Next Generation Antibody Drug Conjugates: What Is Changing in Antibodies, Linkers, and Payloads

Antibody drug conjugates (ADCs) couple a monoclonal antibody to a cytotoxic payload through a designed linker to deliver targeted chemotherapy while limiting off target effects. As of the mid twenty twenties, reviews report around fifteen ADCs approved by the United States Food and Drug Administration and more than one hundred ADCs in clinical development worldwide. These numbers position ADCs as a relatively mature but still fast evolving modality.

Why Design Choices Matter

Clinical performance and safety are tightly linked to the three core components of an ADC: the antibody, the linker, and the payload.

• The antibodydrives target recognition and internalization.
• The linkermust remain stable in circulation, yet release the payload after internalization.
• The payloadprovides the cytotoxic effect once delivered.

Together, these design choices determine specificity, exposure, and toxicity profiles. For readers exploring partners that can offer antibody selection, linker chemistry, payload strategy, and analytics within a single organization, there are antibody drug conjugate services that cover everything from design through IND support.

Learning From Early Experience

First generation ADCs established proof of concept but also revealed design risks. Gemtuzumab ozogamicin, the first approved ADC, experienced challenges with linker stability that could lead to premature payload release in circulation, contributing to adverse effects and a temporary market withdrawal before later label revisions.

These early lessons accelerated advances in antibody humanization, linker chemistry, and payload selection that now define newer ADCs.

The Evolution of ADC Generations

The development of ADCs is often described in generations, each marked by improvements in the three core components:

• First generation:Relied on murine antibodies and non cleavable linkers, often with immunogenicity and limited efficacy.
• Second generation:Adopted humanized or fully human antibodies, with better linker stability and more potent payloads.
• Third generation:Introduced more controlled conjugation methods and optimized drug to antibody ratios, which reduced aggregation and off target toxicity.
• Fourth generation:Enables higher effective drug loading while maintaining safety. Agents such as trastuzumab deruxtecan and sacituzumab govitecan illustrate this trend, showing higher average drug to antibody ratios alongside improved clinical performance.

Antibody Engineering

Modern ADCs typically use humanized or fully human monoclonal antibodies. This approach helps minimize immunogenicity while preserving high affinity for tumor antigens and efficient internalization.

Antibody selection and epitope targeting influence tumor penetration, intracellular trafficking, and payload delivery. Beyond whole IgG, research is exploring engineered fragments such as Fab segments that may provide improved internalization or tumor penetration for specific targets.

Linker Chemistry as a Performance Lever

Linker design must balance stability in plasma with efficient release at the target site.

• Cleavable linkersrespond to intracellular conditions such as pH, redox environment, or specific enzymes.
• Non cleavable linkersrequire complete antibody degradation to release the active payload.

Advances in linker hydrophilicity and stability help counteract payload hydrophobicity, enable better control of drug to antibody ratio, and reduce premature payload release. The result is a wider therapeutic window and more consistent exposure profiles.

Payload Selection and the Bystander Effect

Different payload classes deliver different pharmacology.

Topoisomerase I inhibitors such as deruxtecan can produce a bystander effect, in which a membrane permeable payload diffuses into adjacent tumor cells. This can be valuable in heterogeneous tumors where not every cell expresses the target antigen.

By contrast, payloads such as MMAF tend to be less membrane permeable and generally do not produce a strong bystander effect. This distinction influences payload selection based on target expression patterns and tumor microenvironment.

Lessons From Early ADC Setbacks

The temporary withdrawal of gemtuzumab ozogamicin highlighted the risks associated with linker instability and demonstrated the importance of pharmacokinetic control. Other early ADCs struggled with heterogeneous drug to antibody ratios, aggregation, and dose limiting toxicities.

These challenges underscored the need for more precise conjugation chemistry, advanced analytics, and tighter quality control. Modern ADC platforms now use site specific conjugation and improved linker chemistry to produce more uniform constructs with safer and more predictable therapeutic windows.

What Biotechs Should Seek in an ADC Services Partner

For companies entering the ADC field, the choice of development partner can determine whether a program moves smoothly or runs into costly delays. Common evaluation criteria include:

• Antibody optimization and internalization testing:Ability to confirm that the target antigen is suitable and that the antibody internalizes efficiently.
• Conjugation platform breadth:Access to site specific conjugation, controlled drug to antibody ratios, and chemistries compatible with different payload classes.
• Linker and payload toolbox:A range of stable cleavable and non cleavable linkers, plus clinically validated payload classes suited to the program’s indication.
• Advanced analytics:Capability for intact mass analysis, drug to antibody ratio distribution, aggregation assessment, and stability testing under defined stress conditions.
• Mechanism aligned bioassays:Systems for evaluating cytotoxicity, assessing bystander effect when relevant, and performing pharmacokinetic modeling.
• Regulatory documentation and scale up:Experience preparing IND ready packages and supporting transition from clinical to commercial scale.

Beyond biologics and conjugation chemistry, ADC programs also depend on a reliable supply of high-quality small-molecule payloads. Robust API manufacturing underpins this part of the value chain by ensuring scalable synthesis, tight control of impurities, and appropriate containment for highly potent compounds. Partnering with specialists in API manufacturing can help biotechs align process development, safety, and regulatory expectations long before commercial scale is reached.

The Road Ahead: Fourth Generation ADCs and Beyond

ADC design is moving toward higher drug loading with preserved safety, enabled by more hydrophilic linkers and increasingly refined conjugation techniques. Novel constructs, including engineered antibody fragments, are being investigated to improve tumor penetration and internalization.

While oncology remains the primary focus, there is growing interest in applying ADC strategies to other disease areas. Expanding research and development investment and a record number of regulatory designations for ADCs suggest that this modality will remain an important growth area in oncology and beyond. 

Final Thoughts

Antibody drug conjugates have progressed from early proof of concept molecules with significant safety limitations to established therapies with rapidly evolving design strategies. Today’s ADCs benefit from humanized antibodies, stable linker chemistries, and payloads tailored to specific tumor environments. For biotechs, success in this space often depends on integrating antibody discovery, conjugation chemistry, advanced analytics, and regulatory support into a single continuum, enabling faster and more reliable translation from concept to clinic.