DAY 1

AGENDA

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07.35 – 08.20
Registration

 

08.20 – 08.30
Welcome & Chairman’s Opening
Remarks for Day One

Tom Ransohoff, Operating Partner, Keensight Capital

08.30 – 09.00

Digitalization, modeling, and machine learning: Pillars for development of next generation bioprocesses

  • 1. The talk will describe how MSD is strategizing the use of digitalization, modeling, and machine learning tools for development of next generation bioprocesses.
  • 2. The discussion would include the applicability and suitability of various tools relevant to data aggregation, modeling and simulation, as well as machine/deep learning.
  • 3. Relevant case studies in different areas of development and manufacturing (upstream and downstream) would be shared.
  • 4. Finally, Examples will be provided how the aforementioned techniques are being integrated with high throughput setups and PAT applications for speedy development and enhanced process understanding.

Sanjeev Ahuja Executive, Executive Director Biologics Process R & D, Merck

 

09.00 – 09.30

Faster Isn’t Enough: How Biotech Wins with Efficient Development

  • Over the last 10–20 years, biotech optimized for speed-to-market (compressed timelines, parallelized work, accelerated pathways); now that many “go faster” gains are saturated, the competitive edge shifts to doing more with the same (or less)—higher success rates, fewer handoffs, and less rework.
  • High-throughput automation (robotics, miniaturization, standardized assay/run recipes) increases experimental density and repeatability, reduces human variability, and enables rapid iterate-and-learn cycles with fewer failures and lower cost per decision.
  • Smart data infrastructure (instrument connectivity, metadata standards/ontologies, ELN/LIMS integration, governed data products) makes data findable and reusable, supports end-to-end traceability, and cuts cycle time lost to data wrangling, reconciliation, and “rediscovery.”
  • AI/ML tools turn integrated data into better decisions—prioritizing targets/compounds, optimizing experiments, detecting quality issues early, and forecasting manufacturability—so teams run fewer but higher-value experiments and de-risk programs earlier.

Terrence Dombrowsky, Senior Director, Head of Biotherapeutics Technology Development and Implementation, Takeda



09.30 – 10.00

Overcoming pump tube limitations in demanding biomanufacturing applications

  • Company and product overview
  • Advanced materials that can enable higher pump tube performance
  • Applications that can benefit from higher level performance
  • Risk mitigation in demanding applicataions

 

Downstream Development

10.00 – 10.30

Contextualized Data Framework to Accelerate Downstream Tech Transfer and CMC Readiness

  • Pain Point & Regulatory Context: Manual, unstructured document workflows impede searchability, traceability, and reusability; AI can extract history but not author source content—making structured data essential as FDA advances KASA and structured PQ/CMC submissions.
  • Scope & Rationale: Internal framework that contextualizes downstream experimental data and process definition was chosen to reduce cost, increase feedback speed, upskill scientists, and build the business case.
  • Architecture: Three layers of implementation includes Data Capture (templated ELNs; scientist-built UI for process parameters), Data Mapping (information model linking steps, parameters, attributes, and interdependencies), and Data Consumption (automated queries for advanced analysis).
  • Outcomes: Enables version-controlled tech transfer across scales, facility-fit and buffer-volume planning and faster investigations with traceable specs and supporting data

Lye Lin Lock, Associate Scientific Director, BMS

Upstream Sciences

10.00 – 10.30

Modernizing upstream development to advance and accelerate process understanding and CMC excellence

  • Traditional upstream development is changing with advances in modelling and sensors.
  • Real time product quality data- how often and how well can this be achieved?
  • PAT tools that support process development modernization
  • Creating a CMC data package with AI, smart templates, and regulatory intelligence

 

Sarwat Khattak, Head of Cell Culture and Cell Line Development, Biogen

10.30 – 11.20
COFFEE BREAK & MEETINGS

11.20 – 12.10

Roundtable Discussions:

For 6 to 10 participants (per roundtable) to discuss and debate on a topic of their choice

  1. Next Gen Processes to Overcome Scale Limitations
  2. Late-Stage Development of Purification Processes for Biotherapeutics
  3. Digitalization, Modeling, and Machine Learning
  4. Laboratory Data Automation Experiences
  5. Lean Process Characterisation in Upstream Processing- Challenges and Experiences for Implementation
  6. HCP Control Strategy – Benchmarking and Common Understanding of Agency Requirements
  7. Challenges in Outsourcing CMC development
  8. ML/AI for Process Development
  9. DSP Intensification Strategies

 

12.10 –13.40

One to One Meetings & Investment Areas

  • Downstream/Upstream Process Technology Platforms
  • Biopharma 4.0
  • Digitalization
  • Specialised cell culture media
  • Single-use & Disposable Technologies
  • Separation and Purification Technology
  • Virus Filtration Processes
  • Smart Manufacturing Technologies – Tech. Transfer
  • Facility Management & Integration
  • Biopharma & Modular Biosafety Technology
  • Capacity & Facility Design
  • Multi product facilities
  • Fluid Management Systems
  • Lean/Operational Excellence
  • Continuous Improvement
  • PAT & MES, Automation and Process Control Excellence
  • QbD, Quality Assurance & Quality Systems
  • Validation Process/Life cycle Management systems
  • Regulation – Rapid Release Testing
  • cGMP – Contract, External Manufacturing Services
  • Biogenerics/Biobetters
  • Personalised Medicines
  • Cell & Gene Therapy
  • Fill and finish
  • Microbial Process Development and Production
  • Biopharmaceutical USP 665 Testing & Characterization Services

Workshops

12.10 – 12.40

Large-scale implementation data for Amsphere A+: a high DBC, low backpressure, 1M NaOH stable Protein A resin

  • Building on the proven platform of Amsphere A3, JSR Life Sciences has developed Amsphere A+, a next-generation Protein A resin designed to meet the evolving demands of the biopharma industry.
  • Combining high dynamic binding capacity even at short residence times with exceptional stability during repeated 1 M NaOH exposure and excellent pressure–flow performance, Amsphere A+ enables more efficient, robust operations.
  • In this presentation, we will share key large-scale performance and life-cycle data and demonstrate how Amsphere A+ serves as a versatile affinity platform for both classical and non-classical antibody formats, supporting high process intensification and enhanced in-process bioburden control.

12.40 – 13.10

Pharma 4.0 in Action: Unlocking the Value of Unified Life Sciences Eco-system

The pharmaceutical industry is embracing Pharma 4.0 and digital transformation to improve efficiency, compliance, and agility. This session explores how unified life sciences and MES solutions address disconnected systems, regulatory demands, and operational inefficiencies while fostering collaboration and continuous improvement.

  • Leverage unified manufacturing system to streamline operations, enhance compliance, and drive digital transformation in Pharma 4.0.
  • Overcome challenges related to disconnected systems, regulatory requirements, and operational inefficiencies through an integrated approach.
  • Foster cross-team collaboration to improve agility, meet evolving market demands, and establish a framework for continuous improvement.

    13.10 – 13.40

    Accelerating Bioprocessing with 3M™Harvest RC: A joint Implementation Success by Solventum and CDR-Life

    • In today´s dynamic biopharmaceutical environment, manufacturers face growing pressure to optimize upstream processing steps while maintaining product quality and regulatory compliance
    • One critical area is cell culture clarification – the removal of cells, cell debris, and soluble impurities from harvested cell culture fluid prior to downstream processing.
    • Solventum and CDR-Life successfully collaborated to rapidly implement the innovative chromatographic clarification solution that replaces conventional depth filtration methods. 3M™ Harvest RC Chromatographic Clarifier efficiently separates cells, cell debris and DNA from the harvested cell culture fluid containing the target product in a single-stage clarification step, utilizing Q-chemistry grafted nonwoven media.
    • The rapid adoption of 3M™Harvest RC in an established process environment was achieved significantly faster than typical technology changeovers.
    • Key benefits during implementation included significant time saving in the harvest phase, improved filtrate quality, reduced DNA levels, and a simplified clarification step.
    • Importantly, these gains were realized without requiring major changes to the existing equipment or process layout, highlighting the plug-and-play nature of the technology.

    13.40 – 14.30

    NETWORKING LUNCH

    Downstream Development

    14.30 – 15.00

    Investigations in virus filter process performance at different positions in the downstream process

    • The focus of authorities on contamination control strategy requires a re-assessment of the downstream process
    • New virus filters enable the filtration of higher concentrated samples and thus placement further downstream the purification process
    • Studies showed successful re-location of the filters, although flux was affected, depending on the molecule studied
    • Irrespective of low or high flux viral clearance studied an effective removal of viruses

    Yi Liu, Director of Process Development and Partnering Projects, Bayer

    15.00 – 15.30

    Bridging the Gap for BioPharma End-to-end Lab Automation Platform: Success and Opportunity

    • Microscale purification using Robocolumns in Tecan Liquid handlers
    • Automation of filtration applications to enable end to end purification platform
    • Leveraging multi attribute method testing to streamline Product quality assessment
    • Develop a framework for end-to-end automation platform for monoclonal antibody

    Manoj Ganesh, Senior Staff Process Scientist, Regeneron Pharmaceuticals

    15.30 – 16.00

    Changing the vibes of Process Characterization: How lean teams can do more with less

    • The focus will be on gaining efficiencies during process characterization by judicious use of gen AI and modeling.

    Borna Ghosh, PhD., Associate Director, Downstream Process Development, Alexion

    Upstream Sciences

    14.30 – 15.00

    Matching Medium and Process

    • Increase of volumetric productivity exceeds all initial expectations in the field
    • Fed-batch, intensified fed-batch and perfusion processes made it to the manufacturing
    • Both, medium and process contributed to the strong gain in volumetricproductivity
    • Media optimization tailers the medium to the specific process needs
    • Case studies for a perfusion medium will be presented and challenges discussed

    Martin Jordan, Senior Scientist, Merck Group

    15.00 – 15.30

    Scalable Harvest Solutions to New Challenges from Process Intensification

    • Upstream process intensification via n-1 perfusion reactor technologies can bring significant benefits and titer uplift to biologics
    • Increased output on upstream processes pose new challenges on downstream processing capacity and equipment
    • The deployment of single-use centrifuge can improve throughput, lower impurity burden, reduce waste and overall COGs
    • Pilot case study and real data for 1k, 2k bioreactor GMP

    Brendan Moore, Senior Cell Culture Engineer II, Biogen

    15.30 – 16.00

    Introduction of Model-based Process Control (MbPC) strategy for Dextrose feeding

    • Uncertain quantification of glucose uptake rate
    • Mathematical model of cell culture
    • Approach and development of MbPC strategy
    • Real-time control simulation
    • Sensitivity and robust analysis

    Min-Cheol Kim, Process Engineer IV, Sanofi

    16.00 – 16.50

    COFFEE BREAK & MEETINGS

    16.50 – 17.50

    One to One Meetings & Investment Areas

    • Downstream/Upstream Process Technology Platforms
    • Biopharma 4.0
    • Digitalization
    • Specialised cell culture media
    • Single-use & Disposable Technologies
    • Separation and Purification Technology
    • Virus Filtration Processes
    • Smart Manufacturing Technologies – Technology Transfer
    • Facility Management & Integration
    • Biopharma & Modular Biosafety Technology
    • Capacity & Facility Design
    • Multi product facilities
    • Fluid Management Systems
    • Lean/Transformational Change – Operational Excellence
    • Continuous Improvement / Manufacturing Processing
    • PAT & MES, Automation and Process Control Excellence
    • QbD
    • Quality Assurance & Quality Systems
    • Validation Process/Life cycle Management systems
    • Regulation – Rapid Release Testing
    • cGMP – Contract, External Manufacturing Services
    • Biogenerics/Biobetters
    • Personalised Medicines
    • Cell & Gene Therapy
    • Fill and finish
    • Microbial Process Development and Production
    • Biopharmaceutical USP 665 Testing & Characterization Services

    Workshops

    16.50 – 17.20

    From Molecule to Manufacturing: Unlocking Process Intensification Across the Biopharma Lifecycle

    • Molecular-level intensification: Leveraging high-titer, high-efficiency cell lines supported by advanced analytics, tailored media development, and cell banking services for both research and GMP production.
    • Upstream process intensification: Evaluating PI strategies in upstream processing based on key drivers such as process duration, volumetric productivity, cost of goods, and operational flexibility—tailored to the needs of different manufacturing models.
    • Downstream process intensification: Approaches to reduce cost of goods and facility footprint, comparing membrane-based and resin-based technologies, single vs. multi-column setups, and orchestration platforms for continuous DSP.

     

    17.20 – 17.50

    Process intensification, mRNA & precipitated mAb purification with disruptive Vibro® Membrane Filtration

    • Design behind the Vibro® Technology enabling outstanding performances and new opportunities compared to currently available filtration and centrifuge technologies
    • Low and uniform TMP, high concentration & viscosity enabling process intensification, continuous processes, simplification by removing process steps
    • Understand how Vibro® Membrane Filtration (VMF) is supporting sustainability with its extremely low energy consumption and environmental footprint
    • Case study 1: mRNA purification by SPTFF with 3-fold higher performances vs. specifically developed current technologies to handle mRNA
    • Case study 2: VMF is the only available technology enabling precipitated mAbs/proteins filtration by SPTFF as an alternative to high costly affinity columns both in batch and continuous processes

      17.50 – 18:20

      From Molecule to Manufacturing: Unlocking Process Intensification Across the Biopharma Lifecycle

      • Molecular-level intensification: Leveraging high-titer, high-efficiency cell lines supported by advanced analytics, tailored media development, and cell banking services for both research and GMP production.
      • Upstream process intensification: Evaluating PI strategies in upstream processing based on key drivers such as process duration, volumetric productivity, cost of goods, and operational flexibility— tailored to the needs of different manufacturing models.
      • Downstream process intensification: Approaches to reduce cost of goods and facility footprint, comparing membrane-based and resin-based technologies, single vs. multi-column setups, and orchestration platforms for continuous DSP.

      18.20 – 18:50

      From Capping to Conjugation: Cell Culture Levers That Shape Cysteine Availability and ADC DAR

      • Enhancing ADC Therapeutic Potential through Site-Specific Conjugation: Antibody-Drug Conjugates (ADCs) hold immense promise in oncology. A key challenge lies in their heterogeneity resulting from non-site-specific conjugation. This variability can significantly impact therapeutic efficacy and patient safety. Approaches leveraging site-specific conjugation technologies (such as using engineered cysteines) are particularly valuable for enabling precise drug attachment. Achieving meticulous control over both the conjugation site and the Drug-to-Antibody Ratio (DAR) is essential for optimizing ADC stability, pharmacokinetics, and ultimately, maximizing their therapeutic window.
      • Pivotal Role of Cell Culture in Cysteine Management for ADC Quality: Advanced cell culture strategies play a crucial role in managing the oxidation state (capping/de-capping) of engineered cysteines within ADCs. This precise management is vital for ensuring the optimal availability of free thiols necessary for efficient drug conjugation and achieving the targeted Drug-to-Antibody Ratio (DAR).

      Sri Madabhushi, Senior Director  Cell Culture and Fermentation Sciences, AstraZeneca

        18.50

        CHAIRPERSON’S CLOSING REMARKS AND END OF DAY ONE

        18.55

        Networking drinks reception

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        DAY 2

        AGENDA

        08.10 – 08.15
        Welcome & Chairman’s Opening
        Remarks for Day Two

        Tom Ransohoff, Operating Partner, Keensight Capital

        08.15 – 08.45

        Are We There Yet? A Digital Maturity Model for Enabling Process Monitoring and Artificial Intelligence in Biologics Manufacturing

        • Digital transformation promises to revolutionise biopharmaceutical manufacturing, yet most organisations leverage a fraction of their process data, with the challenges paradoxically increasing with globalisation and digitisation.
        • This talk presents a practical maturity model for effectively navigating bioprocess monitoring and AI implementation.
        • Drawing on assessments of 25 products, the presentation examines how companies can transform data challenges into competitive advantages by ensuring critical data is made available and delivered effectively.

        Jack Prior, PhD, Head, Process Monitoring & Data Science & AI Strategy, Sanofi Group

        08.45 – 09.15

        Mechanisms of Filtration in Bioprocessing: From Depth Filters to Advanced NFF Systems

        • Critical Role of Filtration – Filtration is essential in bioprocessing, ensuring effective purification and concentration of biomolecules in downstream applications.
        • Depth Filtration Efficiency – Depth filters capture contaminants within the filter matrix, offering high particle retention and preventing early blockage— ideal for large debris and harvest-stage processing.
        • Normal Flow Filtration (NFF) Functionality – NFF, or dead-end filtration, pushes all fluid through a membrane under constant pressure, effective for fine filtration but prone to surface cake buildup
        • Complementary Use for Maximum Performance – Using depth filters as pre-filters reduces strain on NFF systems, extends membrane life, and maintains optimal system performance.
        • Pendotech’s Advanced NFF System – METTLER TOLEDO Pendotech offers a next-gen NFF system featuring peristaltic/diaphragm pumps, multi-experiment capabilities, and robust design for high-efficiency biopharmaceutical production.

        Downstream Innovation

        09.15 – 09.45

        Continuous optical monitoring of antibody concentration and Rapid lateral-flow immunoassays for monitoring process and product parameters

        • Continuous optical monitoring of antibody concentration for early detection of breakthrough from large protein A columns, or for determination of titers in process streams
        • Enhanced control of rapid cycling processes or protein A column loading.
        • Rapid lateral-flow immunoassays for monitoring process and product parameters.
        • PAT information in 10 minutes instead of having to go to central analytical laboratories.

        Richard Willson, Huffington-Woestemeyer Professor, University of Houston

        09.45 – 10.15

        DSP intensification strategies- Practical approaches to enhance throughput and reduce COGs in downstream processing

        • Upstream process intensification, such as high inoculation density (HID) and N-1 perfusion, significantly increases product titres but introduces downstream purification challenges like reduced filtration capacity, higher impurities, and capture step bottlenecks.
        • Downstream Process (DSP) intensification strategies focus on improving performance, reducing process time and footprint, and enabling continuous manufacturing through advancements in cell harvesting, Protein A capture resins, multi-column chromatography, polish step intensification, in-line buffer management, and single-pass TFF.
        • Case Study 1: Screening and optimizing high-capacity Protein A resins at reduced bed heights improved productivity and maintained product quality, addressing challenges from intensified upstream processes.
        • Case Study 2: Evaluation of two cation exchange chromatography resins demonstrated trade-offs between yield and purity, highlighting the need for intensified DSP to manage increased loads and enhance process robustness for monoclonal antibodies.

        Yiran Wang, Principal Scientist, BMS

          10.15 – 10.45

          Efficiency Unleashed: Fully Automated Self-Optimizing Screening in Process Development

          • Downstream process development of biopharmaceuticals expressed in microbials and practical benefit of a process design platform. 
          • SMART Process Design Platform, a user-friendly platform for Boehringer Ingelheim´s scientists and data scientists to host and utilize process models.
          • Model-Guided DoE Approach to enhance process development by intelligently suggesting experiments, leading to rapid improvements in model quality and predictive power. 
          • Autonomous Process Optimization: the platform automates the experiment design, execution, and data analysis, significantly improving efficiency.
          • Iterative Model Training and Retraining showing how model quality increases with each iteration, ultimately reaching a plateau, and achieving higher outputs.
          • Genetic Algorithm for Optimization, applying the concept of survival of the fittest to create new generations of models, leading to convergencetowards optimal solutions

            Bioprocess Innovation

            09.15 – 09.45

            Control Strategies Tailored for Multispecifics

            • Critical quality attributes assessment of multispecifics with emphasis on homodimer formation and heavy/light chain mispairing;
            • Innovative control strategies to eliminate homodimers and heavy/light chain mispairing;
            • Advanced analytical methodologies for testing and characterizing of homodimers and heavy/light chain mispairing;
            • Approaches of specification setting and regulatory feedback.

            Wenqin Ni, Senior Principal Scientist, Pfizer

            09.45 – 10.15

            Modeling in biotherapeutics process development: Moving towards workflow integration

            • Modeling typically performed on project basis
            • Goal: Integrate modeling as standard tool in development workflows
            • Prerequisites for workflow integration
            • Case study presentation

            10.15 – 10.45

            Next generation checkpoint inhibitor; JJP-1008 for the treatment of cancer  

            • Novel checkpoint inhibitor
            • Innovative cancer treatment
            • Biomarker for patient stratification
            • Immunosuppression versus immune-activation
            • Anti-CD270 (HVEM), JJP-1008 for the treatment of melanoma

              10.45 – 11.20
              COFFEE BREAK & MEETINGS
              11.20-12.10

              Roundtable Discussions:

              For 6 to 10 participants (per roundtable) to discuss and debate on a topic of their choice

              1. Potential and challenges of changes and optimizations as part of life cycle management of Biotherapeutics manufacturing
              2. Going to large scale with our process
              3. AI Adoption in the Laboratory
              4. Next Generation Process Improvements
              5. Approaches to Conducting CQA Assessment and its Application to Process Understanding
              6. ML/AI for Process Development
              7. Addressing Upstream Bioprocessing Complications
              8. Data Science and AI for CMC: Beyond the Hypee
              9. Challenges and Solutions in Tech Transfer

               

              12.10 – 13.40

              One to One Meetings & Investment Areas

              • Downstream/Upstream Process Technology Platforms
              • Biopharma 4.0
              • Digitalization
              • Specialised cell culture media
              • Single-use & Disposable Technologies
              • Separation and Purification Technology
              • Virus Filtration Processes
              • Smart Manufacturing Technologies – Technology Transfer
              • Facility Management & Integration
              • Biopharma & Modular Biosafety Technology
              • Capacity & Facility Design
              • Multi product facilities
              • Fluid Management Systems
              • Lean/Transformational Change – Operational Excellence
              • Continuous Improvement / Manufacturing Processing
              • PAT & MES, Automation and Process Control Excellence
              • QbD
              • Quality Assurance & Quality Systems
              • Validation Process/Life cycle Management systems
              • Regulation – Rapid Release Testing
              • cGMP – Contract, External Manufacturing Services
              • Biogenerics/Biobetters
              • Personalised Medicines
              • Cell & Gene Therapy
              • Fill and finish
              • Microbial Process Development and Production
              • Biopharmaceutical USP 665 Testing & Characterization Services

              Workshops

              12.10 – 12.40

              Biopharma Speed, Flexibility and Reliability enabled by Digital

              • Digital ambition: Delivering fast, flexible, and reliable PD and manufacturing operations
              • In Silico PD solutions that drive new entitlement of speed and robustness in process development
              • Automation solutions that reduce batch deviations and accelerate release
              • IoT solutions that drive significant reduction of unplanned downtime
              • PAT vision to enable advanced process controls

                12.40 –13.10

                Integrated mAb Capture and Polishing Steps Using the Octave™ MCC Platform

                • Continuous and semi-continuous bioprocessing is becoming more widely adopted in the biopharmaceutical industry, and Multi-column Chromatography (MCC) is playing a crucial role in the conversion.
                • The transition to a fully continuous process ideally fulfills the industry’s economic and environmental regulations, with incremental integration proving to be a practical solution for continuous biomanufacturing.
                • Tosoh Bioscience demonstrates this integration using its Octave™ MCC platform, which uses a Protein A capture step and subsequent polishing step to purify high-titer monoclonal antibody (mAb) feedstock.

                  13.10 –13.40

                  Streamlining Bioprocess Development: A Novel Perspective on the Role of Hybrid Models and Risk-Based Optimal Experimental Designs

                  • Leveraging a powerful combination of hybrid modeling, transfer learning, and Pareto-based Bayesian optimization to enhance process understanding, reuse historical data across products and scales, and enable risk-informed experimental design – accelerating development and process understanding.
                  • These technologies are incorporated and leveraged as part of the “methodology”, inspired by the PDCA (Plan-Do-Check-Act) cycle used in lean development, but which is adapted to the capabilities and opportunities of machine-learning.
                  • The result is increased efficiency, effectiveness, and flexibility across the product life cycle, with faster and more robust, insight-driven, decision-making. Case studies across multiple modalities will be discussed.

                    13.40 –14.40

                    NETWORKING LUNCH

                    Upstream Sciences/CMC Development

                    14.40 – 15.10

                    Revealing the temporal impact of dissolved oxygen on lactate metabolism in mammalian bioprocesses using dynamic design of experiments

                    • The switch from lactate production to consumption is crucial for mammalian bioprocesses but remains not fully understood.
                    • A robust switch to lactate consumption improves metabolic efficiency, cell growth, and productivity.
                    • Efforts focus on actively controlling and maintaining the lactate consumption state throughout the bioprocess.
                    • Dissolved oxygen (DO) is a critical process parameter significantly influencing lactate metabolism in CHO cells.
                    • The presented study investigates the impact of DO on lactate metabolism and its effect on overall process performance, considering exposure time and levels using dynamic design of experiments
                    • Insights aim to define a robust DO profile aligned with cellular dynamics and scalable bioprocesses

                    15.10 –15.40

                    Advancing Real Time Cell Culture Prediction Models: Insights and Improvements for CQA Crash Behavior

                    • Brief recap of the digital twin system as a background (presented in 2025 conference)
                    • Challenge faced by the real time prediction model on CQA prediction for atypical batches
                    • Approaches to address the challenge
                    • Outcome and impact

                    Rui Wheaton, Principal Scientist, BMS

                      Bioprocess Innovation

                      14.40 – 15.10

                      Unlocking the power of Digital Transformation and AI: a strategy in upstream process development

                      • The Future of Upstream Automation
                      • Explore how digital transformation and AI are revolutionizing upstream bioprocessing across the industry.
                      • This session examines practical implementations that enhance process development, optimize cell culture conditions, and accelerate time-to-market—featuring real-world success stories Flexible actionable strategies for implementation in any stage of their digital journey.

                      Zhuangrong Huang, Senior Staff Engineer, Takeda

                        15.10 –15.40

                        Model-assisted development in antibody purification

                        • Limits of experiential process knowledge
                        • Holistic model utilization in downstream processing
                        • From candidate screening to facility fit
                        • Development acceleration and efficiency gains

                          15.40 – 16.10

                          Next-Gen Cell Culture Media Formulator: Integrating Predictive Modelling and Calculators to Accelerate Process Development

                          • Efficient methods for screening new possible formulations for solubility and stability prior to wet experimentation
                          • Rapid construction of new formulations that retain desired traits from previous iterations
                          • Reduction in preparation time for component heavy formulations via targeted manipulation of chemical interactions

                          Spencer Monaco, Sr. Associate Scientist, Biogen

                            15.40 – 16.10

                            Overcoming Buffer Bottlenecks Using Inline Buffer Formulation

                            • Increasing cell culture titer (> 5 to 10 g/L) has led to a significant increase in downstream processing buffer consumption
                            • A GMP scale Inline Buffer Formulation skid was designed to enhance manufacturing flexibility by enabling on-demand buffer production
                            • This presentation will focus on the supporting lab studies and challenges for GMP implementation
                            • The future goal of creating lab-scale inline buffer formulation models that predict GMP performance will also be discussed

                            Kheng Tee Ng, Senior Scientist, AbbVie

                             

                             

                             

                              16.10 – 16.40

                              Outsourced early CMC development of a non-platform protein: Experience dealing with CDMOs

                              • Overview of Tribune Therapeutics, a leading research company in fibrotic diseases
                              • Product portfolio including the frontrunner TRX-44, an albumin fusion protein
                              • Management of the CMC development using exclusively CDMOs towards initial clinical trial application
                              • What went well, what needs special attention, what needs to improve
                              • General learnings how to deal with CDMOs

                                16.40

                                CHAIRPERSON’S CLOSING REMARKS

                                16.45

                                CLOSE

                                Back to top

                                Please Note: Workshop, Agenda, Speakers and Participants can be subject to change

                                Richard Willson

                                Huffington-Woestemeyer Professor

                                University of Houston

                                Richard Willson is Huffington-Woestemeyer Professor of Chemical & Biomolecular Engineering, Biology & Biochemistry, and Biomedical Engineering at the University of Houston, and a Senior Affiliate of The Houston Methodist Hospital Research Institute. He holds B.S. (honors) and M.S. degrees in Chemical Engineering from Caltech, and completed his Ph.D. and postdoctoral studies at MIT. Dr. Willson is former Chair of ACS BIOT, and an elected Fellow of the AIMBE, ACS, RSC, and AAAS. He is a member of the National Academy of Inventors, was CTO of Visigen which built the first system for single-molecule sequencing-by-synthesis, was on the founding Technical Advisory Board of Moderna from 2012, and served for a time as interim Associate VP for Technology Transfer of the University of Houston, then the non-medical public university with the largest patent royalty income in the US. His research interests are in PAT, and the purification of biological molecules.

                                Abstract
                                Continuous and high-intensity processing, rapid process development, and digitalization all benefit from continuous data. We have developed a fiber-optic probe that continuously reports Fc concentrations, and are working to make it CIP-compatible and usable both at very low concentrations (for breakthrough detection) and higher ranges (for g/L titer measurement. Separately, we have adapted lateral-flow immunoassays (the format of many COVID-19 tests and the home pregnancy test) to rapid, local, determination of process and product characteristics.

                                Borna Ghosh

                                Associate Director, Downstream Process Development

                                Alexion

                                 

                                Borna Ghosh is an Associate Director in Downstream Process Development at Alexion, AstraZeneca Rare Disease, with over nine years of industry experience. She holds a Ph.D. in Biophysics and has previously contributed to biologics development at Merck & Co, BMS and Eli Lilly. She specializes in Process Characterization, Viral Clearance, and commercial scale up, applying QbD to build robust control strategies, drive PPQ readiness, and enable efficient tech transfer.

                                 

                                Jack Prior

                                PhD, Head, Process Monitoring & Data Science & AI Strategy

                                Sanofi Group

                                Dr. Jack Prior leads MSAT Process Monitoring & Data Science/AI Strategy at Sanofi, where he spearheads global initiatives in process monitoring and AI-driven yield improvement for biologics manufacturing. Previously as Head of MSAT Digital, he led teams working to develop global process data analytics systems and to digitize laboratory operations for Industrial Affairs Specialty Care drug substance and drug product manufacturing. Jack’s career at Sanofi-Genzyme spans nearly 3 decades, where he has led manufacturing science organizations supporting process characterization, modeling, technology transfer, and manufacturing operations for critical therapies treating rare genetic disorders. Throughout his career, he has focused on integrating process modeling and advanced analytics with manufacturing science to enhance biologics production across US and European operations. Dr. Prior holds a Doctor of Science in Chemical Engineering from MIT and a Bachelor of Science in Chemical Engineering from the University of Connecticut.

                                 

                                Rui Wheaton

                                Principal Process Engineer

                                Bristol Myers Squibb

                                Rui Wheaton is currently a principal scientist in the Digital Strategy and Process Optimization group at Bristol Myers Squibb. Her focus is advanced computational models and digital twins in manufacturing and process development. Prior to her current role, she has experience as a senior scientist in the Process Modeling and Data Scientist group at resilience and Process Engineer in the Manufacturing Technology Upstream group at Bristol Myers Squibb. Rui holds a Ph.D. in Chemical Engineering from Worcester Polytechnic Institute.

                                Abstract

                                Last year’s presentation introduced a model?based approach for real?time predictions of cell culture dynamics and critical quality attributes (CQAs), enabling SMEs to make data?informed decisions to optimize process control and improve product yield and consistency. This year, we highlight a key challenge observed in practice: reduced prediction performance for atypical batches, where a harvest?timing CQA undergoes a rapid crash late in culture.
                                We first quantified the crash behaviour to define a consistent modelling target, then examined the role of integrated VCD and other features in identifying early signals of decline. These insights supported new models that predict the onset of the crash event and guided enhancements to the original real?time prediction algorithm to improve CQA forecasts within the crash region.
                                These updates strengthen model robustness across both typical and atypical trajectories, supporting more reliable harvest?timing decisions.

                                 

                                Sri Madabhushi

                                Senior Director

                                AstraZeneca

                                Sri is a Senior Director at AstraZeneca, where she leads teams focused on cell culture process development and material supply. She has served as CMC lead across multiple early- and late-stage programs, shaping timelines and strategy, orchestrating stakeholder management, and delivering end-to-end outcomes spanning drug substance, drug product, clinical supply, and regulatory submissions. As a recognized scientific leader, she defines the strategic roadmap for scientific and technology investments and has advanced next?generation innovations, including ultra?productive fed?batch processes (>20 g/L), process intensification and continuous manufacturing, media development, and end?to?end platform design.

                                 

                                Terrence Dombrowsky

                                Senior Director

                                Takeda

                                Terrence Dobrowsky has been a group leader in Biotherapeutics Process Development at Takeda since 2023. His group focuses on establishing Process, Automation, and In Silico tools to advance process performance, control, and overall development for Biologics programs. Prior to joining Takeda he led the Gene Therapy Drug Substance Development group at Biogen. He has supported the development of multiple Biologics programs as well as novel production platforms through internal development as well as industry or academic collaborations. He has contributed to program and technical initiatives spanning early phase development, mid-phase optimization and late-phase process characterization. Terrence earned B.S. in Chemical Engineering from the University of Notre Dame and a Ph.D. in Chemical and Biomolecular Engineering from Johns Hopkins University in 2010 where he focused on characterizing viral adhesion kinetics.

                                 

                                Lye Lin Lock

                                Associate Scientific Director

                                Bristol Myers Squibb

                                Lye Lin Lock is an Associate Scientific Director in the Downstream Biologics Process Development at Bristol Myers Squibb (Devens, MA). She leads digitalization initiatives that connect instrument data to cloud databases, standardize data capture for chromatography and filtration, and surface insights through automated dashboards. At BioTalk 2026, Lye Lin will share how to build a contextualized data framework that links ELN/eBR records, process metadata, and analytics to accelerate decisions and improve knowledge continuity across sites and tech transfer. Outside of work, Lye Lin enjoys baking bread and traveling to different national parks.

                                 

                                Min-Cheol Kim

                                Process Engineer IV

                                Sanofi

                                Dr. Min-Cheol Kim is a Process Engineer at Sanofi. His current interest areas are building hybrid models by integrating machine learning and digital twin modelling on bioprocess engineering and computational fluid dynamics (CFD) single and multiphase fluid simulations on mixing tanks.

                                Abstract

                                Controlling of desired set-point of glucose concentration has gained great interest in the upstream bioprocess engineering. In addition, it is also crucial in maintaining the product quality and less lactate production. For example, it has been known that too excessive dextrose can lead to increased waste production, such as lactate and ammonia, which can significantly reduce viable cell density in a bioreactor.

                                However, real-time control of glucose is currently limited because glucose has been offline-measured, and too frequent offline or even at-line measurement has practical limitations and increases the risk of contamination. Here, we present a robust model-based process control (MbPC) strategy for the successful glucose feeding in a bioreactor using only daily offline measurements.

                                Our MbPC strategy is composed of two kinds of formulas for predicting 1) glucose feeding amounts at daily sample time-points and 2) glucose feeding amounts at unsampled time-points.

                                First, we used a detailed simulation of the cell culture to determine a theoretical optimal dextrose feeding strategy for a nominal cell culture. Then we determined a practical feeding strategy that can be implemented given equipment constraints. Then the second part of the strategy is to augment that nominal open-loop control strategy with daily dextrose additions based on a discrete-time proportional control strategy to responds the expected variation from the assumed nominal performance.

                                Finally, we successfully implemented our MbPC strategy to Ambr250 bioreactor experiments for the frequent glucose feeding.

                                 

                                Kheng Tee Ng

                                Senior Scientist

                                Abbvie

                                Dr Kheng Tee Ng currently works as a Senior Scientist at AbbVie Biologics Singapore where he works on purification process development (i.e. process internalization, simplification and intensification) and CMC related aspects (i.e. tech transfer, process characterization modeling, facility fit, risk assessment and investigations) of biological drug development. Prior to working with AbbVie, he was a process characterization scientist at Lonza where he has directed multiple process characterization studies such as scale down model building for different unit operations (chromatography, depth filtration and UF/DF), resin lifetime as well as DoE modeling experiments which supported the establishment of NOR/PAR process ranges in FMEA for different customers. Dr Ng has obtained his PhD from University of Cambridge in 2016 and BSc from University College London in 2012.

                                 

                                Irina Ramos

                                Director, Bioprocess Technology and Engineering

                                AstraZeneca

                                Irina Ramos is a director of downstream continuous manufacturing, in the Bioprocess Engineering and Technology group at AstraZeneca in Gaithersburg, MD, USA. She has been a key driver of the technology development and implementation strategy for continuous biomanufacturing. Her team works to increase fundamental understanding of various downstream unit operations of drug substance manufacturing. They manage the design, testing and qualification of process equipment and automation of the systems to integrate them.

                                Dr Ramos holds a BS/MS in Chemical Engineering from University of Porto (Portugal) and a PhD in Chemical & Biochemical Engineering from University of Maryland, Baltimore County (UMBC). For the past 14 years, Dr Ramos’ work in the pharmaceutical industry has spanned from early to late-stage process development and validation, process scalability, CMC and technology transfer to both clinical and commercial manufacturing. With that experience, Irina lead process transfer efforts of the AZ COVID-19 vaccine. She has been involved with NIIMBL Process Intensification program by leading the Control Strategy workstream since 2020 and has been teaching graduate level classes on a Biotechnology Master program since 2015.

                                 

                                Rajat Sharma

                                Staff Engineer, Biotherapeutics process development
                                Takeda

                                I am Rajat Sharma, Ph.D.
                                I am currently working as the tech-transfer lead for GMP tech-transfers for clinical biologics assets at Takeda, in Lexington, MA.
                                My academic research involved studying and developing microbial processes for generation of valuable bio-products from fibrous agricultural waste biomass. (MS in Biological and Agricultural Engineering, NCSU, Raleigh, NC,& Ph.D. Food Science and Technology, ISU, Ames, IA).
                                I started my industrial career at Valent Biosciences in 2017, as a Sr. Fermentation engineer, where I was responsible for end-to-end large-scale upstream bacterial cell cultures.
                                I joined Takeda in 2020, as a member of the Microbial development team, where I worked on process development and CMC activities for the microbiome and E. coli protein expression programs.
                                I later moved on to my current role as Tech-Transfer lead for clinical GMP biologics assets, where I am responsible for seamless process transfers from process development/pilot processes to clinical GMP scales for internal and external manufacturing receiving units.

                                Abstract

                                Tech-transfer landscape is complex with multiple programs, multiple modalities and a wide network of manufacturing partners (internal/CDMOs). In such an environment, its important to approach a tech-transfer which is inherently a complex activity, with constant pressure of timely completion and being right: “first time”. This presentation is a high-level showcasing of the tools and approaches that can be employed in this complicated TT landscape. The discussion in this presentation will be centered around the following themes: tech-transfer work flow & structure, dos and donts, network strategy, comprehensive process transfer templates, streamlining flow of information, tech-transfer communication strategy, digitalization, and seamless connectivity to electronic management systems in manufacturing.

                                Dr. Sarwat Khattak

                                Head of Cell Culture and Cell Line Development

                                Biogen

                                Dr. Sarwat Khattak has 15+ years of experience in the biopharmaceutical industry and has been with Biogen since 2016. She is the Head of Cell Culture Development and Cell Line Development Biologics. Sarwat received her Ph.D. in Chemical Engineering from University of Massachusetts at Amherst and her B.S. in Chemical Engineering from MIT. She has extensive experience in recombinant protein program development through commercialization, cell culture media design, modelling cell culture processes, product quality optimization and continuous manufacturing.

                                 

                                 

                                 

                                Manoj Ganesh

                                Sr. Staff Process Scientist

                                Regeneron Pharmaceuticals

                                • PhD Materials Chemistry from NYU Tandon School of Engineering (2012)
                                • Joined Regeneron in 2018 - 5 years of BioPharmaceutical Downstream processing and Investigations
                                • Leads a Team of 10 People involved in Highthroughput Automation and Analytics
                                • Research experience in the field of Automation of downstream applications, Protein purification, Filtration, Polymer Chemistry, Biodegradable Polymer, Enzyme Immobilization & Bio-catalysis
                                • Publications include 7 journal articles, 1 book chapter and 1 patent awarded.

                                Fun Fact
                                • Prior to Regeneron, Manoj has 5 years of proactive startup skill experience in the biobased chemical industry
                                • Enjoys cycling.

                                 

                                Tom Ransohoff

                                Operating Partner, Keensight Capital, Principal, RTI Consulting

                                Keensight Capital

                                Thomas Ransohoff, M.S., has over 35 years of experience in the biopharmaceutical industry with broad experience in the development and manufacture of biologics and in the management of technology-based start-up firms. He is currently Principal, RTI Consulting, LLC, providing strategic and advisory consulting services to life sciences firms, and an Operating Partner with Keensight Capital. Previously, Mr. Ransohoff was Technical Head, Biologics Franchise for National Resilience, Inc. who he joined through the acquisition of 4th Dimension Bioprocess, where he was a co-founder and COO. Before joining Resilience, Mr. Ransohoff was a Managing Director at BDO and its precursor BioProcess Technology Consultants (BPTC), a leading CMC consulting firm that he helped build over a 20 year period. Prior to that, he held senior level positions at TranXenoGen, Dyax, Repligen, and Xoma. Mr. Ransohoff is a co-founder of several successful start-ups, including 4th Dimension Bioprocess, Tarpon Biosystems and BioFlash Partners, and he holds several board and scientific advisory board appointments. He holds a Bachelor's degree from MIT and a Master's degree from the University of California, Berkeley, both in Chemical Engineering.

                                 

                                Ishaan Shandil

                                Director, MS&T Process Modeling and Analytical Technologies
                                Bristol-Myers Squibb

                                 

                                Ishaan Shandil is a Biochemical Engineer with 16 years of process and product development, manufacturing and project leadership experience in the Biopharmaceutical industry. Ishaan currently works as an Associate Director Process Engineering MSAT Bristol-Myers Squibb (BMS) where he is responsible for leading projects in Process Engineering and Manufacturing Technology functions. In his role at BMS, he also manages the technical aspects of an external manufacturing relationship and provides CMO oversight. Prior to joining BMS, Ishaan worked for Merck & Co. in roles spanning across R&D and Manufacturing where he designed and developed scalable bioprocesses to manufacture differentiated biologics drug candidates. He also studied and published the impact of process conditions on Glycosylation in monoclonal antibodies and fusion proteins. Ishaan received a MS in Chemical & Biochemical Engineering from University of California Irvine and an MBA from University of Chicago Booth School of Business.

                                Henry Lin

                                Global Head, Cell Culture Process Development
                                Sanofi

                                Henry Lin is a 20+ years veteran in the biopharma industry with deep subject matter expertise in the upstream space as well broad CMC experience spanning pre-clinical to FIH to commercial. He is currently the Global Head of Cell Culture Process Development at Sanofi having responsibilities for all of upstream development in U.S. and France. Prior to Sanofi, Henry was an Executive Director in Biologics Process Development at Merck, Director of Cell Culture Development at Boehringer Ingelheim, and Principal Scientist at Amgen. Henry is a co-inventor on 10 patents and an author of 28 peer-reviewed publications. Henry received his PhD in biochemical engineering from Rice University and bachelor’s degree in bioengineering from UC San Diego.

                                Ionela Iliescu

                                Sr. Scientist
                                Amgen

                                Process Development Scientist at Biogen for 26 years. Coordinate purification development activities for antibodies, fusion proteins, and other types of biological therapeutics. Lead for purification strategy, process development for internal and external programs, process characterization, process validation activities and related global regulatory filings.

                                Spencer Monaco

                                Sr. Associate Scientist
                                Biogen

                                Spencer is an NCSU graduate with a B.S. in Polymer and Color Chemistry. His first job was working on the Biogen manufacturing floor alternating between upstream and downstream activities, until migrating into a development support role and expressing interest in upstream media development. He currently works with the cell culture development teams at Biogen, providing chemical expertise to investigations and new media formulation construction. As of 2024, Spencer has returned to NCSU to pursue a Masters in Polymer Chemistry exploring the possibility of bringing advances in polymer science into the media design space.

                                Abstract

                                Large scale media production presents various challenges to modern bio-pharmaceutical companies. Highly concentrated feed solutions must be constructed with extra care to ensure the solution remains viable throughout a campaign. A 5L small-scale model was designed to capture comparative mixing stress, temperature profiles, and exposure times to reliably replicate precipitation seen during a production run. The data from the scale down model was used to redesign the formulation and process parameters to produce a stable solution at all scales. In addition to automation parameters, floor operations were evaluated for gains in operational efficiency. Implementation of the observed process changes resulted in successful subsequent media preparation and confirmation of the scalable design.

                                Matthias Wiendahl

                                Principal Scientist
                                Novo Nordisk A/S

                                - Diploma in Biotechnology at Technical University Braunschweig, Germany
                                - PhD (Dr. Ing.) in Juergen Hubbuchs group at Research Center in Juelich, Germany
                                - 2007-2012: Development scientist at Novo Nordisk A/S, Denmark
                                - > 2012: Principal Scientist in Manufacturing Science and Technology department at Novo Nordisk Denmark

                                Abstract

                                Continuous capture chromatography is a chromatographic technique promising higher resin utilization, higher productivity and lower buffer consumption than traditional batch chromatography capture processes. The design of cSMB processes is more challenging than the design of batch processes because each chromatographic phase is influenced by the load from the previous phase and it is in turn influencing the subsequent phase. An iterative approach can be used to identify optimal conditions.

                                Our current process design approach is based on single column breakthrough curves and feeding the breakthrough data into a model. However, this concept leads to a sub-optimal process as it is based on a single loading flow rate, while effectively, flow rates and amounts in interconnected and parallel load phases can be different so using one flow rate only leads to sub-optimal processes.

                                We are presenting an approach where different flow rates and different breakthrough curves are used as model inputs together with pressure-flow dependencies for the resin of interest. Using the improved process design, significantly higher productivities were achieved than with the standard procedure. The effect was confirmed for a given in-house model process (mAb purification using Protein A affinity chromatography) where productivities could be increased by approximately 50% which has been confirmed at laboratory scale. The presented approach was also evaluated using mechanistic modelling. Finally, implications of the new cSMB design approach for large-scale manufacturing are discussed.  

                                Dr. Wenqin Ni

                                Senior Principal Scientist
                                Pfizer

                                I joined Pfizer in 2013. Currently, I am a Senior Principal Scientist in Pfizer and lead multiple analytical programs from early stage (before clinical study) to commercial approval. My expertise is focusing on analytical strategies such as process characterization and comparability studies. I successfully developed comparability strategies for multiple programs to support clinical or commercial material usage after manufacturing process changes. In addition, I am a key lead/member of analytical comparability expert group in Pfizer to review analytical comparability strategy for biologics. Before joining Pfizer, I received a Ph.D degree in Northeastern University focusing on characterization of post-translational modifications in biologics using LC/MS.

                                Abstract

                                During product development and the life cycle of commercial product, process changes are inevitable. Products manufactured using pre- and post- process changes are required to demonstrate comparability per ICH Q5E. A comparability study is a critical tool to ensure the “similarity” of product quality including efficacy, pharmacokinetics, safety and immunogenicity.
                                In this presentation, a phase appropriate risk assessment of process change will be introduced, followed by comparability strategy based on the risk assessment. Analytical comparability study tools will be discussed including the analytical comparability plan, comparability criteria, execution, data analysis and presentation. Furthermore, non-clinical and clinical comparability will be briefly discussed if there is any analytical difference which may impact product quality. Two comparability case studies will be presented. The first study is to support a new bioprocess to improve product quality and to facilitate larger scale manufacturing. The second one is to support the use of an early process stability study for establishing commercial shelf-life by leveraging the comparability study for an accelerated program. The agency feedback from multiple markets for the case studies will also be discussed.  

                                Kyle McHugh

                                Associate Director
                                Takeda Pharmaceuticals

                                Kyle McHugh received his PhD in Chemical and Biological Engineering from the University of Delaware on cell culture models of neurodegenerative disease. He worked in Upstream Biologics Process Development at Bristol Myers Squibb supporting commercial process development and process characterization for multiple therapeutic protein projects as well as high-throughput optimization, media development, and PAT advancement. Currently, Kyle is an Associate Director of Biotherapeutics Process Development at Takeda Pharmaceuticals in Lexington, MA supporting advancement of platform capabilities and multiple project modalities from FIH through late-stage development.

                                Abstract

                                Speed to clinic is critical to enable faster identification of successful early-stage drugs and subsequently faster BLA filing to commercialization. Here we discuss multiple levers to enable faster timelines to IND balancing prioritization of the timeline, business risk, and minimization of pre-investment. From a cell line perspective, strategic choice of source material for exploratory and GLP Tox studies allows for earlier delivery of representative material. Application of automation tools for screening clones and sampling bioreactors allows for more extensive screening and efficient process development. Data connectivity for automated capture and visualization of real-time offline and online process metrics helps to monitor ongoing runs, aggregate data for modelling, and streamline analysis for reports and regulatory submissions. Overall, we demonstrate significant improvements in speed, throughput, and automation for early-stage cell culture process development.

                                Angela Lewandowski

                                Sr. Director | GDPE (Global Downstream Dev/Pilot Plant/External Mfg)
                                Bristol Myers Squibb

                                Angela joined Bristol Myers Squibb in 2013, and over time has taken on increasing responsibilities. Angela and her team of 4 direct reports and 16 full-time employees are responsible for downstream process development for BMS’ growing biologics pipeline. Angela is currently doing a 6-month rotation, where she leads an additional team of 4 direct reports and 28 full-time employees responsible for process analytics. She has been the drug substance matrix lead since 2016 for a monoclonal antibody asset, from mid-stage through commercialization and life cycle management. She has driven several key strategic cross-functional initiatives. Prior to BMS, she worked for several years at Sanofi Genzyme and Regeneron Pharmaceuticals, and has a total of over 19 years of industrial experience. Angela holds M.S. and Ph.D. degrees in Chemical and Biomolecular Engineering from the University of Maryland, and a B.S. in Chemical Engineering from the University of Virginia.

                                Scott H. Altern

                                Senior Scientist
                                AbbVie

                                Scott H. Altern completed his PhD in Chemical Engineering at Rensselaer Polytechnic Institute (RPI) in Professor Steven Cramer's group (2023). His PhD research was centered on advancing the state-of-the-art in mechanistic modeling of preparative column chromatography and high-throughput process development. Currently, his role is at AbbVie in Worcester, MA where he focuses on mechanistic modeling of preparative chromatography, computational fluid dynamics, and molecular modeling to directly aid in process development. Scott is also highly involved in using high-throughput (HT) experimentation to expedite process development and model generation. Overall, Scott aims to transform industrial bioprocess development using automation and multiscale modeling.

                                Abstract

                                In this work, we employed HT instrumentation and multiscale modeling to support early-stage process development for two monoclonal antibodies (mAbs). These molecules had nearly the same isoelectric point but were found to behave differently in CEX. Both antibodies were screened for their dynamic binding capacity (DBC) on POROS XS RoboColumns across a wide range of loading pH and conductivity. Curiously, opposing DBC trends with loading pH and conductivity were observed between the mAbs. Generally, increasing loading pH and conductivity, beyond a certain threshold, results in a reduced DBC in CEX systems. This was consistent with the behavior for mAb B, but contradicted the trends seen for mAb A. Molecular modeling was then employed to identify the molecular features responsible for the unusual screening results. Homology models were constructed for each of the antibodies, from which molecular descriptors were calculated. Descriptors such as net charge and CDR positive charge surface area were correlated with DBC values to confirm that the degree of exclusion was directly related to molecular charge properties. Additionally, mechanistic model parameters were regressed from RoboColumn breakthrough curves to provide additional insight into the unique chromatographic behavior. For instance, trends in surface diffusivity with loading conductivity and pH were examined to determine their contribution to CEX loading performance. Further experimental studies were conducted in order to elucidate the molecular origins of the observed trends. Dynamic light scattering (DLS) experiments were carried out to determine the protein-protein interaction constant over a range of pH and conductivity. Interaction strength was found to be correlated with DBC, suggesting that repulsive forces negatively affect DBC and are dependent on solution conditions. In summary, this study used high-throughput screening and multiscale modeling in conjunction to facilitate CEX PD and improve process understanding from a molecular perspective. 

                                Daryl Powers, Ph.D.

                                Director, Bioprocess Technology Manufacturing, Science and Technology
                                Bristol Myers Squibb

                                Daryl is a director in the Bristol Myers Squibb MS&T drug substance group. He leads a team of process subject matter experts and laboratory scientists supporting the BMS commercial and registrational biologics portfolio. He has a PhD in chemical engineering and 18 years experience in the biotechnology industry.
                                 
                                Abstract
                                A commercial process was experiencing significant yield and product quality variability. To enhance process SME insights, the enterprise invested in a substantial modelling effort, which included building a data pipeline and conducting both non-proprietary and proprietary process modelling efforts. Initial observations confirmed SME insights and provided quantified targets for future batches. The work for this project highlighted opportunities to improve data quality through addition of PAT tools, expanded data sources, and incorporation of more mechanistic features into models.

                                Dhanuka Wasalathanthri

                                Associate Director
                                Bristol Myers Squibb

                                Dhanuka Wasalathanthri, Ph.D. is an Associate Director at Bristol Myers Squibb (BMS) where his main role is to serve as the strategy lead for Process Analytical Technology (PAT), High-Throughput Automation and Digital Capabilities at Analytical Development organization. He is a versatile leader with more than 10 years of biotech industry experience in strategic implementation of technologies, CMC analytical development, project management and building high-performing teams in meeting corporate goals. Dhanuka represents BMS at several academic and industry consortia, and he Holds a Ph.D. in Analytical Chemistry from University of Connecticut, USA.

                                Abstract

                                Biopharmaceutical landscape is getting increasing complex with a broad spectrum of modalities to meet unmet medical needs, while external geo-political, regulatory, generic competition and sustainability challenges demand acceleration of drug development pipelines. Despite significant advancements in the development and manufacturing workflows for faster and more efficient processes such as intensified and continuous operations, in-process analytical testing is still mainly centric around manual testing. Harnessing the power of automation enables fit-for-purpose and plug-and-play modular units with end-to-end parallel testing of multiple analytical assays with significant improvement in speed and productivity. The concept of robotic process automation (RPA) tools resembles as “Digital Workers” to automatically process, analyze and transcribe analytical results in real time which greatly improves the rapid availability of data to the stakeholders. Complex modalities in the pipeline often require non-platform analytical methods, unique approaches, and upfront investment on method development. Such efforts can be greatly simplified using data interrogation techniques such as Machine Learning and Deep Learning approaches. Herein a vision, roadmap and case studies of automation and digital transformation efforts measured against main KPI’s such as speed and productivity for in-process analytics for biologics are presented.

                                Shyam Panjwani

                                Principal Data Scientist
                                Bayer Pharmaceuticals

                                Shyam Panjwani is currently working as a Principal Data Scientist at Bayer Pharmaceuticals, Berkeley. He holds a PhD degree from University of Houston and a bachelor’s degree from Indian Institute of Technology, Kanpur in chemical engineering. He has 8+ of experience in applying AI/ML/statistics for biologics manufacturing processes, biological assays and process development. Before joining Bayer, he worked with Halliburton and Air Products.

                                Abstract

                                The biopharmaceutical industry is increasingly turning to data science to optimize manufacturing processes and enhance product quality. This presentation explores two innovative case studies that leverage data science to improve efficiency in biologics manufacturing.

                                The first case study focuses on a cloud-based predictive modeling application designed to enhance the predictability of mammalian cell culture processes. By forecasting bioreactor potency from at-line process parameters over a multiple-day horizon, this application quantifies prediction uncertainty and provides valuable insights for process control, ultimately enhancing productivity and product quality.

                                The second case study presents a novel framework for assessing the out-of-specification (OOS) risk associated with drug product potency. This framework utilizes a cloud-based statistical software application to streamline the evaluation of alternate potency targets, reducing manual errors and improving the efficiency of risk assessments.

                                Together, these case studies illustrate the transformative impact of data science on the biopharmaceutical manufacturing landscape. 

                                Sandra Bennun

                                Director Biologics Process Development, BPR&D
                                Merck

                                Experienced R&D Director with a demonstrated history of evaluating and delivering Process Analytics and Automation solutions to clinical and commercial biologics manufacturing.

                                Carrie has been with Lonza for 17 years. Her focus at Lonza includes commercial biomanufacturing SME support and technology transfer of clinical to commercial manufacturing. She has been a key contributor to the Lonza R&D efforts in intensified, continuous mAb manufacturing. Her current role is leading a multidisciplinary team in the investigation and development of novel bioprocessing modalities with a focus on process analytical technologies. Recently she was in charge of the design and build of a stand alone state of the art facility for the research of novel technology and automation. The Process Innovation Center was completed in March 2024. As the Head of the PIC, Carrie is responsible for directing PAT and Automation research, Industry and Academic collaborations in the New England Biotech Ecosystem.

                                She has over 25 years in industry primarily focused on development of chromatography and separations technology with associated analytical method development. She is a member of numerous industry consortia and collaborative efforts with the intent to drive forward innovations to advance the current biomanufacturing processes.

                                 

                                Carrie Mason 

                                Associate Director Bioprocess R&D
                                Lonza

                                Experienced R&D Director with a demonstrated history of evaluating and delivering Process Analytics and Automation solutions to clinical and commercial biologics manufacturing.

                                Carrie has been with Lonza for 17 years. Her focus at Lonza includes commercial biomanufacturing SME support and technology transfer of clinical to commercial manufacturing. She has been a key contributor to the Lonza R&D efforts in intensified, continuous mAb manufacturing. Her current role is leading a multidisciplinary team in the investigation and development of novel bioprocessing modalities with a focus on process analytical technologies. Recently she was in charge of the design and build of a stand alone state of the art facility for the research of novel technology and automation. The Process Innovation Center was completed in March 2024. As the Head of the PIC, Carrie is responsible for directing PAT and Automation research, Industry and Academic collaborations in the New England Biotech Ecosystem.

                                She has over 25 years in industry primarily focused on development of chromatography and separations technology with associated analytical method development. She is a member of numerous industry consortia and collaborative efforts with the intent to drive forward innovations to advance the current biomanufacturing processes.

                                 

                                Shuangping Shi

                                Associate Vice President, Head of Biologics Process Research & Development
                                Merck

                                Experienced pharma leader with extensive knowledge in biologics CMC, small molecule CMC, commercial manufacturing, bioanalytics, GLP lab management and GMP manufacturing facility operation.

                                 

                                Brandon Moore

                                Senior Cell Culture Engineer II
                                Biogen

                                Brandon Moore is an Upstream Process Engineer with 13 years of experience working on the development, characterization, and optimization of mammalian cell culture biomanufacturing processes with a specific focus on advanced process control and process analytics. Throughout this work, a recurring theme that has surfaced is the need for new approaches towards improving process understanding using advanced modelling and troubleshooting techniques which take the unique complexities and performance of cell-based systems into account.

                                Abstract

                                Variability was observed in the cell culture performance of inoculum stages in batches of a large-scale HEK293 commercial therapeutic protein production process. The impact was significant enough in result in termination of several batches, as insufficient cell mass was present to inoculate subsequent stages. Root cause analysis and bench-scale laboratory studies indicated that the large-scale media preparations were the root cause of the growth impact, and that the magnitude of impact varied between media bottles within a batch. Additionally, variability was observed between multiple batches of media which used identical filtration and preparation operations.

                                The investigation summarized in this case study examined each step of the media preparation and filtration processes. Bottle-to-bottle variability in media performance was replicated under laboratory conditions when using a specific 0.1µm polyethersulfone (PES) pre-filter which was part of the filtration platform for Chinese hamster ovary (CHO) processes. Interestingly, the first few bottles of media filtered were found to support normal growth—performance impact was first observed in later bottles, becoming more severe before eventually resolving. This behavior is inconsistent with the widely-held assumption that the magnitude of process impact would be greatest in the first volume of media passing through a filter. Replacing the filter was found to result in restoration of consistently high cell growth in the previously-impacted inoculum stages. This case study highlights the importance of the robust evaluation of filtration schemes between media formulations for different cell lines and the strategic application of platform process elements.

                                Alexandre Super

                                Lead Statistician CMC Development
                                UCB

                                Alexandre currently works within the Centre of Expertise CMC Statistics at UCB Pharma. He is responsible the development and implementation of statistical and modelling approaches for biologics and medical devices projects throughout their lifecycle, from the early stages of technical development all the way to commercial manufacturing.

                                Yiannis Dres

                                Process Engineer, Clinical Manufacturing
                                Pfizer

                                Alessandra Molinaro is a Process Engineer with six years of experience in the biopharmaceutical industry specializing in cell culture operations at the clinical scale. Alessandra has a Bachelor of Science in purification at the clinical-scale and GMP Manufacturing. Yianni has a Bachelor of Science in Chemical Engineering from University of Massachusetts Lowell and a Master of Science in Biotechnology from Worcester Polytechnic Institute.

                                Abstract

                                Implementation of a new technology in a GMP manufacturing environment present several distinct challenges, including adhering to regulatory requirements, implementing new methods into the existing systems, as well as management of new risks. In this work, we present a case study of the implementation of the One-Pot Capture Redox (OPCR), a novel technology for the production of multispecifics, into a clinical production facility.

                                This presentation will discuss the challenges of introducing the OPCR technology at the clinical manufacturing scale. Based on the success of implementation of the new technology, a harmonized approach has been identified to enable other new technologies to be implemented simpler in GMP manufacturing.

                                Alessandra Molinaro

                                Process Engineer, Clinical Manufacturing
                                Pfizer

                                Alessandra Molinaro is a Process Engineer with six years of experience in the biopharmaceutical industry specializing in cell culture operations at the clinical scale. Alessandra has a Bachelor of Science in Chemical Engineering from the University of Massachusetts Lowell and a Master of Science in Biotechnology from Worcester Polytechnic Institute.

                                Abstract

                                Implementation of a new technology in a GMP manufacturing environment present several distinct challenges, including adhering to regulatory requirements, implementing new methods into the existing systems, as well as management of new risks. In this work, we present a case study of the implementation of the One-Pot Capture Redox (OPCR), a novel technology for the production of multispecifics, into a clinical production facility.

                                This presentation will discuss the challenges of introducing the OPCR technology at the clinical manufacturing scale. Based on the success of implementation of the new technology, a harmonized approach has been identified to enable other new technologies to be implemented simpler in GMP manufacturing.

                                Jian Ren

                                Principal Scientist, Bioprocess Development
                                Abbvie

                                Jian Ren is a Principal Scientist in the Manufacturing Science and Technology (MSAT) organization at AbbVie Bioresearch Center in Worcester, MA. She leads process tech transfer, validation, and manufacturing support activities for the downstream manufacturing process for late phase and commercial biologics programs, including monoclonal antibodies, bispecific antibodies and fusion proteins. Prior to MSAT, she led purification process development, tech transfer, and validation activities for early-to-late-phase biologics projects. Prior to AbbVie, her research focused on the development and optimization of polymeric membranes and modules for various separation applications. Jian holds a PhD in Chemical Engineering from the University of Connecticut.

                                Lihua Yang

                                Senior Principal Research Scientist
                                Abbvie

                                Dr. Lihua Yang has been at AbbVie for over 20 years and is currently a Senior Principal Research Scientist and Group Leader within the Purification Development Department in Product Development Science and Technology organization. Dr. Yang led 25+ early and late phase programs and numerous innovation initiatives on biologics in areas of mAb, bispecific, antibody-drug conjugates and gene therapy. She has extensive experience in bioprocess development, characterization, validation, tech transfer to global GMP manufacture, process internalization, product launch, IND and BLA filing. Besides leading strong functional and cross-functional teams to deliver innovative and improved purification process, Dr. Yang is also a subject matter expert in bioanalytical assay development and protein characterization. Dr. Yang holds a Ph.D degree in Chemistry and Chemical Biology from Northeastern University, and a BS degree in Physical Chemistry from Peking University in China.

                                Tom Ransohoff

                                OPERATING PARTNER
                                Keensight Capital

                                With over 35 years of professional experience in the biopharma industry, his experience includes serving as the Technical Head of the biologicals franchise within Resilience, overseeing all activities related to recombinant protein and monoclonal antibody projects and technology development initiatives.

                                Prior to that, Tom has held various C-suite positions at other biopharma companies such as 4th Dimension Bioprocess, Inc. (co-founder and COO), BioFlash Partners (President and CEO), TranXenGen, Inc. (Vice President, Operations), Dyax Corp (Vice President, Program Management and Product Development).

                                Tom is a regular speaker at leading biopharma conferences, has published over 20 academic articles and has also developed and filed several patents, related to innovative biopharma manufacturing processes.

                                Tom holds a B.S in Chemical Engineering from MIT and a M.S. in Chemical Engineering from the University of California, Berkeley.

                                Ishaan Shandil

                                Director, MS&T Process Modeling and Analytical Technologies
                                Bristol Myers Squibb

                                Ishaan Shandil is a Biochemical Engineer with 16 years of process and product development, manufacturing and project leadership experience in the Biopharmaceutical industry. Ishaan currently works as an Associate Director Process Engineering MSAT Bristol-Myers Squibb (BMS) where he is responsible for leading projects in Process Engineering and Manufacturing Technology functions. In his role at BMS, he also manages the technical aspects of an external manufacturing relationship and provides CMO oversight. Prior to joining BMS, Ishaan worked for Merck & Co. in roles spanning across R&D and Manufacturing where he designed and developed scalable bioprocesses to manufacture differentiated biologics drug candidates. He also studied and published the impact of process conditions on Glycosylation in monoclonal antibodies and fusion proteins. Ishaan received a MS in Chemical & Biochemical Engineering from University of California Irvine and an MBA from University of Chicago Booth School of Business.

                                Ravi Vattepu

                                Senior Scientist Pivotal Biologics Drug Substance Technologies
                                Amgen

                                Ravi Vattepu is a Senior Scientist in the Pivotal Biologics Process Development group, focused on purification process development of biologics. He holds a PhD in Chemistry from Wichita State University and completed postdoctoral research at Harvard Medical School, where his work focused on antibody glycosylation and the role of IgG subclasses in inflammation.