Frustration with traditional antibody discovery, which captures only 1% of a sample's B-cell diversity, led to Memo's microfluidics platform. CEO Erik van den Berg states their technology retains over 80% of the B-cell information, enabling the discovery of rare, super-potent human antibodies that would otherwise be lost.
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In the real world, the selection of a therapeutic modality like an antibody or peptide is often driven by a company's existing expertise and technology platform rather than a purely agnostic approach to finding the single best tool for a clinical problem. Organizations default to the tools in their toolbox.
To overcome the industry bottleneck of few validated solid tumor targets (15-20), Memo analyzes tumor-infiltrating B-cells from patients with superior outcomes. This approach aims to identify unique antibody-target pairs, unlocking new biological pathways for next-generation therapies like ADCs and CAR-Ts.
The relationship between a multi-specific antibody's design and its function is often non-intuitive. LabGenius's ML platform excels by exploring this complex "fitness landscape" without human bias, identifying high-performing molecules that a rational designer would deem too unconventional or "crazy."
Enara Bio's discovery platform wasn't outsourced. It was built internally with integrated computational biology, mass spectrometry, and immunology teams. The CEO believes the most significant innovation and "magic" happens at the interface between these disciplines, a synergy only possible with close internal collaboration.
Contrary to the popular belief that antibody development is a bespoke craft, modern methods enable a reproducible, systematic engineering process. This allows for predictable creation of antibodies with specific properties, such as matching affinity for human and animal targets, a feat once considered a "flight of fancy."
To overcome on-target, off-tumor toxicity, LabGenius designs antibodies that act like biological computers. These molecules "sample" the density of target receptors on a cell's surface and are engineered to activate and kill only when a specific threshold is met, distinguishing high-expression cancer cells from low-expression healthy cells.
Traditional antibody optimization is a slow, iterative process of improving one property at a time, taking 1-3 years. By using high-throughput data to train machine learning models, companies like A-AlphaBio can now simultaneously optimize for multiple characteristics like affinity, stability, and developability in a single three-month process.
The long history of now-commonplace technologies like monoclonal antibodies serves as a crucial reminder for the biotech industry. What appears to be an overnight success is often the culmination of decades of hard, incremental scientific work, highlighting the necessity of patience and long-term perspective.
Many innovative drug designs fail because they are difficult to manufacture. LabGenius's ML platform avoids this by simultaneously optimizing for both biological function (e.g., potency) and "developability." This allows them to explore unconventional molecular designs without hitting a production wall later.
The future of biotech moves beyond single drugs. It lies in integrated systems where the 'platform is the product.' This model combines diagnostics, AI, and manufacturing to deliver personalized therapies like cancer vaccines. It breaks the traditional drug development paradigm by creating a generative, pan-indication capability rather than a single molecule.
