Sites stability, viii

X) for VIII (13) y iii) theoretical calculations indicating unusually high contributions of the polar resonance form VII (15) and iv) association with a proton or metal ion at the nitroso oxygen, the site of the highest electron density (14). The structure of nitrosamines is more realistically represented by the resonance hybrid VIII which explains the extraordinary stability of nitrosamines towards acids and bases in contrast to the lability of nitrosamides I under dilute acidic and basic conditions. ... 

Two examples where metal ions confer stability or increased activity in proteins are human deoxyribonuclease (rhDNase, Pulmozyme ), and Factor VIII. In the case of rhDNase, Ca2+ ions (up to 100 mM) increased the stability of the enzyme through a specific binding site (64). In fact, the removal of calcium ions from the solution with EGTA caused an increase in deamidation and aggregation. However, this effect was observed only with Ca+2 ions other divalent cations, Mg2+, Mn2+, and Zn2+, were observed to destabilize rhDNase. Similar effects were observed in Factor VIII. Ca2+ and Sr2+ ions stabilized the protein, whereas others such as Mg2+, Mn2+ and Zn2+, Cu2+, and Fe2+ destabilized the enzyme (65). In a separate study with Factor VIII, a significant increase in the aggregation rate was observed in the presence of Al3+ ions (66). The authors note that other excipients like buffer salts are often contaminated with Al3+ ions and illustrate the need to use excipients of appropriate quality in formulated products. 

Compound I must be activated by the strongly acidic medium. One possible protonation site is the basic pyrrolidinium nitrogen atom (structure X), which would favor the formation of carbenium ion XI (see Scheme 16.3). This intermediate would gain additional stabilization from the polar solvent. Conditions for an SnI substitution would prevail to yield XII, whose fragmentation would resemble, formally speaking, the retro cycloaddition process used in the synthesis of I (i.e., VIII - I). The resulting ketone (XIII) would contain the elements required for the construction of a five-membered carbocycle with the desired incorporation of the functional carbon of one of the nitrile groups, as... 

In the polymerization of ethylene by (Tr-CjHsljTiClj/AlMejCl [111] and of butadiene by Co(acac)3/AlEt2Cl/H2 0 [87] there is evidence for bimolecular termination. The conclusions on ethylene polymerization have been questioned, however, and it has been proposed that intramolecular decomposition of the catalyst complex occurs via ionic intermediates [91], Smith and Zelmer [275] have examined several catalyst systems for ethylene polymerization and with the assumption that the rate at any time is proportional to the active site concentration ([C ]), second order catalyst decay was deduced, since 1 — [Cf] /[Cf] was linear with time. This evidence, of course, does not distinguish between chemical deactivation and physical occlusion of sites. In conjugated diene polymerization by Group VIII metal catalysts -the unsaturated polymer chain stabilizes the active centre and the copolymerization of a monoolefin which converts the growing chain from a tt to a a bonded structure is followed by a catalyst decomposition, with a reduction in rate and polymer molecular weight [88]. 

A possible mechanism for the stabilization of PFAP (II) with bis (8-oxyquinolate)zinc(II) involves complexation of this zinc compound with POH moieties (IV) to form thermally and hydrolytically stable sites (VIII). 

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