Generation of anti-SN38 antibody for loading efficacy and therapeutic monitoring of SN38-containing therapeutics.

SN38, one of the most potent anti-tumor analogues of the camptothecins (CPTs), has limitations in its direct formulation as an anticancer agent due to its super toxicity and poor solubility in water and pharmaceutically approved solvents. However, it has garnered significant scientific interest as a payload in conjugated nanomedicine platforms (e.g., SN-38lip, NK012, SNB-101, and ADCs) to enhance their effectiveness and safety. The development of these platforms necessitates a convenient quantitative determination of SN38 in preclinical and clinical studies, a need that our study directly addresses, offering a practical solution to a pressing problem in cancer research and drug development. This study details the meticulous process of generating poly and monoclonal antibodies (pAb and mAb) against SN38 and their application to measure the SN38 in naked and conjugated forms of SN38-conjugated ADCs. For this purpose, two haptens of SN38 were synthesized by introducing the glycine or 4-amino-4-oxobutanyol(glycine) moiety as a conjugation functional group of the SN38. IR, NMR and mass spectrometric techniques confirmed the chemical modifications of the haptens. The haptens were then conjugated to each bovine serum albumin (BSA) and keyhole limpet hemocyanin (KLH) protein. The SN38-KLH conjugates were meticulously examined for immunization and generation of pAb and mAb. The immunization efficiency, reactivity, binding affinity, specificity, and cross-reactivity of purified pAb and mAb against Irinotecan, a model for the emergence of an SN38 derivative in clinical settings, were evaluated using ELISA and western blotting (WB) techniques. Conjugation efficiency of the SN38 to the KLH was increased using 4-amino-4-oxobutanyol(glycine) moiety, as its immunization efficacy was more to generate pAb. Furthermore, only this hapten could immunized mice to generate mAb recognizing SN38 with nanomolar equilibrium affinity. Our recent findings strongly support the notion that the generated pAb employed in developing an ELISA effectively ascertains the presence of SN38 in SN38-conjugated ADC, with a test midpoint EC of 2.5 μg/mL. Our study's unique contribution to the field lies in the development of specific antibodies against SN38 for measuring it on ADC, a feat that has not been achieved before. These immunoassays can be readily applied to detect other SN38-conjugate therapeutic platforms, thereby enhancing their clinical knowledge translation. The affinity of both pAb and mAb also meets the acceptance criteria for quantifying SN38 in fluidic material, as well as in Therapeutic drug monitoring (TDM) studies, a crucial aspect of personalized medicine. The potential applications of the anti-SN38 antibodies extend to reducing SN38-induced systemic toxicity through an inverse targeting strategy, a novel approach that piques further interest in our findings.