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Your search keyword '"Crowell, Anne D."' showing total 9 results
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9 results on '"Crowell, Anne D."'

1. Morphological Control of Bundled Actin Networks Subject to Fixed-Mass Depletion

Author

Clarke, James, Melcher, Lauren, Crowell, Anne D., Cavanna, Francis, Houser, Justin R., Graham, Kristin, Green, Allison, Stachowiak, Jeanne C., Truskett, Thomas M., Milliron, Delia J., Rosales, Adrianne M., Das, Moumita, and Alvarado, José

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

Depletion interactions are thought to significantly contribute to the organization of intracellular structures in the crowded cytosol. The strength of depletion interactions depends on physical parameters like the depletant number density and the depletant size ratio. Cells are known to dynamically regulate these two parameters by varying the copy number of proteins of a wide distribution of sizes. However, mammalian cells are also known to keep the total protein mass density remarkably constant, to within 0.5% throughout the cell cycle. We thus ask how the strength of depletion interactions varies when the total depletant mass is held fixed, a.k.a. fixed-mass depletion. We answer this question via scaling arguments, as well as by studying depletion effects on networks of reconstituted semiflexible actin $\textit{in silico}$ and $\textit{in vitro}$. We examine the maximum strength of the depletion interaction potential $U^*$ as a function of $q$, the size ratio between the depletant and the matter being depleted. We uncover a scaling relation $U^* \sim q^{-\zeta}$ for two cases: fixed volume fraction $\phi$ and fixed mass density $\rho$. For fixed volume fraction, we report $\zeta < 0$. For the fixed mass density case, we report $\zeta > 0$, which suggests the depletion interaction strength increases as the depletant size ratio is increased. To test this prediction, we prepared our filament networks at fixed mass concentrations with varying sizes of the depletant molecule poly(ethylene glycol) (PEG). We characterize the depletion interaction strength in our simulations via the mesh size. In experiments, we observe two distinct actin network morphologies, which we call weakly bundled and strongly bundled. We identify a mass concentration where different PEG depletant sizes leads to weakly bundled or strongly bundled morphologies...[more in main text]., Comment: 21 pages, 5 figures. arXiv admin note: substantial text overlap with arXiv:2205.01864

Published
2023

2. Depletion-Driven Morphological Control of Bundled Actin Networks

Author

Clarke, James, Cavanna, Francis, Crowell, Anne D., Melcher, Lauren, Houser, Justin R., Graham, Kristin, Green, Allison, Stachowiak, Jeanne C., Truskett, Thomas M., Milliron, Delia J., Rosales, Adrianne M., Das, Moumita, and Alvarado, José

Subjects
Condensed Matter - Soft Condensed Matter, Physics - Biological Physics
Abstract

The actin cytoskeleton is a semiflexible biopolymer network whose morphology is controlled by a wide range of biochemical and physical factors. Actin is known to undergo a phase transition from a single-filament state to a bundled state by the addition of polyethylene glycol (PEG) molecules in sufficient concentration. While the depletion interaction experienced by these biopolymers is well-known, the effect of changing the molecular weight of the depletant is less well understood. Here, we experimentally identify a phase transition in solutions of actin from networks of filaments to networks of bundles by varying the molecular weight of PEG polymers, while holding the concentration of these PEG polymers constant. We examine the states straddling the phase transition in terms of micro and macroscale properties. We find that the mesh size, bundle diameter, persistence length, and intra-bundle spacing between filaments across the line of criticality do not show significant differences, while the relaxation time, storage modulus, and degree of bundling change between the two states do show significant differences. Our results demonstrate the ability to tune actin network morphology and mechanics by controlling depletant size, a property which could be exploited to develop actin-based materials with switchable rigidity., Comment: 22 pages, 10 figures. Authors James Clarke and Francis Cavanna contributed equally; Changes: Added modeling work, extended dynamic light scattering analysis

Published
2022

3. Morphological control of bundled actin networks subject to fixed-mass depletion.

Author

Clarke, James, Melcher, Lauren, Crowell, Anne D., Cavanna, Francis, Houser, Justin R., Graham, Kristin, Green, Allison M., Stachowiak, Jeanne C., Truskett, Thomas M., Milliron, Delia J., Rosales, Adrianne M., Das, Moumita, and Alvarado, José

Subjects
MOLECULAR size, ETHYLENE glycol, LIGHT scattering, CELL cycle, ACTIN
Abstract

Depletion interactions are thought to significantly contribute to the organization of intracellular structures in the crowded cytosol. The strength of depletion interactions depends on physical parameters such as the depletant number density and the depletant size ratio. Cells are known to dynamically regulate these two parameters by varying the copy number of proteins of a wide distribution of sizes. However, mammalian cells are also known to keep the total protein mass density remarkably constant, to within 0.5% throughout the cell cycle. We thus ask how the strength of depletion interactions varies when the total depletant mass is held fixed, a.k.a. fixed-mass depletion. We answer this question via scaling arguments, as well as by studying depletion effects on networks of reconstituted semiflexible actin in silico and in vitro. We examine the maximum strength of the depletion interaction potential U as a function of q, the size ratio between the depletant and the matter being depleted. We uncover a scaling relation U ∼ qζ for two cases: fixed volume fraction φ and fixed mass density ρ. For fixed volume fraction, we report ζ < 0. For the fixed mass density case, we report ζ > 0, which suggests that the depletion interaction strength increases as the depletant size ratio is increased. To test this prediction, we prepared our filament networks at fixed mass concentrations with varying sizes of the depletant molecule poly(ethylene glycol) (PEG). We characterize the depletion interaction strength in our simulations via the mesh size. In experiments, we observe two distinct actin network morphologies, which we call weakly bundled and strongly bundled. We identify a mass concentration where different PEG depletant sizes lead to weakly bundled or strongly bundled morphologies. For these conditions, we find that the mesh size and intra-bundle spacing between filaments across the different morphologies do not show significant differences, while the dynamic light scattering relaxation time and storage modulus between the two states do show significant differences. Our results demonstrate the ability to tune actin network morphology and mechanics by controlling depletant size and give insights into depletion interaction mechanisms under the fixed-depletant-mass constraint relevant to living cells. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Biodegradable microneedle patch for delivery of meloxicam for managing pain in cattle

Author

Castilla-Casadiego, David A., primary, Miranda-Muñoz, Katherine A., additional, Roberts, Jesse L., additional, Crowell, Anne D., additional, Gonzalez-Nino, David, additional, Choudhury, Dipankar, additional, Aparicio-Solis, Frank O., additional, Servoss, Shannon L., additional, Rosales, Adrianne M., additional, Prinz, Gary, additional, Zou, Min, additional, Zhang, Yuntao, additional, Coetzee, Johann F., additional, Greenlee, Lauren F., additional, Powell, Jeremy, additional, and Almodovar, Jorge, additional

Published
2022
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8. Using Inquiry Based Simulations in the Honors Science Laboratory

Author

Crowell, Anne D and Geller, Harold

Subjects
PHET, simulations, physics, chemistry, inquiry-based learning, liberal arts, creative problem solving, honors, Liberal arts education, Computer science, media_common.quotation_subject, Energy (esotericism), Physics education, Creativity, Educational research, Creative problem-solving, ComputingMilieux_COMPUTERSANDEDUCATION, Mathematics education, Natural (music), Inquiry-based learning, media_common
Abstract

The project known as PhET, originally stood for Physics Education Technology, but was quickly expanded into the other natural sciences. It is a project which, with a grant from the NSF and other sponsors, now provides free inquiry- based simulations in the natural sciences and mathematics. The project was founded by Nobel Prize winner Carl Wieman. The simulations are highly interactive, easy to use, and based on the latest educational research. The GMU Honors College teaches several science courses geared to high achieving liberal arts students. The courses cover a wide range of topics that include astrobiology, energy/environmental issues, and scientific thought and processes. Despite their high ability and motivation, these students often report a reluctance to engage in scientific inquiry.  PhET simulations were used as laboratory experiments to teach basic concepts in physics and chemistry. Students display high engagement and interest utilizing PhET simulations. Students also were able to demonstrate creativity in problem solving, and a reduced fear of making mistakes.  The PhET computer simulations allowed students to quickly identify cause and effect relationships between simulation inputs and outputs., Innovations in Teaching & Learning Conference Proceedings, Vol 8 (2016): Cultivating Creative and Reflective Learners

Published
2016
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