Revvity has launched a major new addition to its Revvity Signals Software portfolio: Signals BioDesign, a cloud-native molecular cloning platform designed to streamline biologics R&D and accelerate therapeutic development.
Built for biotech and pharma research teams, Signals BioDesign replaces fragmented desktop tools and overly complex systems with a unified, enterprise-ready environment for collaborative construct design. The platform is aimed at simplifying high-complexity cloning workflows while enabling scalable, real-time teamwork across organizations.
The solution integrates key molecular cloning methods—including Golden Gate, Gibson assembly, and restriction/ligation—alongside primer design, Sanger sequencing analysis, and protein translation in a single application.
It also supports high-throughput combinatorial cloning of up to 1,000 constructs, helping researchers move faster from design to experimentation while reducing data silos and workflow bottlenecks.
Signals BioDesign is fully integrated with the company’s Signals One™ platform, making it the only cloud-native molecular cloning tool embedded in a broader biologics research ecosystem that connects construct design with bioregistration and experimental data capture.
“The Signals BioDesign offering addresses a critical need for molecular biology teams developing the next generation of antibody, cell, and gene therapies,” said Kevin Willoe, president of Revvity Signals Software.
“This solution empowers researchers with enterprise-ready collaboration and centralized construct management without the complexity of over-engineered platforms.”
The cloud-based system enables real-time collaboration, centralized sequence libraries, duplicate detection, monomer management, and granular access controls—capabilities the company says are difficult or impossible to achieve with traditional desktop software.
Its multi-tenant SaaS architecture also eliminates licensing overhead and reduces compliance risks, while laying the groundwork for AI-driven sequence optimization and predictive design tools.
