Your search keyword '"Erwin Irdam"' showing total 13 results

1. Simple Methods to Predict Particle Size for Growth-Only Systems Undergoing One or More Temperature Cycles

Author

Daniel B. Patience, Erwin Irdam, Nicole Madden, Liang Chen, Min He, and Frederick Osei-Yeboah

Subjects

Organic Chemistry, Physical and Theoretical Chemistry

Published

2022

2. Cross-Pharma Collaboration for the Development of a Simulation Tool for the Model-Based Digital Design of Pharmaceutical Crystallization Processes (CrySiV)

Author

Nandkishor K. Nere, Daniel Patience, Aaron S. Cote, Yiqing Claire Liu, Moussa Boukerche, Iben Østergaard, Daniel Pohlman, Eric B. Sirota, Daniel A. Green, Kushal Sinha, Justin L. Quon, Ryan Ellis, Jaron Mackey, Daniel J. Jarmer, Botond Szilagyi, Michael A. Lovette, Huayu Li, Ayse Eren, Zoltan K. Nagy, Wei-Lee Wu, Rahn McKeown, Lorenzo Codan, Erwin Irdam, Shivani Kshirsagar, Kevin P. Girard, Megan Ketchum, Yihui Yang, Haiyan Qu, Christopher S. Polster, Jie Chen, Venkata Ramana Reddy, Emoke Szilagyi, Samir A. Kulkarni, Anna Jawor-Baczynska, Akshay Korde, Laurie Mlinar, Bing-Shiou Yang, Jochen Schoell, Christopher L. Burcham, Jeremy M. Merritt, and Simon N. Black

Subjects

Materials science, law, General Materials Science, General Chemistry, Crystallization, Condensed Matter Physics, Manufacturing engineering, law.invention

Abstract

Precompetitive collaborations on new enabling technologies for research and development are becoming popular among pharmaceutical companies. The Enabling Technologies Consortium (ETC), a precompetitive collaboration of leading innovative pharmaceutical companies, identifies and executes projects, often with third-party collaborators, to develop new tools and technologies of mutual interest. Here, we report the results of one of the first ETC projects: the development of a user-friendly population balance model (PBM)-based crystallization simulator software. This project required the development of PBM software with integrated experimental data handling, kinetic parameter regression, interactive process simulation, visualization, and optimization capabilities incorporated in a computationally efficient and robust software platform. Inputs from a team of experienced scientists at 10 ETC member companies helped define a set of software features that guided a team of crystallization modelers to develop software incorporating these features. Communication, continuous testing, and feedback between the ETC and the academic team facilitated the software development. The product of this project, a software tool called CrySiV, an acronym for Crystallization Simulation and Visualization, is reported herein. Currently, CrySiV can be used for cooling, antisolvent, and combined cooling and antisolvent crystallization processes, with primary and secondary nucleation, growth, dissolution, agglomeration, and breakage of crystals. This paper describes the features and the numerical methods of the software and presents two case studies demonstrating its use for parameter estimation. In the first case study, a simulated data set is used to demonstrate the capabilities of the software to find kinetic parameters and its goodness of fit to a known solution. In the second case study, the kinetics of an antisolvent crystallization of indomethacin from a ternary solvent system are estimated, providing a practical example of the tool.

Published

2021

3. Synthesis of Vixotrigine, a Voltage- and Use-Dependent Sodium Channel Blocker. Part 2: Development of a Late-Stage Process

Author

Hanspeter Matzinger, Vincent Couming, Daw-Iong Albert Kwok, Daniel Patience, Roman Kuhn, John Guzowski, Chaozhan Gu, Thiemo Stucki, Erwin Irdam, William F. Kiesman, Markus Stöckli, Michael Thut, Markus Grohmann, Michael Nonnenmacher, Benjamin Haefner, Wenli Liang, Robbie Chen, Paolangelo Cerea, Suzanne M. Opalka, Donald G. Walker, Stefan Sahli, Frederick Osei-Yeboah, Erin M. O’Brien, Joerg Lotz, Xin Zhang, and Tamera Mack

Subjects

medicine.medical_specialty, Use dependent, 010405 organic chemistry, Manufacturing process, business.industry, Organic Chemistry, Late stage, 010402 general chemistry, medicine.disease, 01 natural sciences, 0104 chemical sciences, Sodium channel blocker, Trigeminal neuralgia, Internal medicine, medicine, Cardiology, Physical and Theoretical Chemistry, business

Abstract

As vixotrigine (1) entered a later clinical phase for trigeminal neuralgia (Zakrzewska, J. M.; et al. Lancet Neurol. 2017, 16, 291−300), the development of a sustainable late-stage process was requ...

Published

2020

4. Improving the Manufacturability of Cohesive and Poorly Compactable API for Direct Compression of Mini-tablets at High Drug Loading via Particle Engineering

Author

Liang Chen, Yiqing Lin, Erwin Irdam, Nicole Madden, and Frederick Osei-Yeboah

Subjects

Pharmacology, Drug Compounding, Organic Chemistry, Pressure, Pharmaceutical Science, Molecular Medicine, Pharmacology (medical), Powders, Particle Size, Biotechnology, Tablets

Abstract

To utilize a particle engineering strategy to improve the manufacturability of a cohesive and poorly compactable API at high drug loading for direct compression of mini-tablets.A high-shear mixer was used for wet milling during the API manufacturing process to obtain target particle size distributions. The targeted particles were characterized and formulated into blends by mixing with excipients. The formulated blends were compressed directly into mini-tablets using a compaction simulator. The tablet hardness, weight variation, and friability of the mini-tablets were characterized and compared with mini-tablets prepared with hammer milled APIs.Compared to the hammer milled APIs, the wet milled APIs, had smoother surface, narrower particle size distributions and demonstrated a better flow properties. Moreover, the mini-tablets produced with the wet milled APIs exhibited better weight uniformity, robust tablet mechanical strength and ultimately better friability. In addition, unlike the hammer milled process, the wet milling process is controllable and easy to scale up.This study successfully implemented API particle engineering through a high shear wet milling process to produce particles suitable for robust drug product manufacturing.

Published

2022

5. Crystallization of a Metastable Solvate and Impact of the Isolation Method on the Material Properties of the Anhydrous Product

Author

Peterson Matthew, Erwin Irdam, Kenny Tran, Daniel Patience, Daw-Iong Kwok, Kalyan Vasudevan, and Frederick Osei-Yeboah

Subjects

Materials science, Organic Chemistry, Ethyl acetate, 02 engineering and technology, 021001 nanoscience & nanotechnology, 030226 pharmacology & pharmacy, law.invention, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, chemistry, Chemical engineering, law, Metastability, Scientific method, Particle-size distribution, Anhydrous, Desolvation, Physical and Theoretical Chemistry, Crystallization, 0210 nano-technology, Material properties

Abstract

We report the crystallization of a metastable small-molecule solvate and the effect of the isolation method on the physical and material properties of the resulting anhydrous material. The anhydrous crystalline products obtained from two different isolation routes using either a temperature-driven form change or a solvent-wash-mediated form change were analyzed by a suite of material-sparing characterization methods probing both physical form and material properties such as particle size distribution and powder flow behavior. The temperature-driven desolvation method was found to be time-consuming and undesirable. A relatively rapid desolvation approach was obtained using an ethyl acetate wash-mediated process. However, this method leads to powder with a broader particle size distribution, poorer flowability, higher interparticulate friction, and lower bulk density compared with the powder obtained by the temperature-driven desolvation process. The direct impact of the method of isolation on the material ...

Published

2018

6. Enteric coating of micron-size drug particles through a Würster fluid-bed process

Author

Min He, Shyam B. Karki, Erwin Irdam, Peter N. Zawaneh, J. Michael Macphee, Andrea N. Trementozzi, Pierre Boulas, Cheuk-Yui Leung, Yiqing Lin, and Jin Xu

Subjects

Active ingredient, Materials science, Scanning electron microscope, General Chemical Engineering, 02 engineering and technology, engineering.material, equipment and supplies, 021001 nanoscience & nanotechnology, 030226 pharmacology & pharmacy, Enteric coating, 03 medical and health sciences, 0302 clinical medicine, Chemical engineering, Coating, Fluidized bed, medicine, engineering, Dissolution testing, Particle size, 0210 nano-technology, Layer (electronics), medicine.drug

Abstract

Enteric coated active pharmaceutical ingredient (API) particles can provide advantages in clinical and pre-clinical formulation development targeting intestinal drug release over traditional tablet and capsule formulations. The challenge with this approach is developing a robust coating process to achieve sufficient gastric protection and efficient intestinal release on micron sized particles. A Wurster coating fluid bed process to directly produce enteric coated API particles was developed at a 650 g scale and was scaled up to 20 kg. Generating API with low 3-dimensional aspect ratio structure was critical for this process and was achieved through a wet milling process. The starting particle size had D50 ~ 90 μm, and the D50 of the resulting coated particles could be as small as 180 μm. Scanning electron microscopy imaging and dissolution testing were used to characterize the properties of the enteric layer on the API particles as a function of coating thickness. Coated API particles achieved up to 8 h enteric protection in the gastric environment and rapid release in the intestinal environment.

Published

2017

7. Engineered particles demonstrate improved flow properties at elevated drug loadings for direct compression manufacturing

Author

Shyam B. Karki, Cheuk-Yui Leung, Frederick Osei-Yeboah, Peter N. Zawaneh, Pierre Boulas, Andrea N. Trementozzi, Erwin Irdam, J. Michael Macphee, and Yiqing Lin

Subjects

Materials science, Flow (psychology), Compaction, Pharmaceutical Science, 02 engineering and technology, 030226 pharmacology & pharmacy, 03 medical and health sciences, 0302 clinical medicine, Technology, Pharmaceutical, Particle Size, Composite material, Cellulose, Active ingredient, Jet (fluid), Silicon Dioxide, 021001 nanoscience & nanotechnology, Compression (physics), Carboxymethylcellulose Sodium, Particle-size distribution, Microscopy, Electron, Scanning, Particle, Particle size, Powders, Rheology, 0210 nano-technology, Stearic Acids, Tablets

Abstract

Optimizing powder flow and compaction properties are critical for ensuring a robust tablet manufacturing process. The impact of flow and compaction properties of the active pharmaceutical ingredient (API) becomes progressively significant for higher drug load formulations, and for scaling up manufacturing processes. This study demonstrated that flow properties of a powder blend can be improved through API particle engineering, without critically impacting blend tabletability at elevated drug loadings. In studying a jet milled API (D 50 = 24 μm) and particle engineered wet milled API (D 50 = 70 μm and 90 μm), flow functions of all API lots were similarly poor despite the vast difference in average particle size ( ff c 4). This finding strays from the common notion that powder flow properties are directly correlated to particle size distribution. Upon adding excipients, however, clear trends in flow functions based on API particle size were observed. Wet milled API blends had a much improved flow function ( ff c > 10) compared with the jet milled API blends. Investigation of the compaction properties of both wet and jet milled powder blends also revealed that both jet and wet milled material produced robust tablets at the drug loadings used. The ability to practically demonstrate this uncommon observation that similarly poor flowing APIs can lead to a marked difference upon blending is important for pharmaceutical development. It is especially important in early phase development during API selection, and is advantageous particularly when material-sparing techniques are utilized.

Published

2017

8. The Enabling Technologies Consortium (ETC): Fostering Precompetitive Collaborations on New Enabling Technologies for Pharmaceutical Research and Development

Author

Erwin Irdam, Christopher J. Welch, Aaron S. Cote, Jean W. Tom, Pierre Boulas, Joel M. Hawkins, Kenneth M. Wells, Charles D. Papageorgiou, David Dermot Patrick Laffan, Margaret M. Faul, Purdie Mark, Rahn McKeown, Scott A. May, Steven J. Wittenberger, Srinivas Tummala, Kevin D. Seibert, Nicholas Murray Thomson, Frederick Hicks, Antonio Christian Ferretti, Paul Frank Fernandez, Keith Horspool, Shailendra Bordawekar, and Bing-Shiou Yang

Subjects

Engineering, Engineering management, Work (electrical), 010405 organic chemistry, business.industry, Organic Chemistry, Physical and Theoretical Chemistry, 010402 general chemistry, business, 01 natural sciences, 0104 chemical sciences, Structure and function

Abstract

The creation of the Enabling Technologies Consortium (ETC) is described. The ETC fosters precompetitive collaborations aimed at the development and evaluation of new enabling technologies for pharmaceutical research and development, with an initial focus on chemistry, manufacturing, and controls. An overview of the structure and function of the new organization, which will carry out its work while remaining mindful of antitrust compliance requirements, is herein presented along with a description of several ongoing development projects.

Published

2017

9. Discovery and Chemical Development of the Use-Dependent Sodium Channel Blocker Vixotrigine for the Treatment of Pain

Author

Robbie Chen, Michael Williams, Erwin Irdam, William F. Kiesman, Erin M. O’Brien, David T. MacPherson, John Guzowski, Stefan Sahli, Daw-Iong Albert Kwok, Suzanne M. Opalka, Daniel Patience, Tamera Mack, Couming Vinny, David R. Witty, Gerard M. P. Giblin, Wenli Liang, Frederick Osei-Yeboah, and Donald G. Walker

Subjects

Use dependent, Sodium channel blocker, Chemistry, Pharmacology

Published

2020

10. Case Studies in the Development of Drug Substance Control Strategies

Author

Nicholas Murray Thomson, John Lepore, Carla V. Luciani, Sushil K. Srivastava, Erwin Irdam, Robert A. Singer, Kevin D. Seibert, William F. Kiesman, and Luke Schenck

Subjects

Upstream (petroleum industry), Process (engineering), Computer science, media_common.quotation_subject, Organic Chemistry, Control (management), Process design, Risk analysis (engineering), Order (business), Quality (business), Product (category theory), Physical and Theoretical Chemistry, Critical quality attributes, media_common

Abstract

A series of case histories from IQ consortium member companies are presented in order to exemplify many of the different elements of drug substance control strategies that are required in order to ensure process performance and product quality. Control through process, method, and/or model design can combine to form a holistic control strategy that effectively manages risk and assures quality for the patient. A typical drug substance control strategy overview is presented, along with a number of detailed case histories that aim to demonstrate the use of process design and the development of methods and modeling to ensure control of critical quality attributes where appropriate, whether in the final drug substance or through upstream controls.

Published

2015

11. Case Studies in the Applicability of Drug Substance Design Spaces Developed on the Laboratory Scale to Commercial Manufacturing

Author

Kevin D. Seibert, Srinivas Tummala, Shailendra Bordawekar, Phenix Brian Dean, Daniel J. Kumke, Nicholas Murray Thomson, Erwin Irdam, and William F. Kiesman

Subjects

Computer science, business.industry, media_common.quotation_subject, Organic Chemistry, Laboratory scale, Commercialization, Manufacturing engineering, Product lifecycle, Quality (business), Physical and Theoretical Chemistry, business, Design space, media_common, Pharmaceutical industry

Abstract

A number of strategies have been employed within the pharmaceutical industry in order to mitigate the risk of applying design space boundaries developed on the laboratory scale to commercial drug substance manufacturing. The following communication presents a number of case histories from members of the International Consortium for Innovation and Quality in Pharmaceutical Development (IQ), with the aim of exemplifying strategies used to confirm applicability of design spaces developed on the laboratory scale. The strategies presented have a common aim of ensuring that appropriate quality standards are developed, maintained, and enhanced during the product lifecycle whilst delivering rapid and cost-effective mechanisms for drug substance commercialization.

Published

2014

12. Understanding and Control of Dimethyl Sulfate in a Manufacturing Process: Kinetic Modeling of a Fischer Esterification Catalyzed by H2SO4

Author

William F. Kiesman, John Guzowski, Michael Humora, Albert Kwok, Edward J. Delaney, Erwin Irdam, and Amy D. Moran

Subjects

chemistry.chemical_classification, organic chemicals, Carboxylic acid, fungi, Organic Chemistry, Sulfuric acid, Catalysis, chemistry.chemical_compound, Dimethyl sulfate, Reaction rate constant, chemistry, Yield (chemistry), Organic chemistry, Dimethyl ether, Methanol, Physical and Theoretical Chemistry

Abstract

The formation and fate of monomethyl sulfate (MMS) and dimethyl sulfate (DMS) were studied by proton NMR for a sulfuric acid catalyzed esterification reaction in methanol. The kinetic rate constants for DMS and MMS were determined at 65 °C by fitting time-dependent experimental data to a model using DynoChem. In refluxing methanol, sulfuric acid was converted to monomethyl sulfate (MMS) in nearly quantitative yield within 45 min. Once formed, the MMS underwent a reversible esterification reaction to form DMS. Dimethylsulfate reacted with methanol to regenerate MMS and form dimethyl ether. A byproduct of the esterification reaction was water, which further consumed DMS through hydrolysis. On the basis of derived rate constants, in refluxing methanol, DMS would not be expected to exceed 4 ppm in the reaction mixture at equilibrium. In the presence of the carboxylic acid substrate, DMS was not detected in the reaction mixture. The reaction pathways of this system have been systematically investigated, and th...

Published

2012

13. Development of a Practical Large-Scale Synthesis of Denagliptin Tosylate

Author

Michael P LeBlanc, Jeremiah D. Powers, Erwin Irdam, Martin H. Osterhout, Tyler Sharkey, Daniel E. Patterson, and Emily Boehler

Subjects

Chemistry, Organic Chemistry, Late stage, Nanotechnology, Physical and Theoretical Chemistry, Combinatorial chemistry, DENAGLIPTIN TOSYLATE

Abstract

A large-scale synthesis of denagliptin tosylate has been developed. The efficiency of the synthesis has been improved from the initially scaled route by changing the order of steps (performing a dehydration at a late stage). The key step of the synthesis is a single-step peptide coupling/dehydration, mediated by n-propanephosphonic acid cyclic anhydride. The challenges of developing this synthesis into a robust and practical manufacturing route are described.

Published

2009