Aggregate structure, morphology and the effect of aggregation mechanisms on viscosity at elevated protein concentrations

Barnett, Gregory V.; Wei, Qi; Amin, Samiul; Lewis, E. Neil; Roberts, Christopher J.

doi:10.1016/j.bpc.2015.07.002

Cited by 34 publications

(17 citation statements)

References 57 publications

(116 reference statements)

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“…As seen in Figure (B), these variations are not observed at early times, and all the temperature conditions show linear behavior for M w / M 1 values below approximately 2, which is consistent with previous work for aggregation of monoclonal antibodies . The upward curvature at later times in Figure (A) is expected, as aggregates grow to larger sizes and likely also coalesce with each other . The linear regime obtained up to M w / M 1 ∼ 2 [cf., Fig.…”

Section: Resultssupporting

confidence: 89%

“…S1(A)]. This qualitative behavior was also consistent with results for other proteins . As noted in Methods, attempts to purify dimer via chromatography for seeding experiments were unsuccessful, potentially because of issues with column interactions that limited resolution of monomer and aggregate species that are being investigated as part of future work.…”

Section: Resultssupporting

confidence: 78%

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Parallel chromatography and in situ scattering to interrogate competing protein aggregation pathways

et al. 2018

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Protein aggregation can follow different pathways, and these can result in different net aggregation rates and kinetic profiles. α-chymotypsinogen A (aCgn) was used as a model system to quantitatively and qualitatively assess an approach that combines ex situ size-exclusion chromatography (SEC) with in situ laser scattering (LS) to monitor aggregation vs. time. Aggregation was monitored for a series of temperatures and initial dimer (ID) levels for starting conditions that were primarily (> 97%) monomer, and under initial-rate conditions (limited to low monomer conversion-less than 20% monomer mass loss), as these conditions are of most to interest to many pharmaceutical and biotechnology applications. SEC results show that modest decreases of ID levels can greatly reduce monomer loss rates, but do not affect the effective activation energy for aggregation. The normalized aggregation rates determined from LS were typically ∼ 1 order of magnitude higher than the corresponding rates from SEC. Furthermore, LS signals vs. time became variable and highly nonlinear with decreasing ID level, temperature, and/or total protein concentration. Temperature-cycling LS experiments showed this corresponded to conditions where dimer/oligomer "seeding" was suppressed, and high levels of reversible oligomers ("prenuclei") were formed prior to "nucleation" and growth of stable aggregates. In those conditions, aggregation rates inferred from LS and SEC are greatly different, as the techniques monitor different stages of the aggregation process. Overall, the results illustrate an approach for interrogating non-native protein aggregation pathways, and potential pitfalls if one relies on a single method to monitor aggregation-this holds more generally than the particular methods here.

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Section: Resultssupporting

confidence: 89%

Section: Resultssupporting

confidence: 78%

Parallel chromatography and in situ scattering to interrogate competing protein aggregation pathways

et al. 2018

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“…Nicoud et al 48 show that the aggregate fractal dimension of a mAb increases as concentration rises. Barnett et al 49 used the protein a-chymotrypsinogen as a model system to illustrate that the 3D structure of the protein changes with increasing concentration. In this case, monomer loss is followed by increase in viscosity.…”

Section: Theoretical Foundations and Experimentally Measurable Quantimentioning

confidence: 99%

Molecular basis of high viscosity in concentrated antibody solutions: Strategies for high concentration drug product development

Tomar

Kumar

Singh

et al. 2016

mAbs

147

145

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Effective translation of breakthrough discoveries into innovative products in the clinic requires proactive mitigation or elimination of several drug development challenges. These challenges can vary depending upon the type of drug molecule. In the case of therapeutic antibody candidates, a commonly encountered challenge is high viscosity of the concentrated antibody solutions. Concentration-dependent viscosity behaviors of mAbs and other biologic entities may depend on pairwise and higher-order intermolecular interactions, non-native aggregation, and concentration-dependent fluctuations of various antibody regions. This article reviews our current understanding of molecular origins of viscosity behaviors of antibody solutions. We discuss general strategies and guidelines to select low viscosity candidates or optimize lead candidates for lower viscosity at early drug discovery stages. Moreover, strategies for formulation optimization and excipient design are also presented for candidates already in advanced product development stages. Potential future directions for research in this field are also explored.

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“…The use of MALS and/or DLS, sometimes in conjunction with other methods of macromolecular characterization (e.g., CD, fluorescence or Raman spectroscopy, SAXS, SANS), to monitor the progress of irreversible aggregation following an initiating event provides information about the time evolution of aggregate size, which has been used to develop models for the mechanism of aggregate formation (see for example [21, 22]). Measurement of effective charge via ELS has also been found to correlate with the rate of irreversible aggregation of glycosylated and non-glycosylated Fc-1 antibody fragments [23]; the tendency to aggregate diminishes with increasing effective charge.…”

Section: Applicationsmentioning

confidence: 99%

Recent applications of light scattering measurement in the biological and biopharmaceutical sciences

Minton

2016

Analytical Biochemistry

105

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Aggregate structure, morphology and the effect of aggregation mechanisms on viscosity at elevated protein concentrations

Cited by 34 publications

References 57 publications

Parallel chromatography and in situ scattering to interrogate competing protein aggregation pathways

Parallel chromatography and in situ scattering to interrogate competing protein aggregation pathways

Molecular basis of high viscosity in concentrated antibody solutions: Strategies for high concentration drug product development

Recent applications of light scattering measurement in the biological and biopharmaceutical sciences

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