Monitoring and digital design of the cooling crystallization of a high-aspect ratio anticancer drug using a two-dimensional population balance model
Published 2022 View Full Article
- Home
- Publications
- Publication Search
- Publication Details
Title
Monitoring and digital design of the cooling crystallization of a high-aspect ratio anticancer drug using a two-dimensional population balance model
Authors
Keywords
-
Journal
CHEMICAL ENGINEERING SCIENCE
Volume 257, Issue -, Pages 117700
Publisher
Elsevier BV
Online
2022-04-30
DOI
10.1016/j.ces.2022.117700
References
Ask authors/readers for more resources
Related references
Note: Only part of the references are listed.- Iterative Model Based Experimental Design for Spherical Agglomeration Processes
- (2021) Kanjakha Pal et al. AICHE JOURNAL
- Dimensionless Framework for Seed Recipe Design and Optimal Control of Batch Crystallization
- (2021) Hao-Jen Pan et al. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH
- Digital Design of the Crystallization of an Active Pharmaceutical Ingredient Using a Population Balance Model with a Novel Size Dependent Growth Rate Expression. From Development of a Digital Twin to In Silico Optimization and Experimental Validation
- (2021) Botond Szilágyi et al. CRYSTAL GROWTH & DESIGN
- Application of Model-Free and Model-Based Quality-by-Control (QbC) for the Efficient Design of Pharmaceutical Crystallization Processes
- (2020) Botond Szilagyi et al. CRYSTAL GROWTH & DESIGN
- Model-based analysis and quality-by-design framework for high aspect ratio crystals in crystallizer-wet mill systems using GPU acceleration enabled optimization
- (2019) Botond Szilagyi et al. COMPUTERS & CHEMICAL ENGINEERING
- Advantages of Utilizing Population Balance Modeling of Crystallization Processes for Particle Size Distribution Prediction of an Active Pharmaceutical Ingredient
- (2019) Tamar Rosenbaum et al. Processes
- Hybrid modeling based on mechanistic and data-driven approaches for cane sugar crystallization
- (2019) Yanmei Meng et al. JOURNAL OF FOOD ENGINEERING
- Image Analysis for In-line Measurement of Multidimensional Size, Shape, and Polymorphic Transformation of l-Glutamic Acid Using Deep Learning-Based Image Segmentation and Classification
- (2018) Zhenguo Gao et al. CRYSTAL GROWTH & DESIGN
- Development and Scale-Up of a Crystallization Process To Improve an API’s Physiochemical and Bulk Powder Properties
- (2018) Landon Durak et al. ORGANIC PROCESS RESEARCH & DEVELOPMENT
- A framework for model reliability and estimability analysis of crystallization processes with multi-impurity multi-dimensional population balance models
- (2018) D. Fysikopoulos et al. COMPUTERS & CHEMICAL ENGINEERING
- What is the “typical” particle shape of active pharmaceutical ingredients?
- (2017) Weili Yu et al. POWDER TECHNOLOGY
- Effect of needle-like crystal shape on measured particle size distributions
- (2016) Ian de Albuquerque et al. AICHE JOURNAL
- Graphical processing unit (GPU) acceleration for numerical solution of population balance models using high resolution finite volume algorithm
- (2016) Botond Szilágyi et al. COMPUTERS & CHEMICAL ENGINEERING
- A Short-Cut Method for the Quantification of Crystallization Kinetics. 2. Experimental Application
- (2016) Erik Temmel et al. CRYSTAL GROWTH & DESIGN
- A design aid for crystal growth engineering
- (2016) Jinjin Li et al. PROGRESS IN MATERIALS SCIENCE
- Application of Process Analytical Technology-Based Feedback Control Strategies To Improve Purity and Size Distribution in Biopharmaceutical Crystallization
- (2015) Elena Simone et al. CRYSTAL GROWTH & DESIGN
- Multi-Impurity Adsorption Model for Modeling Crystal Purity and Shape Evolution during Crystallization Processes in Impure Media
- (2015) Akos Borsos et al. CRYSTAL GROWTH & DESIGN
- Face-Specific Growth and Dissolution Kinetics of Potassium Dihydrogen Phosphate Crystals from Batch Crystallization Experiments
- (2014) H. Eisenschmidt et al. CRYSTAL GROWTH & DESIGN
- Modification of Crystal Shape through Deep Temperature Cycling
- (2014) Mo Jiang et al. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH
- Recent advances in the monitoring, modelling and control of crystallization systems
- (2013) Zoltan K. Nagy et al. CHEMICAL ENGINEERING RESEARCH & DESIGN
- High accuracy online measurement of multidimensional particle size distributions during crystallization
- (2013) Stefan Schorsch et al. CHEMICAL ENGINEERING SCIENCE
- Comparison of laser diffraction and image analysis for measurement of Streptomyces coelicolor cell clumps and pellets
- (2012) Nanna Petersen Rønnest et al. BIOTECHNOLOGY LETTERS
- Image-Analysis-Based Method for 3D Crystal Morphology Measurement and Polymorph Identification Using Confocal Microscopy
- (2012) Meenesh R. Singh et al. CRYSTAL GROWTH & DESIGN
- Predictive Modeling of Supersaturation-Dependent Crystal Shapes
- (2012) Michael A. Lovette et al. CRYSTAL GROWTH & DESIGN
- Advances and New Directions in Crystallization Control
- (2012) Zoltan K. Nagy et al. Annual Review of Chemical and Biomolecular Engineering
- Optimal seed recipe design for crystal size distribution control for batch cooling crystallisation processes
- (2010) E. Aamir et al. CHEMICAL ENGINEERING SCIENCE
- Controlling crystal growth with modifiers
- (2009) Franca Jones et al. CRYSTENGCOMM
- Two-dimensional population balance model with breakage of high aspect ratio crystals for batch crystallization
- (2008) Kazuhiro Sato et al. CHEMICAL ENGINEERING SCIENCE
- On the prediction of crystal shape distributions in a steady-state continuous crystallizer
- (2008) Christian Borchert et al. CHEMICAL ENGINEERING SCIENCE
- Determination of the Kinetic Parameters for the Crystallization of Paracetamol from Water Using Metastable Zone Width Experiments
- (2008) Zoltan K. Nagy et al. INDUSTRIAL & ENGINEERING CHEMISTRY RESEARCH
Discover Peeref hubs
Discuss science. Find collaborators. Network.
Join a conversationPublish scientific posters with Peeref
Peeref publishes scientific posters from all research disciplines. Our Diamond Open Access policy means free access to content and no publication fees for authors.
Learn More