- Platform goals and positioning clarification
- Application field determination
Clearly delineate the specific synthetic biology products or processes that the platform will primarily serve for validation. This may encompass a range of domains, including biopharmaceuticals, biochemistry, biomaterials, agricultural biotechnology, and beyond. It is essential to recognize that the requirements and priorities for process validation can differ significantly across these fields. For instance, in the realm of biopharmaceuticals, greater emphasis may be placed on product purity, activity, and safety.
- Validation scale definition
Establish the scale of process validation that the platform will encompass, which can include laboratory small-scale testing, pilot scale testing, and potential industrial simulation scale. The small-scale trial phase is primarily aimed at preliminarily verifying the feasibility of the process and optimizing key parameters. In contrast, the pilot scale is utilized to further investigate the stability and repeatability of the process under conditions that closely mimic actual production scenarios. The industrial simulation scale serves to proactively identify and address potential challenges that may arise during large-scale production.
- Infrastructure Construction
- Laboratory space layout design
Strategically plan the layout of specialized laboratory areas, which should include fermentation rooms, purification rooms, analysis and testing rooms, and biosafety protection zones. It is crucial to ensure that the configuration of each functional area is logical and aligns with the process flow, facilitating efficient personnel operation and material movement. Additionally, considerations for biological safety and prevention of cross-contamination must be integral to the design.
- Equipment selection and Installation
The equipment can be categorized into several distinct groups as follows:
Cell culture and fermentation equipment: in alignment with the platform positioning and validation scale, configure appropriate bioreactors, including stirred bioreactors, air-lift bioreactors, and single-use bioreactors. These systems can feature precise controls for temperature, pH, dissolved oxygen, and stirring speed, tailored to meet the specific needs of various microorganisms and cell cultures. Additionally, it is important to incorporate corresponding seed cultivation tanks, culture medium preparation systems, and sterilization equipment to ensure optimal conditions for growth.
Purification equipment: install advanced equipment dedicated to product separation and purification, such as centrifuges, filtration systems (including microfiltration, ultrafiltration, and nanofiltration), chromatography systems (encompassing ion exchange chromatography, affinity chromatography, and gel filtration chromatography), and freeze-dryers. It is imperative that these devices meet stringent performance criteria to ensure product purity and quality, while also exhibiting excellent stability and reliability.
Environmental monitoring and control system: build a comprehensive environmental monitoring system to oversee and regulate real-time parameters, such as temperature, humidity, cleanliness, and pressure within the laboratory. It is essential to implement an air purification system to maintain air quality in accordance with relevant standards, thereby safeguarding against microbial contamination and dust particles that could compromise experimental outcomes.
- Technological platform construction
Various methods can be used for this purpose:
Design of experiment (DoE) method: Utilizing the principles of statistical experimental design, such as orthogonal design and response surface methodology, systematically explore the influence of multiple process parameters on product quality and yield. This approach allows to identify critical process parameters and develop mathematical models that can predict process performance, ultimately leading to optimized process design. By implementing the DoE method, significantly reduce the number of experiments required, enhance experimental efficiency, and acquire more comprehensive and precise information regarding the process.
Process analysis technology (PAT) method: introduce PAT tools, including online spectroscopic analysis (such as near-infrared and Raman spectroscopy), online biosensors (like glucose, lactate, and dissolved oxygen sensors), and process imaging technologies (including particle imaging and fluorescence imaging), to facilitate real-time monitoring and control of essential process steps, such as fermentation and purification. For instance, by continuously monitoring changes in dissolved oxygen levels and pH during fermentation, adjust the aeration rate and acid-base additions in real time, thereby maintaining optimal environmental conditions for microbial growth.
Quality standards and testing method: in alignment with relevant regulations and industry standards, and taking into account product characteristics, develop comprehensive quality standards for raw materials, intermediate products, and final products. It allows to establish corresponding analytical and detection methods, encompassing both qualitative and quantitative analyses, and conduct thorough methodological validation to ensure the accuracy, repeatability, specificity, and sensitivity of these methods.