A stepwise mechanism for aqueous two-phase system formation in concentrated antibody solutions

Aqueous two-phase system (ATPS) formation is the macroscopic completion of liquid–liquid phase separation (LLPS), a process by which aqueous solutions demix into 2 distinct phases. We report the temperature-dependent kinetics of ATPS formation for solutions containing a monoclonal antibody and polye...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2019-08, Vol.116 (32), p.15784-15791
Main Authors: Rogers, Bradley A., Rembert, Kelvin B., Poyton, Matthew F., Okur, Halil I., Kale, Amanda R., Yang, Tinglu, Zhang, Jifeng, Cremer, Paul S.
Format: Article
Language:English
Subjects:
Activation energy
Antibodies, Monoclonal - analysis
Aqueous solutions
Binary systems
Coalescence
Coalescing
Colloids - chemistry
Droplets
Gelation
Kinetics
Liquid phases
Metastable region
Monoclonal antibodies
Phase diagrams
Phase separation
Physical Sciences
PNAS Plus
Polyethylene glycol
Proteins
Rate constants
Scattering, Radiation
Solutions
Temperature
Temperature dependence
Temperature effects
Temperature gradients
Time Factors
Time-Lapse Imaging
Water - chemistry
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Summary:Aqueous two-phase system (ATPS) formation is the macroscopic completion of liquid–liquid phase separation (LLPS), a process by which aqueous solutions demix into 2 distinct phases. We report the temperature-dependent kinetics of ATPS formation for solutions containing a monoclonal antibody and polyethylene glycol. Measurements are made by capturing dark-field images of protein-rich droplet suspensions as a function of time along a linear temperature gradient. The rate constants for ATPS formation fall into 3 kinetically distinct categories that are directly visualized along the temperature gradient. In the metastable region, just below the phase separation temperature, Tph, ATPS formation is slow and has a large negative apparent activation energy. By contrast, ATPS formation proceeds more rapidly in the spinodal region, below the metastable temperature, Tmeta, and a small positive apparent activation energy is observed. These region-specific apparent activation energies suggest that ATPS formation involves 2 steps with opposite temperature dependencies. Droplet growth is the first step, which accelerates with decreasing temperature as the solution becomes increasingly supersaturated. The second step, however, involves droplet coalescence and is proportional to temperature. It becomes the rate-limiting step in the spinodal region. At even colder temperatures, below a gelation temperature, Tgel, the proteins assemble into a kinetically trapped gel state that arrests ATPS formation. The kinetics of ATPS formation near Tgel is associated with a remarkably fragile solidlike gel structure, which can form below either the metastable or the spinodal region of the phase diagram.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1900886116