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Hydroxyl group Ether linkage

The two polymers most often used in these applications are dextran and PEG. Both polymers consist of repeating units of a single monomer—glucose in the case of dextran and an ethylene oxide basic unit in the case of PEG. The polymers may be composed of linear strands (PEG or dextran) or branched constructs (dextran). An additional similarity is that both of them possess hydroxyl and ether linkages, lending hydrophilicity and water solubility to the molecules. Dextran and PEG can be activated through their hydroxyl groups by a number of chemical methods to allow... [Pg.625]

Aromatic substituents noticeably affect reaction thermochemistry only when such groups either directly delocalize the odd-electron or lead to a difference in strain energy between reactants and products. For example, meta- or para-alkyl groups, ether linkages, hydroxyl groups, etc. will not noticeably influence reaction thermochemistry (117). [Pg.115]

The outstanding performance characteristics of the resins are conveyed by the bisphenol A moiety (toughness, rigidity, and elevated temperature performance), the ether linkages (chemical resistance), and the hydroxyl and epoxy groups (adhesive properties and formulation latitude, or reactivity with a wide variety of chemical curing agents) (see also Phenolic resins). [Pg.362]

Palytoxin carboxylic acid, C,23H2i3N053 (Figure 1, R -R = H), derived from palytoxin, C,29H223N3054, contains 41 hydroxyl groups, one amino group, one ketal, one hemiketal, and one carboxylic acid, in addition to some double bonds and ether linkages. [Pg.5]

Above 160°C it is believed that additional cross-linking reactions take place involving the formation and reaction of quinone methides by condensation of the ether linkages with the phenolic hydroxyl groups (Figure 23.14). [Pg.642]

Up to 1915 it had been established that oscine was a tertiary bas containing one hydroxyl group, and that the second oxygen atom wi probably present in an etheric linkage. It was also known that on oxid ... [Pg.86]

The ant Iridomyrmex pruinosus utilizes 2-heptanone as an alarm pheromone. Figure 17 illustrates the existence of a close correlation of the similarity between 2-heptanone and its analogs in molecular model silhouettes with their alarm activity45. It is noteworthy that the replacement of the methylene group in position 3 of 2-heptanone by the ether linkage yields n-butyl acetate which has the same activity as the natural pheromone. Considerable activity is still retained even when the carbonyl group is replaced by the hydroxyl group. [Pg.107]

Monosaccharides can differ in their formulas, their ring sizes, and the spatial orientations of their hydroxyl groups. To analyze the differences between two monosaccharides, begin with structural drawings of the molecules, oriented so the ether linkages are in comparable positions. Then examine the stmctures to locate differences in constituents and bond orientations. [Pg.922]

The A-type proanthocyanidins are characterized by a second ether linkage between an A-ring hydroxyl group of the lower unit and C-2 of the upper unit. Since they are less frequently isolated from plants than the B-types, they have been considered unusual structures [18,19]. The first identified A-type proanthocyanidin was procyanidin A2 isolated from the shells of fruit of Aes-culus hippocastanum. Since then, many more A-type proanthocyanidins have been found in plants, including dimers, trimers, tetramers, pentamers and ethers [18,21]. [Pg.242]

The structural features of this group are summarized as follows (1) possession of an acetal or a hemiacetal ether linkage between C-8 and C-10, and (2) either absence of a substituent or presence of a hydroxyl group or ester moiety at C-6. Because a large number of hasubanan alkaloids follow this cleavage pattern, the metaphanine-type cleavage may be one of the primary pattern for all hasubanan alkaloids (76). [Pg.316]

Figure 1.30 Hydroxyl groups within sugar residues may undergo alkylation or acylation reactions, forming ether or ester linkages. Figure 1.30 Hydroxyl groups within sugar residues may undergo alkylation or acylation reactions, forming ether or ester linkages.
An example of the use of 1,4-butanediol diglycidyl ether for the activation of soluble dex-tran polymers is given in Chapter 25, Section 2.3. One end of the fezs-epoxide reacts with the hydroxylic sugar residues of dextran to form ether linkages, which terminate in epoxy functionalities. The epoxides of the activated derivative then can be used to couple additional mol-ecules-containing nucleophilic groups to the dextran backbone. [Pg.269]

Porath, 1974). B/s-oxirane compounds also can be used to introduce epoxide groups into soluble dextran polymers in much the same manner (Boldicke et al., 1988 Bocher et al., 1992). The epoxide group reacts with nucleophiles in a ring-opening process to form a stable covalent linkage. The reaction can take place with primary amines, sulfhydryls, or hydroxyl groups to create secondary amine, thioether, or ether bonds, respectively (Chapter 2, Section 1.7). [Pg.957]

See other pages where Hydroxyl group Ether linkage is mentioned: [Pg.936]    [Pg.7]    [Pg.61]    [Pg.98]    [Pg.241]    [Pg.354]    [Pg.139]    [Pg.141]    [Pg.218]    [Pg.339]    [Pg.87]    [Pg.224]    [Pg.235]    [Pg.238]    [Pg.238]    [Pg.248]    [Pg.347]    [Pg.400]    [Pg.565]    [Pg.580]    [Pg.267]    [Pg.220]    [Pg.95]    [Pg.716]    [Pg.345]    [Pg.404]    [Pg.129]    [Pg.67]    [Pg.921]    [Pg.103]    [Pg.173]    [Pg.224]    [Pg.69]    [Pg.40]    [Pg.938]    [Pg.318]   
See also in sourсe #XX -- [ Pg.796 ]



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Ether group

Ether linkages

Ethereal linkages

Linkage groups

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