| scholarly article | Q13442814 |
| P50 | author | Joop H. ter Horst | Q57617998 |
| P2093 | author name string | Efrem Curcio | |
| Gianluca Di Profio | |||
| Teresa F Mastropietro | |||
| Elvira Pantuso | |||
| Maria L Briuglia | |||
| Charline J J Gerard | |||
| Fiore P Nicoletta | |||
| P2860 | cites work | Predicting protein crystallization from a dilute solution property | Q47985162 |
| Analytical similarity assessment of rituximab biosimilar CT-P10 to reference medicinal product. | Q50146186 | ||
| High concentration formulations of recombinant human interleukin-1 receptor antagonist: I. Physical characterization. | Q50873904 | ||
| Thermodynamic analysis of osmolyte effect on thermal stability of ribonuclease A in terms of water activity. | Q51137253 | ||
| Factors affecting the viscosity in high concentration solutions of different monoclonal antibodies. | Q51663592 | ||
| Osmotic Virial Coefficients as Access to the Protein Partitioning in Aqueous Two-Phase Systems. | Q51822471 | ||
| Mechanism of poly(ethylene glycol) interaction with proteins. | Q54181460 | ||
| Enhancement of Protein Crystal Nucleation by Critical Density Fluctuations | Q56932074 | ||
| Specific Ion and Buffer Effects on Protein–Protein Interactions of a Monoclonal Antibody | Q57362747 | ||
| Sensitivity of circular dichroism to protein tertiary structure class | Q59096620 | ||
| Magic number colloidal clusters as minimum free energy structures | Q59789931 | ||
| A mechanism for reversible mesoscopic aggregation in liquid solutions. | Q64977844 | ||
| Polymer-induced entropic depletion potential | Q83020291 | ||
| Interactions and phase behavior of a monoclonal antibody | Q83396585 | ||
| Protein structural conformation and not second virial coefficient relates to long-term irreversible aggregation of a monoclonal antibody and ovalbumin in solution | Q83821273 | ||
| Crystallization and liquid-liquid phase separation of monoclonal antibodies and fc-fusion proteins: screening results | Q84313399 | ||
| Long- and short-range electrostatic interactions affect the rheology of highly concentrated antibody solutions | Q84609560 | ||
| Behavior of monoclonal antibodies: relation between the second virial coefficient (B (2)) at low concentrations and aggregation propensity and viscosity at high concentrations | Q84792220 | ||
| Influence of macromolecular precipitants on phase behavior of monoclonal antibodies | Q86279213 | ||
| Origin of Aggregate Formation in Antibody Crystal Suspensions Containing PEG | Q87310645 | ||
| Crystalline monoclonal antibodies for subcutaneous delivery | Q30478345 | ||
| Tapping the Protein Data Bank for crystallization information | Q33227610 | ||
| Protein-protein interactions in dilute to concentrated solutions: α-chymotrypsinogen in acidic conditions | Q33732547 | ||
| Molecular origins of osmotic second virial coefficients of proteins | Q34169400 | ||
| Protein interactions in solution characterized by light and neutron scattering: comparison of lysozyme and chymotrypsinogen | Q34169496 | ||
| Liquid-liquid phase separation in hemoglobins: distinct aggregation mechanisms of the beta6 mutants | Q34185062 | ||
| Physical stability of proteins in aqueous solution: mechanism and driving forces in nonnative protein aggregation | Q35563682 | ||
| Optimization of crystal nucleation close to a metastable fluid-fluid phase transition | Q35764677 | ||
| Protein aggregation and bioprocessing | Q36616347 | ||
| Future of antibody purification | Q36668477 | ||
| Alternatives to chromatographic separations | Q36725108 | ||
| Protein aggregation: pathways, induction factors and analysis | Q37281536 | ||
| Aqueous two-phase systems for protein separation: a perspective | Q37900716 | ||
| Aqueous two-phase systems for protein separation: phase separation and applications | Q38001814 | ||
| Making sense of Brownian motion: colloid characterization by dynamic light scattering | Q38232624 | ||
| Renaissance of protein crystallization and precipitation in biopharmaceuticals purification. | Q39026374 | ||
| Solubilization of proteins in aqueous two-phase extraction through combinations of phase-formers and displacement agents | Q39171728 | ||
| Predicting solution aggregation rates for therapeutic proteins: approaches and challenges | Q39760066 | ||
| Elucidating the Weak Protein-Protein Interaction Mechanisms behind the Liquid-Liquid Phase Separation of a mAb Solution by Different Types of Additives | Q40115249 | ||
| The second virial coefficient as a predictor of protein aggregation propensity: A self-interaction chromatography study | Q40640354 | ||
| Inclusion of mPRISM potential for polymer-induced protein interactions enables modeling of second osmotic virial coefficients in aqueous polymer-salt solutions | Q40650445 | ||
| The concentration-dependence of macromolecular parameters | Q41971526 | ||
| Phase behavior of an intact monoclonal antibody | Q42107398 | ||
| Challenges in Predicting Protein-Protein Interactions from Measurements of Molecular Diffusivity | Q42693191 | ||
| Protein-protein association in polymer solutions: from dilute to semidilute to concentrated | Q42826492 | ||
| Effects of ammonium sulfate and sodium chloride concentration on PEG/protein liquid-liquid phase separation | Q47399904 | ||
| Catching the PEG-induced attractive interaction between proteins. | Q47975543 | ||
| P433 | issue | 1 | |
| P304 | page(s) | 8902 | |
| P577 | publication date | 2020-06-01 | |
| P1433 | published in | Scientific Reports | Q2261792 |
| P1476 | title | On the Aggregation and Nucleation Mechanism of the Monoclonal Antibody Anti-CD20 Near Liquid-Liquid Phase Separation (LLPS) | |
| P478 | volume | 10 |
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