光敏性
光降解
化学
降级(电信)
生物物理学
荧光
有效载荷(计算)
活性氧
光化学
紫外线
紫外线
光解
单线态氧
辐照
热稳定性
双特异性抗体
组合化学
效力
结合
氧化应激
生物化学
DNA损伤
脚印
作用机理
臭氧消耗
合理设计
作者
Feng Liu,Wei Song,Shuang Jia,Guanghui Wang,Xue Zhang,Chen Lyu,Dahui Xing,Yidi Qu,Bo Liu,Renbo Yu,Sukai Li,Renjun Gao,Jinliang Zhang
标识
DOI:10.1016/j.ejps.2025.107374
摘要
Bispecific Antibody-Drug Conjugates (BsADCs) represent a promising class of targeted therapeutics, combining the bispecific targeting with the potency of cytotoxic payloads. However, their inherent structural complexity poses unique stability and photosensitivity challenges in development, manufacturing, and storage. In this study, we assessed the stability of three BsADCs under different light sources. Fluorescent lamp consistently induced BsADCs photodegradation, implicating its ultraviolet component as a key driver. Subsequent research results on the mechanism of photodegradation indicated that the fluorescent lamp-induced instability in BsADCs is primarily driven by the generation of reactive oxygen species from the payload upon photoexcitation, which subsequently induces photodegradation of the BsADCs. Notably, BsADCs exhibited significantly higher oxidation at conventional methionine residues of the Fc region than unconjugated parental bispecific antibodies (BsAbs). Integrated with the results from the carboxyl group footprinting and thermal stress study, suggested the structural differences between BsADCs and parental BsAbs. Our findings highlight that payload-mediated photoreactivity and structural alterations upon conjugation are critical factors contributing to the photodegradation of BsADCs compared with parental BsAbs. These insights underscore the importance of rigorous photostability assessment and appropriate light protection strategies throughout BsADCs development, manufacturing, and storage.
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