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| Format: | Preprint |
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2024
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| Online-Zugang: | https://arxiv.org/abs/2412.09821 |
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| _version_ | 1866913609912680448 |
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| author | Bal, Vivekananda Hong, Moo Sun Wolfrum, Jacqueline M. Barone, Paul W. Springs, Stacy L. Sinskey, Anthony J. Kotin, Robert M. Braatz, Richard D. |
| author_facet | Bal, Vivekananda Hong, Moo Sun Wolfrum, Jacqueline M. Barone, Paul W. Springs, Stacy L. Sinskey, Anthony J. Kotin, Robert M. Braatz, Richard D. |
| contents | Crystallization of proteins, specifically proteins of medical relevance, is performed for various reasons such as to understand the protein structure and to design therapies. Obtaining kinetic constants in rate laws for nucleation and growth of advanced biotherapeutics such as capsids, an assembly of macromolecules, is challenging and essential to the design of the crystallization processes. In this work, coupled population balance and species balance equations are developed to extract nucleation and growth kinetics for crystallization of recombinant adeno-associated virus (rAAV) capsids. A comparison of model results with that of experimental data for capsid crystallization in hanging-drop vapor diffusion system shows that slow rate of vapor diffusion from the droplet controls the initial nucleation and growth processes, and the capsid nucleation occurs via heterogeneous nucleation in the microdroplet. Results also show that the capsids, which are of very high molecular weight (~3.6 MDa), have a similar tendency to nucleate as small organic molecules such as glycine (75 Da), low-molecular-weight proteins, and small-molecule active pharmaceutical ingredients due to its ball-shaped outer structure/shape. Capids also show a prolonged nucleation period as for proteins and other macromolecules, but has a slow growth rate with a growth rate pre-factor seven orders of magnitude smaller than that of lysozyme. The capsid crystal growth rate is weakly sensitive to the supersaturation compared to lysozyme and is limited by the transport of capsids due to slow Brownian motion resulting from the very high molecular weight. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2412_09821 |
| institution | arXiv |
| publishDate | 2024 |
| record_format | arxiv |
| spellingShingle | An Integrated Experimental and Modeling Approach for Crystallization of Complex Biotherapeutics Bal, Vivekananda Hong, Moo Sun Wolfrum, Jacqueline M. Barone, Paul W. Springs, Stacy L. Sinskey, Anthony J. Kotin, Robert M. Braatz, Richard D. Applied Physics Crystallization of proteins, specifically proteins of medical relevance, is performed for various reasons such as to understand the protein structure and to design therapies. Obtaining kinetic constants in rate laws for nucleation and growth of advanced biotherapeutics such as capsids, an assembly of macromolecules, is challenging and essential to the design of the crystallization processes. In this work, coupled population balance and species balance equations are developed to extract nucleation and growth kinetics for crystallization of recombinant adeno-associated virus (rAAV) capsids. A comparison of model results with that of experimental data for capsid crystallization in hanging-drop vapor diffusion system shows that slow rate of vapor diffusion from the droplet controls the initial nucleation and growth processes, and the capsid nucleation occurs via heterogeneous nucleation in the microdroplet. Results also show that the capsids, which are of very high molecular weight (~3.6 MDa), have a similar tendency to nucleate as small organic molecules such as glycine (75 Da), low-molecular-weight proteins, and small-molecule active pharmaceutical ingredients due to its ball-shaped outer structure/shape. Capids also show a prolonged nucleation period as for proteins and other macromolecules, but has a slow growth rate with a growth rate pre-factor seven orders of magnitude smaller than that of lysozyme. The capsid crystal growth rate is weakly sensitive to the supersaturation compared to lysozyme and is limited by the transport of capsids due to slow Brownian motion resulting from the very high molecular weight. |
| title | An Integrated Experimental and Modeling Approach for Crystallization of Complex Biotherapeutics |
| topic | Applied Physics |
| url | https://arxiv.org/abs/2412.09821 |