Simultaneous monitoring of oxidation, deamidation, isomerization, and glycosylation of monoclonal antibodies by liquid chromatography-mass spectrometry method with ultrafast tryptic digestion

Wang, Yi; Li, Xiaojuan; Liu, Yan‐Hui; Richardson, Daisy; Li, Huijuan; Shameem, Mohammed; Yang, Xiaoyu

doi:10.1080/19420862.2016.1226715

Cited by 77 publications

(56 citation statements)

References 43 publications

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“…Similarly, MAM can facilitate the monitoring of host cell proteins (HCPs) with immunogenicity or safety risks, and for any HCPs at unacceptable levels, MAM can aid the optimization of purification processes for greater clearance (32). In addition to being an excellent formulation screening tool, MAM is now widely used to monitor specific oxidation, deamidation, isomerization, and/or succinimide formation events that can impact product potency and establish appropriate product expiries to mitigate their impact (8,10,(12)(13)(14)32,33).…”

Section: Mam Implementationmentioning

confidence: 99%

A View on the Importance of “Multi-Attribute Method” for Measuring Purity of Biopharmaceuticals and Improving Overall Control Strategy

Rogers

Abernathy

Richardson

et al. 2017

AAPS J

128

122

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Abstract.Today, we are experiencing unprecedented growth and innovation within the pharmaceutical industry. Established protein therapeutic modalities, such as recombinant human proteins, monoclonal antibodies (mAbs), and fusion proteins, are being used to treat previously unmet medical needs. Novel therapies such as bispecific T cell engagers (BiTEs), chimeric antigen T cell receptors (CARTs), siRNA, and gene therapies are paving the path towards increasingly personalized medicine. This advancement of new indications and therapeutic modalities is paralleled by development of new analytical technologies and methods that provide enhanced information content in a more efficient manner. Recently, a liquid chromatography-mass spectrometry (LC-MS) multi-attribute method (MAM) has been developed and designed for improved simultaneous detection, identification, quantitation, and quality control (monitoring) of molecular attributes (Rogers et al. MAbs 7(5): 2015). Based on peptide mapping principles, this powerful tool represents a true advancement in testing methodology that can be utilized not only during product characterization, formulation development, stability testing, and development of the manufacturing process, but also as a platform quality control method in dispositioning clinical materials for both innovative biotherapeutics and biosimilars.KEY WORDS: biotherapeutic; mass spectrometry; multi-attribute method; quality by design.To date, multi-attribute method (MAM) has been applied to several early stage clinical programs with different classes of protein therapeutics and compared to current practices. This experience shows that the MAM technology can be utilized for different types of protein therapeutics delivering highly specific and quantitative information, which is invaluable during process development and essential for molecular characterization. Data has also been generated to support its use for release and stability in alignment with Quality by Design (QbD) principles. Utilizing recent advances in the technology, research, and development labs, in industry, has generated convincing data that MAM would be highly beneficial in a cGMP environment. This article will summarize the advantages of MAM relative to conventional product testing approaches. We recommend that MAM, unlike conventional purity methods, be used to specifically monitor and quantify molecular product quality attributes and product/process-related impurities. This increased specificity for attributes with increased relevance to safety and efficacy can lead to better product/process understanding, shorter process and product development timelines, and an improved control strategy by improving specificity of the measurement. MAM OVERVIEWReduced LC-MS-based peptide mapping methods have been used in academia and the industry for several decades. Biopharmaceutical companies are increasingly using quantitative LC-MS-based peptide mapping methods for clinical material characterization, as well as release and stability testing (1-7). Quantit...

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Section: Mam Implementationmentioning

confidence: 99%

A View on the Importance of “Multi-Attribute Method” for Measuring Purity of Biopharmaceuticals and Improving Overall Control Strategy

Rogers

Abernathy

Richardson

et al. 2017

AAPS J

128

122

View full text Add to dashboard Cite

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“…The product quality was established using a multiattribute monitoring peptide mapping method. This method is similar to previous published examples . Protein samples (62 μg) are dried by centrifugal evaporation and then denatured with 75 μL solution of 6M Guanidine hydrochloride, 500 mM Tris, 1 mM EDTA at pH 8.2.…”

Section: Methodsmentioning

confidence: 96%

Development of a novel, high‐throughput screening tool for efficient perfusion‐based cell culture process development

Gagliardi

Chelikani

Yang

et al. 2019

Biotechnology Progress

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Perfusion technology has been successfully used for the commercial production of biotherapeutics, in particular unstable recombinant proteins, for more than a decade. However, there has been a general lack of high‐throughput cell culture tools specifically for perfusion‐based cell culture processes. Here, we have developed a high‐throughput cell retention operation for use with the ambr® 15 bioreactor system. Experiments were run in both 24 and 48 reactor configurations for comparing perfusion mimic models, media development, and clone screening. Employing offline centrifugation for cell retention and a variable volume model developed with MATLAB computational software, the established screening model has demonstrated cell culture performance, productivity, and product quality were comparable to bench scale bioreactors. The automated, single use, high‐throughput perfusion mimic is a powerful tool that enables us to have rapid and efficient process development of perfusion‐based cell culture processes.

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“…While general improvements in analytical instrumentation and strategies have been achieved over the past few decades [14], the ability to detect and characterize variants and impurities in biopharmaceuticals has been facilitated to a large degree by advancements in mass spectrometry, with current instruments achieving high resolution detection of peptides in the femtomolar and attomolar range [43,44]. This technology is being leveraged to allow improved detection of functionally relevant glycans on therapeutic proteins [45][46][47], as well as the assessment of minor product variants potentially relevant to protein structure or function, such as sequence variants, truncations, incorrect disulfide bridge structures, and other amino acid modifications [48][49][50][51][52][53][54]. Further, mass spectrometry has become an orthogonal tool in the monitoring of process impurities such as host cell proteins (HCPs), providing improved assessment of the type and amount of these impurities and their potential impact on product stability and immunogenicity [55,56].…”

Section: State-of-the-art Analytics For Detection and Control Of Critmentioning

confidence: 99%

Maintaining consistent quality and clinical performance of biopharmaceuticals

Lamanna¹,

Holzmann

Cohen³

et al. 2018

Expert Opinion on Biological Therapy

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Biopharmaceuticals are large protein based drugs which are heterogeneous by nature due to post translational modifications resulting from cellular production, processing and storage. Changes in the abundance of different variants over time are inherent to biopharmaceuticals due to their sensitivity to subtle process differences and the necessity for regular manufacturing changes. Product variability must thus be carefully controlled to ensure that it does not result in changes in safety or efficacy. Areas covered: The focus of this manuscript is to provide improved understanding of the science and strategies used to maintain the quality and clinical performance of biopharmaceuticals, including biosimilars, throughout their lifecycle. This review summarizes rare historical instances where clinically relevant changes have occurred, defined here as clinical drift, and discusses modern tools used to prevent such changes, including improved analytics, quality systems and regulatory frameworks. Expert opinion: Despite their size complexity and heterogeneity, modern analytics, manufacturing quality systems and comparability requirements for the evaluation of manufacturing changes cumulatively help to ensure the consistent quality and clinical performance of biopharmaceuticals throughout their product lifecycle. Physicians and patients can expect the same safety and efficacy from biopharmaceuticals and their respective biosimilars irrespective of batch or production history.

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Simultaneous monitoring of oxidation, deamidation, isomerization, and glycosylation of monoclonal antibodies by liquid chromatography-mass spectrometry method with ultrafast tryptic digestion

Cited by 77 publications

References 43 publications

A View on the Importance of “Multi-Attribute Method” for Measuring Purity of Biopharmaceuticals and Improving Overall Control Strategy

A View on the Importance of “Multi-Attribute Method” for Measuring Purity of Biopharmaceuticals and Improving Overall Control Strategy

Development of a novel, high‐throughput screening tool for efficient perfusion‐based cell culture process development

Maintaining consistent quality and clinical performance of biopharmaceuticals

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