Stability Testing Strategies During Biologic Scale-Up and Commercial Manufacturing

Transitioning from clinical-scale production to commercial manufacturing is a critical milestone in the lifecycle of biologic drugs. As processes are scaled up, it’s essential to ensure that product stability remains consistent and well-documented. Variability in equipment, raw materials, and environmental factors can all impact stability. This guide outlines how to develop robust stability testing strategies during scale-up and commercial manufacturing to meet regulatory expectations and maintain product integrity.

Why Stability Testing Must Evolve During Scale-Up

Biologic drugs are particularly sensitive to process changes. As production moves from laboratory or pilot scale to full-scale manufacturing, changes in:

• Bioreactor design and volume
• Downstream purification systems
• Environmental conditions and cleanroom classifications

can subtly affect product attributes. Stability testing ensures these changes do not compromise the critical quality attributes (CQAs) of the product.

Key Stability Risks in Scale-Up and Commercialization

• Shear stress from large-scale pumping and filtration
• Equipment-specific interaction with surfaces and materials
• Variability in raw material lots
• Cold chain logistics during scale-up distribution

These factors can influence protein folding, aggregation, or chemical degradation — all of which must be assessed during stability studies.

Step-by-Step Guide to Designing Scale-Up Stability Studies

Step 1: Define the Change and Assess Its Impact

Start with a structured change assessment under ICH Q8 and Q12. Key changes might include:

• Increase in batch size or process scale
• Change in manufacturing site or equipment
• Modification of container closure systems

Each of these changes warrants a reevaluation of the existing stability profile or a new bridging study.

Step 2: Conduct Bridging Stability Studies

Compare pre- and post-scale-up batches under real-time and accelerated conditions:

• Use minimum of one pilot-scale and one commercial-scale batch
• Test all relevant attributes (appearance, pH, potency, aggregation, sub-visible particles)
• Include identical container-closure system and packaging configuration

Step 3: Align Protocol with ICH Q5C

Stability testing should reflect real-time and accelerated conditions:

• Long-term: 2–8°C for refrigerated biologics
• Accelerated: 25°C ± 2°C / 60% RH ± 5% RH
• Stress testing: 40°C, freeze-thaw, light exposure (ICH Q1B)

Timepoints may include 0, 3, 6, 9, 12, 18, and 24 months depending on product lifecycle stage.

Step 4: Use Validated, Stability-Indicating Methods

Ensure methods used for testing are fully validated and sensitive to degradation changes. Common techniques include:

• Size Exclusion Chromatography (SEC) for aggregation
• Potency assays (e.g., ELISA, cell-based)
• Capillary electrophoresis (CE-SDS) for purity
• UV-Vis for turbidity or light sensitivity

Step 5: Document and Justify Stability Comparability

If no significant differences are observed, comparability can be claimed. If minor changes are noted, justify with trending data, risk assessments, and scientific rationale documented in your Pharma SOP and regulatory filing.

Special Considerations for Commercial Batches

Lot Release vs Stability Batches

While lot release tests confirm immediate quality, stability testing tracks degradation over time. Regulatory authorities may request commercial stability data post-approval, especially for:

• Process performance qualification (PPQ) batches
• First three full-scale production lots

Ongoing Stability Programs (ICH Q1E)

Once on the market, real-time stability data must be collected on a rolling basis:

• At least one batch per year (or every six months for fast-degrading products)
• Storage at all relevant conditions
• Link results with shelf-life and expiry extensions

Case Study: Bridging Study for Manufacturing Site Transfer

A biologic manufacturer relocated production to a new facility with similar equipment. Stability testing revealed a slight increase in high molecular weight species after 6 months at 25°C. Root cause analysis linked this to minor differences in pump speed during formulation fill. Process optimization and a second bridging batch validated consistency, allowing regulatory approval with supporting data.

Checklist: Commercial-Scale Stability Implementation

1. Evaluate scale-up risks to stability through QRM (Quality Risk Management)
2. Design comparative studies using pilot and full-scale batches
3. Use ICH-compliant storage and timepoints
4. Track trending with statistical control tools
5. Include stress conditions relevant to real-world distribution

Common Mistakes to Avoid

• Relying solely on clinical-scale data for approval without bridging evidence
• Skipping forced degradation comparison for scaled-up materials
• Neglecting container-closure interaction studies at new scale
• Omitting ongoing stability in annual product quality reviews

Regulatory Expectations and Documentation

Global agencies require clear justification for any changes impacting product stability. Your CTD submission should include:

• Comparability protocols and results (ICH Q5E)
• Bridging study reports with raw data
• Change control documentation
• Updated stability specifications and shelf-life justification

Conclusion

Stability testing during scale-up and commercial manufacturing is essential to ensure product performance remains consistent under real-world conditions. By proactively identifying risks, conducting comparative studies, and integrating ICH-compliant testing protocols, pharmaceutical developers can facilitate seamless regulatory approvals and maintain high standards of quality. For additional resources on formulation and lifecycle stability, visit Stability Studies.