From Bench to Clinical Scale: Broad Clinical Labs’ Approach to Scaling a Custom Assay
Translating a high-performing custom benchtop assay into a reliable, clinical-grade operation at scale is technically challenging. Assays developed in controlled research settings are optimized for sensitivity and scientific utility, but are rarely designed for the reproducibility, automation compatibility, and regulatory documentation required in clinical-grade production. Closing that gap requires foresight and deliberate re-engineering of the assay—and the earlier that process begins, the more efficient the journey will be.
The Core Problem Is Reproducibility at Scale
An assay that performs reliably with one operator, manually prepared reagents, and a controlled sample set will often degrade when exposed to liquid handling automation, batch processing, cross-platform concordance, and the variability of real-world clinical samples. This reflects the substantial differences between small-scale performance and high-throughput production environments.
The challenge is compounded in the clinical context. Clinical-grade operation requires documentation and validation of every process deviation. Design decisions that seemed inconsequential at the benchtop level can become compliance liabilities at scale. Analytical validation parameters, such as accuracy, precision, limit of detection, and limit of quantification, must be established and verified. For programs moving toward clinical trials, the documentation trail must be structured to withstand regulatory review.
The most consequential misstep is treating scale-up as a transfer. It is a re-engineering effort, and the scope of that effort is best understood and planned for early.
Designing for Scale Before Scale Is Needed
In the traditional custom assay development partnership model, assay design falls to the research team while platform and workflow engineering are performed by a service provider. It is frequently at the point of handoff—from the research team to the service provider for scale-up—where technical problems like reagent incompatibilities, protocol weaknesses, and reproducibility failures surface. Resolving these issues during scale-up is substantially more costly than addressing them earlier in development.
Broad Clinical Labs (BCL) addresses this by collaborating with partners during the assay design phase, building workflows that account for scalability from the beginning. This includes deliberate choices about how an assay will integrate with a partner’s sequencing platform, informatics pipeline, and LIMS environment. It also requires an accurate read of where a partner is in their development trajectory.
In early discovery, a fit-for-purpose assay is one that generates reliable output at a reasonable cost and turnaround. As a program approaches clinical trials, that definition expands to include analytical validation, CLIA and CAP compliance, and documentation that would hold up under regulatory review. An assay architecture that anticipates this progression during the design phase avoids the need to substantially rebuild it when regulatory requirements come into focus.
BCL has experience across major platform chemistries, including Illumina®, PacBio®, Roche®, and NEB®, across a range of assay types. That operational depth informs design decisions early and reduces the likelihood of encountering platform-specific constraints when they are most costly to address.
Automation Infrastructure Built Around Each Assay
BCL’s high-throughput infrastructure is designed around the specific requirements of each assay rather than shaping a custom assay to “fit” a standardized platform. Three variables define the automation design: speed, scale, and batch size. These variables often compete, making it essential to define priorities before design begins.
For example, a workflow requiring same-day turnaround on small sample volumes has different automation requirements than one processing thousands of samples in weekly batches. Resolving that distinction during the design phase, rather than after infrastructure has been committed, avoids expensive reconfiguration.
BCL structures each assay workflow into discrete, independently validated units. This modularity allows individual steps to be upgraded or scaled without destabilizing the broader pipeline, which is a meaningful operational advantage as research and development programs grow and change.
BCL applied this approach in collaboration with Delve Bio, scaling their metagenomic next-generation sequencing (NGS) platform for infectious disease diagnostics nationwide. Metagenomic NGS presents a signal-to-noise challenge distinct from targeted sequencing: pathogen reads must be resolved from a high background of host DNA and RNA. Scaling required parallel optimization of wet-lab inputs (sample types, extraction protocols) and the bioinformatics pipeline. Maintaining diagnostic sensitivity as automation was introduced proved to be the central engineering challenge and it required close coordination between BCL’s wet-lab and informatics teams throughout.
The Benefits of Consolidated Services
When a study integrates genomics, transcriptomics, and proteomics, processing those workflows at a single site offers an often underestimated advantage. Shared sample aliquoting strategies, coordinated quality control checkpoints, and a unified chain of custody make cross-omic data normalization easier. Harmonizing data generated by separate vendors under independently optimized conditions is considerably more difficult than designing for harmonization from the start.
The advantages of a single-partner relationship can extend beyond the lab. For programs operating at national scale, pre-analytical variability in sample collection represents one of the highest-risk steps in the workflow. BCL’s direct-to-patient kitting service delivers validated collection materials and standardized instructions directly to participants across all 50 states. This reduces variability at the point of collection and removes the need for independent site-based collection logistics, which makes population-scale studies and decentralized clinical trials operationally and economically more feasible. Further, this approach helps to increase enrollment and participation rates by reducing the burden on patients, ensuring that diverse populations can contribute to and benefit from genomic advancements.
Long-Term Scientific Value
The interpretation of genomic data today is likely to change as more information is made available. Variant classifications change as population databases expand, functional studies accumulate, and clinical guidelines evolve. A variant classified as one of uncertain significance (VUS) at enrollment may be reclassified as pathogenic years later. BCL retains the analytical infrastructure to support re-interpretation of partner data as research advances. This continuity preserves the longitudinal scientific value of the original study.
A Structured Partnership for Scalable Science
Scaling a custom assay from benchtop to clinical-grade production draws on expertise across assay design, automation engineering, regulatory compliance, bioinformatics, and logistics. BCL’s Contract Assay Services function as a centralized engine for scale. We engage with partners across all domains, from early design decisions through long-term operational support, functioning as an integrated extension of the partner’s scientific team.
For teams at any stage of custom assay development and scale-up, BCL’s Contract Assay Services can accelerate the path from discovery to clinical impact. Contact us to discuss how we can support your project.