MassBio is partnering with the Genezen viral vector CDMO team on May 11 to host R&D Reimagined – Advanced Modalities, the first in a series of events designed to connect biotech and pharma R&D leadership with the technology innovators and solution providers transforming the life sciences with new tools and services.
The cell and gene therapy (CGT) field is entering a new phase of maturity, increasingly defined by the industry’s ability to deliver therapies at scale.
For years, lentiviral (LV) and adeno-associated viral (AAV) vectors have dominated the conversation. But today, gammaretroviral vectors (RVVs) are re-emerging as a powerful and relevant gene delivery tool, particularly in ex vivo applications like CAR-T therapies, where they already have a proven commercial track record.
This momentum reflects advances in vector design, including self-inactivating constructs, and a reassessment of how vector systems match therapeutic goals. But as interest in RVVs grows within the CGT space, a critical realization is coming into focus: the true inflection point for retroviral innovation lies in manufacturing.
From feasibility to scalability: Where programs stall
Many retroviral programs don’t fail in early development. Instead, they most often stall when transitioning to clinical and commercial manufacturing. This gap between feasibility and scalability remains one of the most persistent challenges in CGT today.
A core issue is the continued reliance on legacy production approaches. Adherent systems like roller bottles and multilayer flasks have served the field well, but they inherently limit scalability. Expanding production with these systems typically means scaling out (adding more units) rather than scaling up, which introduces variability and increases contamination risk, while also placing strain on facility infrastructure.
At the same time, the biological nature of RVVs introduces additional complexity. RVVs are enveloped and structurally fragile, making them highly sensitive to shear forces and downstream processing conditions. This limits the use of more aggressive purification techniques and forces developers to carefully balance yield, purity and vector integrity.
These hurdles are both technical and strategic, influencing the cost of goods and regulatory readiness, consequently impacting whether a therapy reaches patients in a viable and sustainable way.
Rethinking manufacturing through innovation
What’s encouraging is that the industry is no longer trying to force RVVs into outdated frameworks. Instead, we’re seeing a shift toward purpose-built manufacturing strategies that align with the vector’s biology.
Upstream, the transition to fixed-bed bioreactors and the adoption of stable producer cell lines are enabling higher cell densities, improved consistency and more controlled environments. These systems reduce variability and support more reproducible scale-up, both critical factors as programs move toward commercialization.
Serum-free processes are also gaining traction, helping to eliminate variability associated with animal-derived components while simplifying downstream purification. Cleaner harvests and more defined conditions translate into greater process control and improved regulatory confidence.
Downstream, innovation is equally important, but often more nuanced. Rather than relying on harsh purification methods, the focus is shifting toward gentle, filtration-based approaches that preserve vector integrity while still achieving the required purity. This requires a deeper understanding of vector behavior and a more integrated approach to process design.
These advances signal a broader evolution: manufacturing is now a core driver of therapeutic success, rather than an afterthought
The experience gapand why it matters
Despite this progress, one of the most underappreciated challenges in retroviral development is the industry-wide experience gap.
Much of the practical knowledge around large-scale RVV production remains concentrated within a small number of organizations, often tied to early commercial CAR-T programs. As a result, many developers, particularly emerging biotechs, are navigating complex manufacturing decisions without access to established best practices.
This lack of shared experience can lead to inefficiencies, delays and costly rework, especially when analytical strategies and process development are not aligned early. For example, if critical quality attributes (CQAs) are not defined early and supported by robust, phase-appropriate assays, developers can struggle to demonstrate comparability as processes change, increasing the risk of regulatory delays, additional validation work and costly setbacks.
Closing this gap will require closer collaboration across the entire CGT ecosystem, with more open knowledge sharing, a readiness to challenge old ways of working and a focus on integrated development strategies.
A shift in mindset: From capacity to capability
As the CGT field continues to evolve, it’s becoming clear that success in retroviral manufacturing relies on deep technical expertise and integrated analytical frameworks, as well as the ability to adapt processes to the unique demands of each program.
This is particularly important as therapies become more complex and timelines more compressed. Developers need manufacturing strategies that are not only scalable but also flexible, capable of evolving alongside scientific advancements without introducing unnecessary risk.
Looking ahead, the next wave of CGT innovation will be defined by those who can bridge the gap between discovery and delivery. RVVs have a critical role to play in that future, but unlocking their full potential will depend on how effectively we address the manufacturing challenge.
For those navigating this landscape, a deeper exploration of the evolving retroviral ecosystem, including emerging technologies, process innovations and strategic considerations, is captured in Retroviral vectors: Shaping the next wave of cell and gene therapy innovation.
About the Author
Susan D’Costa is a molecular virologist spanning 25 years of experience in virology. Over the past ten years she has been actively involved in viral vector analytics, process development, manufacturing, and building successful teams. She is currently the Chief Technical and Commercial Officer at Genezen, a leading gene and cell therapy CDMO. Prior to Genezen, Susan was CTO at Alcyone Therapeutics, a biotechnology company pioneering next-generation CNS precision gene-based therapeutics for complex neurological conditions. At Alcyone, she was responsible for viral vector CMC, device development operations and partnering on new technologies for both gene therapy and precision delivery. Dr. D’Costa has also held leadership roles of increasing responsibility at Thermo Fisher Scientific, Viral Vector Services and its predecessor companies – Brammer Bio and Florida Biologix, working with different viral vectors, liaising with diverse biotech clients and building teams with scientific and operational excellence. Susan holds a PhD in biology, specializing in molecular virology, from Texas Tech University; an MS in biochemistry from Mumbai University (Grant Medical College) and a BS in microbiology/biochemistry also from Mumbai University (St. Xavier’s College).