Cell line development is a critical determinant of success in biologics manufacturing. It lays the foundation for product yield, quality and long-term process stability. Yet, despite major advances in host engineering, vector systems and culture conditions, early-stage clone selection remains one of the least analytically supported stages of development.¹

Therapeutic proteins, including monoclonal antibodies, enzymes and fusion proteins, are now central to modern treatment strategies for cancer, autoimmune conditions and genetic disorders. For each of these modalities, a well-characterised and scalable production cell line is essential. This makes cell line development not just a technical necessity, but a strategic priority for biopharmaceutical developers.

In practice, decisions about which clones to progress are often based on incomplete or delayed data, typically obtained only after expansion or purification. This not only introduces inefficiency but also increases the risk of overlooking high-performing candidates. As the pace of biologics development accelerates, the gap between biological complexity and analytical capability becomes harder to ignore. Speed and confidence in cell line selection can ultimately be the difference between a successful biologic and a stalled program. To address this, developers are increasingly turning to in-process analytical tools, such as rapid protein quantification platforms, to gain earlier insight and support more data-driven selection workflows.

This challenge is illustrated in Figure 1, which maps a typical cell line development process and highlights key decision points where data is often limited or delayed.