Long-term stability predictions of therapeutic monoclonal antibodies in solution using Arrhenius-based kinetics

Kuzman, Drago; Bunc, M.; Ravnik, Miha; Reiter, Fritz; Žagar, Lan; Bončina, Matjaž

doi:10.1038/s41598-021-99875-9

Cited by 51 publications

(44 citation statements)

References 48 publications

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“…Recently, Kuzman et al and Gentiluomo et al have shown some potential for predicting long-term shelf-life stability when using non-linear machine learning models. 32 , 33 This, however, also leads to some challenges when assuming first-order kinetics of proteins that may be susceptible to different degradation pathways that may affect chemical and physical stability upon exposure to thermal stress. 34 Therefore, the accelerated stability and real-time stability measurements are different approaches.…”

Section: Discussionmentioning

confidence: 99%

Machine learning prediction of antibody aggregation and viscosity for high concentration formulation development of protein therapeutics

Lai

Gallegos

Mody

et al. 2022

mAbs

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Machine learning has been recently used to predict therapeutic antibody aggregation rates and viscosity at high concentrations (150 mg/ml). These works focused on commercially available antibodies, which may have been optimized for stability. In this study, we measured accelerated aggregation rates at 45°C and viscosity at 150 mg/ml for 20 preclinical and clinical-stage antibodies. Features obtained from molecular dynamics simulations of the full-length antibody and sequences were used for machine learning model construction. We found a k-nearest neighbors regression model with two features, spatial positive charge map on the CDRH2 and solvent-accessible surface area of hydrophobic residues on the variable fragment, gives the best performance for predicting antibody aggregation rates (r = 0.89). For the viscosity classification model, the model with the highest accuracy is a logistic regression model with two features, spatial negative charge map on the heavy chain variable region and spatial negative charge map on the light chain variable region. The accuracy and the area under precision recall curve of the classification model from validation tests are 0.86 and 0.70, respectively. In addition, we combined data from another 27 commercial mAbs to develop a viscosity predictive model. The best model is a logistic regression model with two features, number of hydrophobic residues on the light chain variable region and net charges on the light chain variable region. The accuracy and the area under precision recall curve of the classification model are 0.85 and 0.6, respectively. The aggregation rates and viscosity models can be used to predict antibody stability to facilitate pharmaceutical development.

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Section: Discussionmentioning

confidence: 99%

Machine learning prediction of antibody aggregation and viscosity for high concentration formulation development of protein therapeutics

Lai

Gallegos

Mody

et al. 2022

mAbs

View full text Add to dashboard Cite

show abstract

“…Such non-linear degradation over time, as detected for HMWP formation of SAR441255, is also often observed for several (e.g., aggregation related) quality attributes of vaccines and therapeutic antibodies [25,[34][35][36][37]49,[51][52][53][54], underlining the benefit of screening various kinetic models for biopharmaceutics. With appropriate kinetic models that accurately describe the degradation progress as a function of time and temperature, various applications emerge, such as estimation of shelf life [34][35][36][37][38], accurate degradation-based predictions for products during various types of temperature excursions [35,38,49], ranking of formulations [37,39,49], batch-to-batch comparisons and real-time shelf-life monitoring of products during shipments [39,40,49].…”

Section: Discussionmentioning

confidence: 82%

“…Very recently, Kuzman et al [25] successfully used Arrhenius-based kinetics to predict long-term stability of IgG1, IgG2, and fusion proteins. For some key stability attributes such as sum of aggregates by SEC, accurate predictions of long-term stability were obtained using first-order kinetics.…”

Section: Discussionmentioning

confidence: 99%

“…Of course, further studies will be required to demonstrate general applicability of this approach for therapeutic peptides. However, successful applications of long-term predictions using advanced kinetic modeling for vaccines [34][35][36][37][38][39][40] and antibodies using Arrhenius kinetics [25] suggest that these approaches are generally applicable for a broader range of modalities. The AKTS software can, in principle, operate on any kind of data that follow a reaction progress without the need to know the exact molecular mechanism and kinetic model.…”

Section: Discussionmentioning

confidence: 99%

“…Several approaches have been described that predict the shelf life of liquid dosage forms of biopharmaceutics based on accelerated stability studies [22][23][24][25][26][27][28][29][30]. These are generally performed at elevated temperatures (e.g., 25 and 40 • C), whereas the recommended temperature for long-term storage is usually between 2 and 8 • C for injectable biopharmaceutics.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Long-Term Stability Prediction for Developability Assessment of Biopharmaceutics Using Advanced Kinetic Modeling

2022

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A crucial aspect of pharmaceutical development is the demonstration of long-term stability of the drug product. Biopharmaceuticals, such as proteins or peptides in liquid formulation, are typically administered via parental routes and should be stable over the shelf life, which generally includes a storing period (e.g., two years at 5 °C) and optionally an in-use period (e.g., 28 days at 30 °C). Herein, we present a case study where chemical degradation of SAR441255, a therapeutic peptide, in different formulations in combination with primary packaging materials was analyzed under accelerated conditions to derive long-term stability predictions for the recommended storing conditions (two years at 5 °C plus 28 days at 30 °C) using advanced kinetic modeling. These predictions served as a crucial decision parameter for the entry into clinical development. Comparison with analytical data measured under long-term conditions during the subsequent development phase demonstrated a high prediction accuracy. These predictions provided stability insights within weeks that would otherwise take years using measurements under long-term stability conditions only. To our knowledge, such in silico studies on stability predictions of a therapeutic peptide using accelerated chemical degradation data and advanced kinetic modeling with comparisons to subsequently measured real-life long-term stability data have not been described in literature before.

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Dynamic optimization of an integrated cultivation‐aggregation model for mAb production

Jones,

Gerogiorgis

2024

Biotech & Bioengineering

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Due to their proteinaceous structure, monoclonal antibodies (mAbs) are susceptible to irreversible aggregation, with harmful consequences on drug efficacy and patient safety. To mitigate this risk in modern biopharmaceutical processes, it is critical to comply with current good manufacturing practices (cGMP) and pursue operating strategies minimizing irreversible aggregation whilst also maximizing mAb throughput. These conflicting objectives are targeted in this study by formulating and analyzing an integrated dynamic model accounting for both cultivation and aggregation of mAbs from a Chinese Hamster Ovary (CHO) cell line. Two manipulated dynamic variables are considered here in simulation studies: firstly temperature manipulation within a batch reactor, and secondly feed flow manipulation within a series of isothermal fed‐batch reactors. Following this, dynamic optimization investigations have been conducted, firstly with the single objective of maximizing mAb throughput and secondly with multiple (two) objectives of maximizing mAb throughput while also minimizing irreversible aggregate content, simultaneously. The study provides key insight into tradeoffs of how simultaneous temperature and feed flowrate manipulation affects mAb throughput and aggregation inside bioreactors.

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Long-term stability predictions of therapeutic monoclonal antibodies in solution using Arrhenius-based kinetics

Cited by 51 publications

References 48 publications

Machine learning prediction of antibody aggregation and viscosity for high concentration formulation development of protein therapeutics

Machine learning prediction of antibody aggregation and viscosity for high concentration formulation development of protein therapeutics

Long-Term Stability Prediction for Developability Assessment of Biopharmaceutics Using Advanced Kinetic Modeling

Dynamic optimization of an integrated cultivation‐aggregation model for mAb production

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