Chelating ability

The extraction of metal ions depends on the chelating ability of 8-hydroxyquinoline. Modification of the stmcture can improve its properties, eg, higher solubility in organic solvents (91). The extraction of nickel, cobalt, copper, and zinc from acid sulfates has been accompHshed using 8-hydroxyquinohne in an immiscible solvent (92). In the presence of oximes, halo-substituted 8-hydroxyquinolines have been used to recover copper and zinc from aqueous solutions (93). Dilute solutions of heavy metals such as mercury, ca dmium, copper, lead, and zinc can be purified using quinoline-8-carboxyhc acid adsorbed on various substrates (94). 

Yilmaz and Deligoz [47,48] prepared a calix[6]arene substituted with six aminoglyoxime groups (2), and two Wc-dioxime compounds of calix[4]arene (3,4), and they examined their chelating ability with Co, Cu, and NF. ... 

The nucleophilic addition of Grignard reagents to a-epoxy ketones 44 proceeds with remarkably high diastereoselectivity70. The chelation-controlled reaction products are obtained in ratios >99 1 when tetrahydrofuran or tetrahydrofuran/hexamethylphosphoric triamide is used as reaction solvent. The increased diastereoselectivity in the presence of hexamethylphos-phoric triamide is unusual as it is known from addition reactions to a-alkoxy aldehydes that co-solvents with chelating ability compete with the substrate for the nucleophile counterion, thus reducing the proportion of the chelation-controlled reaction product (vide infra). 

Morel et al. (1993) have reported that three flavanoids (catechin, quercetin and diosmetin) are cytoprotective on iron-loaded hepatocyte cultures. Their cytoprotective activity (catechin > quercetin > diosmetin) correlated with their iron-chelating ability (Morel et al., 1993). These compounds should also be good phenolic antioxidants so iron chelation may only be part of the story. 

The potential for coordination depends on the oxy substituents.82 Alkoxy substituents are usually chelated, whereas highly hindered silyloxy groups usually do not chelate. Trimethylsiloxy groups are intermediate in chelating ability. The extent of chelation also depends on the Lewis acid. Studies with a-alkoxy and (3-alkoxy aldehydes with lithium enolates found only modest diastereoselectivity.83... 

In a separate study, Igwe and Abia46 determined the equilibrium adsorption isotherms of Cd(II), Pb(II), and Zn(II) ions and detoxification of wastewater using unmodified and ethylenediamine tetraacetic acid (EDTA)-modified maize husks as a biosorbent. This study established that maize husks are excellent adsorbents for the removal of these metal ions, with the amount of metal ions adsorbed increasing as the initial concentrations increased. The study further established that EDTA modification of maize husks enhances the adsorption capacity of maize husks, which is attributed to the chelating ability of EDTA. Therefore, this study demonstrates that maize husks, which are generally considered as biomass waste, may be used as adsorbents for heavy metal removal from wastewater streams from various industries and would therefore find application in various parts of the world where development is closely tied to affordable cost as well as environmental cleanliness.46... 

The strong chelating ability of (multi)amino(multi)carboxylate ligands renders complexes of bismuth substantially more hydrolytically stable than those of bifunctional aminocarboxylate ligands (e.g., glycine). Several compounds have been successfully examined as ligands for bismuth, in that complexes are readily isolable as molecular systems with weak intermolecular interactions. The extent and diversity of these complexes is enhanced by substituent derivatization with, for example, cyclohexyl (e.g., cydtpa) and alkoxyethyl (e.g., oedta) groups. 

Addition of the indium reagent derived from the foregoing (P)-allenylstannane to /8-benzyloxy-a-methylpropanal as the aldehyde substrate at low temperature afforded a 70 30 mixture of anti,anti and anti,syn adducts (Eq. 9.141). The improved dia-stereoselectivity in this case can be attributed to substrate control, reflecting the chelating ability of an OBn versus an ODPS group. The lower temperature may also account for the improved diasteroselectivity. 

In the adsorption of some metal ion by tannin adsorbents [16], tannins are widely distributed in nature and have multiple adjacent phenolic hydroxyl groups and exhibit specific chelation ability toward metal ions [17]. According to the chemical stractures of tannins, they can usually be classified into hydrolyzable tannins, condensed tannins and complex tannins. Hydrolyzed tannins yield galhc acid or ellagic acid when hydrolyzed by acid, base or some enzymes [18]. Turkish sumac tannin (hydrolyzable tannin) is illustrated in Fig. 28.1 whose basic stracture is of flavan-3-ols. 

Ihnat and coworkers substituted the primary amine group with a series of gradually increasing alkyl amides 113-119, aromatic amides 120 and 121, succinamide 122 and methylsulfonamide 123 with a systematic increase in partition coefficient (octanoFwater), to increase permeability while retaining iron-chelating ability. The formamide derivative... 

As expected, system 13 did in fact bind and transport zwitterionic a-amino acids through a model membrane barrier with good selectivity under conditions where the porphyrin-derived control system (14), lacking the carboxylate anion chelation ability inherent in 13, would not. Specifically, it was found that at neutral pH compound 13 acts as a very efficient carrier for the through model membrane (H2O-CH2CI2-H2O) transport of phenylalanine and tryptophan. Further, in direct competition experiments, L-phenylalanine was found to be transported four times faster than L-tryptophan and 1000 times faster than L-tyrosine. As implied above, little or no transport was observed when a porphyrin control (14) was used. Nor was significant transport observed when a mixture of sapphyrin and lasalocid was used. 

MRNi was found to correlate with the chelating ability of the modifying reagent. However, as mentioned in Section III,A, the hydrogenation activity of the catalyst was not affected, but rather enhanced, by the modification. The phenomenon which has a close connection with the above finding was observed in the hydrogenation of MAA mentioned in Section III,B. The hydrogenation of MAA with RNi could not be carried out at atmospheric pressure due to corrosion of the catalyst by MAA (32, 34). 

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