂合成的阻垢功能高分子马来酸酐-丙烯酸-氮川三甲叉膦酸共聚物(PMAN)对CaCO3、CaSO4和Ca2(PO4)3合成水的阻垢效果．探讨了共聚物分散氧化铁的能力及药剂用量、温度、pH值、水体硬度对阻垢率的影响．共聚物的合成工艺及应用符合环保要求。其阻垢性能优于常用的阻垢剂．     

Surface patterning of silica nanostructures using bio-inspired templates and directed synthesis

Natural systems excel in directing the synthesis of inorganic materials for various functional purposes. One of the best-studied systems is silica synthesis, as occurs in diatoms and marine sponges. Various biological and synthetic polymers have been shown to template and catalyze silica formation from silicic acid precursors. Here, we describe the use of poly-L-lysine to promote the synthesis of silica in neutral, aqueous solution and when immobilized onto a silicon support structure under similar conditions. Either reagent jetting or conventional photolithography techniques can be used to pattern the templating polymer. Spots created by reagent jetting led to the creation of silica structures in the shape of a ring that may be a result of the spotting process. Photolithographically defined poly-L-lysine spots led to thin laminate structures after exposure to a dilute aqueous silicic acid solution. The laminate structures were nanostructured and highly interconnected. Photolithographic patterning of (3-aminopropyl)trimethoxysilane, a reagent that mimics the lysine functional group, led to similar silica coatings even though low-molecular-weight materials do not rapidly promote silica synthesis in solution. This result highlights the importance of functional-group arrangement for templating and promoting the synthesis of inorganic materials. The described surface-patterning techniques offer a route to integrate conventional silicon-patterning technologies with biologically based material synthesis. Such combined fabrication techniques enable controlled assembly over multiple length scales and an approach to understanding interfacial silica synthesis, as occurs in natural systems.     

A Samarium "Soluble" Anode: A New Source of SmI(2) Reagent for Electrosynthetic Application

An electrochemical method to prepare solutions of samarium diiodide in THF is reported. The simple electrolysis of a samarium rod provides a rapid and straightforward in situ synthesis of SmI(2) . The electrogenerated complex catalyzes various C?C bond formations. The reagent is produced continuously and leads to efficient organic electrosynthesis with significantly smaller amounts of solvent than usually required.     

The precipitation of hydrated cobalt 1-nitroso-2-naphtholate from homogeneous solution

A method has been developed for determining cobalt by precipitating cobalt^III 1-nitroso-2-naphtholate from homogeneous solution. The reagent is synthesised within the reaction mixture by treating 2-naphthol with nitrous acid in the presence of cobalt^II ion. Thus nitrous acid serves the dual role as oxidant for the cobalt^II ion and also as a reactant in the synthesis of the reagent. Excess reagent precipitates after the cobalt nitroso-naphtholate has settled. A washing procedure has been developed to eliminate the excess reagent without affecting the cobalt nitroso-naphtholate. After washing to remove excess reagent and filtration, the precipitate is dried at 115° and weighed as Co(C₁₀H₆O₂N)₃·H₂O.

The presence offluoride prevents the interference of iron, tungsten and other elements which form strong fluoride complexes.

The precision and accuracy is within 0-1 mg of cobalt at a 10-mg level and within 0-2 mg of cobalt at a 50-mg level.     

A concise synthesis of 2,5-dideoxy-2,5-imino-d-mannitol (DMDP) and HomoDMDP from l-xylose

A short and practical procedure for the preparation of C-2 substituted polyhydroxypyrrolidines is described. The C-2 substituent is introduced by a stereoselective addition of a Grignard reagent to a 2,3,5-protected aldofuranose and the cyclization to the pyrrolidine ring system is performed through a bis-mesylation/double nucleophilic displacement sequence. The efficiency of the methodology was demonstrated by its application to the synthesis of HomoDMDP and DMDP.