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Tetrahydrofuran, function

Unlike CNTs, BNNTs are less investigated in the biomedicinal applications. The major problan remains the insolubility of BNNTs in aqueous medium, as well as any other common organic solvents this can be overcome via surface functionalization of the BNNTs. There are a few published reports available on noncovalent, as well as covalent, functionalizations of BNNTs. Zhi et al. reported BNNTs, wrapped in a polymer, were soluble in organic solvents, for example, chloroform, tetrahydrofuran. Functionalization of BNNTs by amine-terminated oligomeric poly(ethylene glycol), stearoyl chloride, interaction with Lewis bases, ammonia plasma irradiation were also studied. Recently, Chen et al. cited the noncytotoxicity of BNNTs and emphasized the need for water-soluble BNNTs. ... [Pg.508]

Instmmental methods of analysis provide information about the specific composition and purity of the amines. QuaUtative information about the identity of the product (functional groups present) and quantitative analysis (amount of various components such as nitrile, amide, acid, and deterruination of unsaturation) can be obtained by infrared analysis. Gas chromatography (gc), with a Hquid phase of either Apiezon grease or Carbowax, and high performance Hquid chromatography (hplc), using siHca columns and solvent systems such as isooctane, methyl tert-huty ether, tetrahydrofuran, and methanol, are used for quantitative analysis of fatty amine mixtures. Nuclear magnetic resonance spectroscopy (nmr), both proton ( H) and carbon-13 ( C), which can be used for quaHtative and quantitative analysis, is an important method used to analyze fatty amines (8,81). [Pg.223]

Certain base adducts of borane, such as triethylamine borane [1722-26-5] (C2H )2N BH, dimethyl sulfide borane [13292-87-OJ, (CH2)2S BH, and tetrahydrofuran borane [14044-65-6] C HgO BH, are more easily and safely handled than B2H and are commercially available. These compounds find wide use as reducing agents and in hydroboration reactions (57). A wide variety of borane reducing agents and hydroborating agents is available from Aldrich Chemical Co., Milwaukee, Wisconsin. Base displacement reactions can be used to convert one adduct to another. The relative stabiUties of BH adducts as a function of Group 15 and 16 donor atoms are P > N and S > O. This order has sparked controversy because the trend opposes the normal order estabUshed by BF. In the case of anionic nucleophiles, base displacement leads to ionic hydroborate adducts (eqs. 20,21). [Pg.236]

Given the relatively rare appearance of oxetanes in natural products, the more powerful functionality of the Patemo-Biichi reaction is the ability to set the relative stereochemistry of multiple centers by cracking or otherwise derivitizing the oxetane ring. Schreiber noted that Patemo—Btlchi reactions of furans with aldehydes followed by acidic hydrolysis generated product 37, tantamount to a threo selective Aldol reaction. This process is referred to as photochemical Aldolization . Schreiber uses this selectivity to establish the absolute stereochemistry of the fused tetrahydrofuran core 44 of the natural product asteltoxin. ... [Pg.48]

TMM cycloadditions to cyclic and conjugated ketones have also been reported (Scheme 2.22) [31]. The steric nature of the substrate does play a critical role in determining product formation. Thus the cyclic ketone (73) produced 55% yield of the tetrahydrofuran, but no cycloadduct could be obtained from the cyclic ketone (74). The enone (75) gave only carbonyl cycloaddition, whereas enone (76) yielded only olefin adduct. Interestingly, both modes of cycloaddition were observed with the enone (77). The ynone (78) also cycloadds exclusively at the carbonyl function [34]. [Pg.72]

The reaction of lead tetraacetate (LTA) with monohydric alcohols produces functionalization at a remote site yielding derivatives of tetrahydrofuran (THF) 12). An example is the reaction of 1-pentanol with LTA in nonpolar solvents which produces 30% THF. The reaction, which is believed to proceed through free-radical intermediates, gives a variable distribution of oxidation products depending on solvent polarity, temperature, reaction time, reagent ratios, and potential angle strain in the product. [Pg.11]

For the most part, cyclic ethers behave like acyclic ethers. The chemistry of the ether functional group is the same, whether it s in an open chain or in a ring. Common cyclic ethers such as tetrahydrofuran and dioxane, for example, are often used as solvents because of their inertness, yet they can be cleaved by strong acids. [Pg.660]

Intermediate 8, the projected electrophile in a coupling reaction with intermediate 7, could conceivably be derived from iodolactone 16. In the synthetic direction, cleavage of the acetonide protecting group in 16 with concomitant intramolecular etherification could result in the formation of the functionalized tetrahydrofuran ring of... [Pg.234]

The next major obstacle is the successful deprotection of the fully protected palytoxin carboxylic acid. With 42 protected functional groups and eight different protecting devices, this task is by no means trivial. After much experimentation, the following sequence and conditions proved successful in liberating palytoxin carboxylic acid 32 from its progenitor 31 (see Scheme 10) (a) treatment with excess 2,3-dichloro-5,6-dicyano-l,4-benzoquinone (DDQ) in ie/t-butanol/methylene chloride/phosphate buffer pH 7.0 (1 8 1) under sonication conditions, followed by peracetylation (for convenience of isolation) (b) exposure to perchloric acid in aqueous tetrahydrofuran for eight days (c) reaction with dilute lithium hydroxide in H20-MeOH-THF (1 2 8) (d) treatment with tetra-n-butylammonium fluoride (TBAF) in tetrahydrofuran first, and then in THF-DMF and (e) exposure to dilute acetic acid in water (1 350) at 22 °C. The overall yield for the deprotection sequence (31 —>32) is ca. 35 %. [Pg.725]

In contrast, aryl azides 86 bearing an ortho electron-withdrawing group, particularly a carbonyl function, in methanol solution ring expand upon photolysis in practicable yields to provide 2-alkoxy-3//-azepines 87 36,74,195 -197 shorter reaction times and improved yields are often obtained using a 1 1 alcohol/tetrahydrofuran mixture. [Pg.153]

Acetyl-5//-dibenz[/>,/]azepine-10-car bon itrile (17, R = CN) when treated with sodium borohydride undergoes reduction (73 % yield) at the CIO - Cl 1 double bond without reduction of the acetyl or cyano groups.212 However, hydroboration of 5-acetyl-5//-dibenz[/y/]azepine (17, R = H) with diborane in tetrahydrofuran under standard conditions is accompanied by reduction of the acyl function to yield 5-ethyi-10,l l-dihydrodibenz[6,/]azepin-10-ol (18).72... [Pg.285]

A mechanism for its formation was also proposed. Essentially, this involved protonation of 2-methylfuran followed by dimerization and trimerization to a 2,4-difuryl tetrahydrofuran derivative which suffered an acid catalysed cleavage of the saturated ring to produce a carbenium ion possessing an alcoholic function at the other end of... [Pg.60]

An interesting example for the preparation of functional disiloxanes by use of organometallic techniques is the synthesis of l,3-bis(4-hydroxybutyl)t.etramethyl-disiloxane as shown in React ion Scheme VI. The first, part of the reaction is conducted at the reflux temperature of tetrahydrofuran (THF) and methyl iodide is used as catalyst. The ratio of dichlorodimethylsilane to magnesium and to THF affects the yield of the cyclic product very strongly. The disiloxane is obtained in about 70% yield by aqueous hydrolysis of the purified cyclic intermediate under mild conditions and in the presence of a small amount of hydrochloric acid. [Pg.15]

The addition, therefore, follows Markovnikov s rule. Primary alcohols give better results than secondary, and tertiary alcohols are very inactive. This is a convenient method for the preparation of tertiary ethers by the use of a suitable alkene such as Me2C=CH2. Alcohols add intramolecularly to alkenes to generate cyclic ethers, often bearing a hydroxyl unit as well. This addition can be promoted by a palladium catalyst, with migration of the double bond in the final product. Rhenium compounds also facilitate this cyclization reaction to form functionalized tetrahydrofurans. [Pg.996]

The 10 OC route was followed for the synthesis of tetrahydrofurans possessing a y-amino alcohol moiety 247 (Eq. 29) 118]. Aldoximes 21a-f (see also Eq. 3 and Table 2), when heated in benzene in a sealed tube at 110 -120 °C for 6 h, underwent smooth intramolecular cycloaddition to the tetrahydrofuranoisoxazo-lidines 246a-f in 70-83% yield (Eq. 29). This ring closure proceeded stereo-specifically to generate three adjacent stereogenic centers. LAH reduction of 246 b resulted in isolation of stereospecifically functionalized tetrahydrofuran derivative 247b in 75% yield. [Pg.36]


See other pages where Tetrahydrofuran, function is mentioned: [Pg.33]    [Pg.21]    [Pg.10]    [Pg.90]    [Pg.439]    [Pg.742]    [Pg.748]    [Pg.186]    [Pg.200]    [Pg.230]    [Pg.243]    [Pg.285]    [Pg.48]    [Pg.55]    [Pg.60]    [Pg.808]    [Pg.92]    [Pg.24]    [Pg.24]    [Pg.152]    [Pg.100]    [Pg.1009]    [Pg.132]    [Pg.132]    [Pg.137]    [Pg.192]    [Pg.60]    [Pg.178]    [Pg.521]    [Pg.826]    [Pg.217]    [Pg.173]    [Pg.178]   


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