胰岛素的化学稳定性。4. 药物配方中化学转化的机理和动力学。

Acta pharmaceutica Nordica Pub Date : 1992-01-01
J Brange
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引用次数: 0

摘要

胰岛素通过多种化学反应分解[1-3]。它在两个不同的残基上通过完全不同的机制进行脱酰胺。在酸中,AsnA21的脱酰胺是由质子化的c末端在分子内催化的,而在pH 6以上,AsnB3残基上形成中间亚胺,导致异Asp和Asp衍生物。亚胺的形成需要在B3的α -碳/肽羰基碳键周围进行大的旋转,对应于b链n端10 a的移动。决定B3脱酰胺速率以及两种产物形成比例的主要因素是局部构象结构,而这种构象结构受各种赋形剂和胰岛素的物理状态的影响很大。在几个六聚体间官能团和Zn2+的协同催化作用下,在菱面体胰岛素晶体中,a链发生了惊人的类似热溶素的自蛋白水解裂解。胰岛素分子的分子间共价交联通过几种机制发生。最突出的机制类型是n端氨基水解,导致与残基GlnA15、AsnA18和AsnA21的a链侧链酰胺形成异肽键。同一类型的反应还导致鱼精蛋白的n端与胰岛素的共价交联。二硫交换反应由A7-B7二硫桥的裂解引发,主要导致共价低聚物和聚合物的形成。中性脱酰胺反应和氨解反应的活化能分别为80和119 KJ/mol。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chemical stability of insulin. 4. Mechanisms and kinetics of chemical transformations in pharmaceutical formulation.

Insulin decomposes by a multitude of chemical reactions [1-3]. It deamidates at two different residues by entirely different mechanisms. In acid, deamidation at AsnA21 is intramolecularly catalyzed by the protonated C-terminal, whereas above pH 6 an intermediate imide formation at residue AsnB3 leads to isoAsp and Asp derivatives. The imide formation requires a large rotation around the alpha-carbon/peptide carbonyl carbon bond at B3, corresponding to a 10 A movement of the B-chain N-terminal. The main determinant for the rate of B3 deamidation, as well as for the ratio between the two products formed, is the local conformational structure, which is highly influenced by various excipients and the physical state of the insulin. An amazing thermolysin-like, autoproteolytic cleavage of the A-chain takes place in rhombohedral insulin crystals, mediated by a concerted catalytic action by several, inter-hexameric functional groups and Zn2+. Intermolecular, covalent cross-linking of insulin molecules occurs via several mechanisms. The most prominent type of mechanism is aminolysis by the N-terminals, leading to isopeptide linkages with the A-chain side-chain amides of residues GlnA15, AsnA18 and AsnA21. The same type of reaction also leads to covalent cross-linking of the N-terminal in protamine with insulin. Disulfide exchange reactions, initiated by lysis of the A7-B7 disulfide bridge, lead mainly to formation of covalent oligo- and polymers. Activation energy (Ea) for the neutral deamidation and the aminolysis reactions was found to be 80 and 119 KJ/mol, respectively.

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