Functionalized, covalent binding

Clarke and Shannon also supported copper bis(oxazoline) complexes onto the surfaces of inorganic mesoporous materials, such as MCM-41 and MCM-48, through the covalent binding of the ligand, modified by alkoxysilane functionalities [59]. The immobilized catalysts allowed the cyclopropanation of styrene with ethyldiazoacetate to be performed as for the corresponding homogeneous case, and were reused once with almost no loss of activity or selectivity. 

The first is cell injury (cytotoxicity), which can be severe enough to result in cell death. There are many mechanisms by which xenobiotics injure cells. The one considered here is covalent binding to cell macromol-ecules of reactive species of xenobiotics produced by metabolism. These macromolecular targets include DNA, RNA, and protein. If the macromolecule to which the reactive xenobiotic binds is essential for short-term cell survival, eg, a protein or enzyme involved in some critical cellular function such as oxidative phosphorylation or regulation of the permeability of the plasma membrane, then severe effects on cellular function could become evident quite rapidly. 

The presence of chemically reactive structural features in potential drug candidates, especially when caused by metabolism, has been linked to idiosyncratic toxicity [56,57] although in most cases this is hard to prove unambiguously, and there is no evidence that idiosyncratic toxicity is correlated with specific physical properties per se. The best strategy for the medicinal chemist is avoidance of the liabilities associated with inherently chemically reactive or metabolically activated functional groups [58]. For reactive metabolites, protein covalent-binding screens [59] and genetic toxicity tests (Ames) of putative metabolites, for example, embedded anilines, can be employed in risky chemical series. 

The search for cavitand tectons can be achieved through covalent binding of cavitands, as well as reversible association through lower rim functionalities, such as H-bonding or metal ion coordination [96]. 

The (3-lactam antibiotics structurally resemble the terminal D-alanyl-D-alanine (o-Ala-o-Ala) in the pen-tapeptides on peptidoglycan (murein) (Fig. 45.1). Bacterial transpeptidases covalently bind the (3-lactam antibiotics at the enzyme active site, and the resultant acyl enzyme molecule is stable and inactive. The intact (3-lactam ring is required for antibiotic action. The (3-lactam ring modifies the active serine site on transpeptidases and blocks further enzyme function. 

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