Finite Element Method (FEM) Modeling of Freeze-drying: Monitoring Pharmaceutical Product Robustness During Lyophilization

Lyophilization is an approach commonly undertaken to formulate drugs that are unstable to be commercialized as ready to use (RTU) solutions. One of the important aspects of commercializing a lyophilized product is to transfer the process parameters that are developed in lab scale lyophilizer to commercial scale without a loss in product quality. This process is often accomplished by costly engineering runs or through an iterative process at the commercial scale. Here, we are highlighting a combination of computational and experimental approach to predict commercial process parameters for the primary drying phase of lyophilization. Heat and mass transfer coefficients are determined experimentally either by manometric temperature measurement (MTM) or sublimation tests and used as inputs for the finite element model (FEM)-based software called PASSAGE, which computes various primary drying parameters such as primary drying time and product temperature. The heat and mass transfer coefficients will vary at different lyophilization scales; hence, we present an approach to use appropriate factors while scaling-up from lab scale to commercial scale. As a result, one can predict commercial scale primary drying time based on these parameters. Additionally, the model-based approach presented in this study provides a process to monitor pharmaceutical product robustness and accidental process deviations during Lyophilization to support commercial supply chain continuity. The approach presented here provides a robust lyophilization scale-up strategy; and because of the simple and minimalistic approach, it will also be less capital intensive path with minimal use of expensive drug substance/active material.

[1]  A. Barresi,et al.  Quality by Design: Scale-Up of Freeze-Drying Cycles in Pharmaceutical Industry , 2013, AAPS PharmSciTech.

[2]  H. Gieseler,et al.  Heat transfer characteristics of current primary packaging systems for pharmaceutical freeze-drying. , 2012, Journal of pharmaceutical sciences.

[3]  Gregory A Sacha,et al.  Quality by design in formulation and process development for a freeze-dried, small molecule parenteral product: a case study , 2011, Pharmaceutical development and technology.

[4]  Sumit Luthra,et al.  Investigation of Design Space for Freeze-Drying: Use of Modeling for Primary Drying Segment of a Freeze-Drying Cycle , 2011, AAPS PharmSciTech.

[5]  Robert E. Johnson,et al.  Use of manometric temperature measurements (MTM) to characterize the freeze-drying behavior of amorphous protein formulations. , 2010, Journal of pharmaceutical sciences.

[6]  Michael J. Pikal,et al.  Determination of End Point of Primary Drying in Freeze-Drying Process Control , 2010, AAPS PharmSciTech.

[7]  Steven L Nail,et al.  Rapid freeze-drying cycle optimization using computer programs developed based on heat and mass transfer models and facilitated by tunable diode laser absorption spectroscopy (TDLAS). , 2009, Journal of pharmaceutical sciences.

[8]  Michael J Pikal,et al.  Use of manometric temperature measurement (MTM) and SMART freeze dryer technology for development of an optimized freeze-drying cycle. , 2007, Journal of pharmaceutical sciences.

[9]  Steven J Davis,et al.  Evaluation of tunable diode laser absorption spectroscopy for in-process water vapor mass flux measurements during freeze drying. , 2007, Journal of pharmaceutical sciences.

[10]  Michael J. Pikal,et al.  Heat and mass transfer scale-up issues during freeze-drying, III: Control and characterization of dryer differences via operational qualification tests , 2006, AAPS PharmSciTech.

[11]  Xiaolin Tang,et al.  Freeze-Drying Process Design by Manometric Temperature Measurement: Design of a Smart Freeze-Dryer , 2005, Pharmaceutical Research.

[12]  H. U. Akay,et al.  The Nonsteady State Modeling of Freeze Drying: In-Process Product Temperature and Moisture Content Mapping and Pharmaceutical Product Quality Applications , 2005, Pharmaceutical development and technology.

[13]  Michael J Akers,et al.  Practical Formulation and Process Development of Freeze-Dried Products , 2005, Pharmaceutical development and technology.

[14]  Xiaolin Tang,et al.  Design of Freeze-Drying Processes for Pharmaceuticals: Practical Advice , 2004, Pharmaceutical Research.

[15]  Michael J. Pikal,et al.  Heat and mass transfer scale-up issues during freeze-drying, I: Atypical radiation and the edge vial effect , 2003, AAPS PharmSciTech.

[16]  Hasan U. Akay,et al.  A computational model for finite element analysis of the freeze-drying process , 1997 .

[17]  G. Stacey,et al.  Cryopreservation and Freeze-Drying Protocols , 1995, Methods in Molecular Biology™.

[18]  M. Pikal,et al.  Use of laboratory data in freeze drying process design: heat and mass transfer coefficients and the computer simulation of freeze drying. , 1985, Journal of parenteral science and technology : a publication of the Parenteral Drug Association.

[19]  S L Nail,et al.  The effect of chamber pressure on heat transfer in the freeze drying of parenteral solutions. , 1980, Journal of the Parenteral Drug Association.

[20]  D M Kremer,et al.  A procedure to optimize scale-up for the primary drying phase of lyophilization. , 2009, Journal of pharmaceutical sciences.

[21]  Michael J. Pikal,et al.  Evaluation of manometric temperature measurement (MTM), a process analytical technology tool in freeze drying, part III: Heat and mass transfer measurement , 2008, AAPS PharmSciTech.

[22]  S L Nail,et al.  Evaluation of manometric temperature measurement as a method of monitoring product temperature during lyophilization. , 1997, PDA journal of pharmaceutical science and technology.

[23]  M. Mclellan,et al.  Cryopreservation and freeze-drying protocols. Introduction. , 1995, Methods in molecular biology.