Trastuzumab deruxtecan (TDXD) and datopotamab deruxtecan (Dato-DXd) share the same cytotoxic payload, yet Dato-DXd has a much lower rate of interstitial lung disease (ILD). This indicates the toxicity is driven by the antibody-antigen interaction, not the payload itself.

Different TROP2-targeted ADCs using the same class of payload (topo-1 inhibitor) display distinct primary toxicities, such as diarrhea versus stomatitis. This highlights that subtle differences in drug-to-antibody ratio and linker technology create unique pharmacological profiles, making the drugs clinically distinct despite their apparent similarities.

Despite targeting the same protein (Trope-2), different ADCs like sacituzumab govitecan (SG) and sacituzumab tirumotecan (sac-TMT) exhibit unique toxicity profiles due to their different linker-payloads. Clinicians must be prepared for diarrhea with SG versus oral mucositis with sac-TMT, requiring distinct mitigation strategies for drugs that otherwise seem very similar.

The modern pipeline of antibody-drug conjugates in solid tumors has largely moved away from older microtubule toxin payloads (like DM4 or MMAE). The majority of ADCs currently in development, and the focus of clinical excitement, utilize camptothecin-based payloads, specifically topoisomerase-1 inhibitors like deruxtecan, reflecting a major technological evolution in the field.

With multiple ADCs available, an emerging sequencing strategy is to alternate between different mechanisms of action, such as following a microtubule toxin-based ADC with a topoisomerase-1 inhibitor payload. This approach aims to avoid compounding specific toxicities, like neuropathy, and potentially circumvent resistance, though it is a strategy born from logic rather than clinical trial data.

When sequencing antibody-drug conjugates, clinical experience suggests that resistance to the chemotherapy payload is a primary driver of failure. Therefore, oncologists tend to avoid using another ADC with the same payload consecutively, preferring to switch both target and payload if possible.

The primary reason Antibody-Drug Conjugates (ADCs) stop working is payload resistance, a shift from the traditional belief that failure stems from tumors losing the target antigen. This insight drives development of multi-payload ADCs to overcome this resistance mechanism.

Experts question the efficacy of sequencing ADCs like EV (Nectin-4 target) and DV (HER2 target) because they share the same MMAE chemo payload. Since resistance is often tied to the payload, not the target antibody, switching targets may not overcome resistance, though anecdotal responses have been observed.

Despite both being Trop-2 targeted antibody-drug conjugates, Sacituzumab Govitecan and Datopotomab duroxotein have distinct side effects due to different linkers and payloads. Sacituzumab causes neutropenia and diarrhea, while Datopotomab is linked to stomatitis and ocular issues, requiring unique management strategies.