A Rheological Study of the Association and Dynamics of MUC5AC Gels

The details of how a mucus hydrogel forms from its primary structural component, mucin polymers, remain incompletely resolved. To explore this, we use a combination of macrorheology and single-particle tracking to investigate the bulk and microscopic mechanical properties of reconstituted MUC5AC muc...

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Published in	Biomacromolecules Vol. 18; no. 11; pp. 3654 - 3664
Main Authors	Wagner, Caroline E, Turner, Bradley S, Rubinstein, Michael, McKinley, Gareth H, Ribbeck, Katharina
Format	Journal Article
Language	English
Published	United States American Chemical Society 13.11.2017
Subjects	Animals Hydrogels - chemistry Hydrogen-Ion Concentration Mucin 5AC - chemistry Mucin 5AC - genetics Particle Size Polymers - chemistry Rheology Salts - chemistry Surface-Active Agents - chemistry Swine Viscosity
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Abstract	The details of how a mucus hydrogel forms from its primary structural component, mucin polymers, remain incompletely resolved. To explore this, we use a combination of macrorheology and single-particle tracking to investigate the bulk and microscopic mechanical properties of reconstituted MUC5AC mucin gels. We find that analyses of thermal fluctuations on the length scale of the micrometer-sized particles are not predictive of the linear viscoelastic response of the mucin gels, and that taken together, the results from both techniques help to provide complementary insight into the structure of the network. In particular, we show that macroscopic stiffening of MUC5AC gels can be brought about in different ways by targeting specific associations within the network using environmental triggers such as modifications to the pH, surfactant, and salt concentration. Our work may be important for understanding how environmental factors, including pathogens and therapeutic agents, alter the mechanical properties of fully constituted mucus.
AbstractList	The details of how a mucus hydrogel forms from its primary structural component, mucin polymers, remain incompletely resolved. To explore this, we use a combination of macrorheology and single-particle tracking to investigate the bulk and microscopic mechanical properties of reconstituted MUC5AC mucin gels. We find that analyses of thermal fluctuations on the length scale of the micrometer-sized particles are not predictive of the linear viscoelastic response of the mucin gels, and that taken together, the results from both techniques help to provide complementary insight into the structure of the network. In particular, we show that macroscopic stiffening of MUC5AC gels can be brought about in different ways by targeting specific associations within the network using environmental triggers such as modifications to the pH, surfactant, and salt concentration. Our work may be important for understanding how environmental factors, including pathogens and therapeutic agents, alter the mechanical properties of fully constituted mucus. The details of how the mucus hydrogel forms from its primary structural component, mucin polymers, remain incompletely resolved. To explore this, we use a combination of macrorheology and single particle tracking to investigate the bulk and microscopic mechanical properties of reconstituted MUC5AC mucin gels. We find that analyses of thermal fluctuations on the length scale of the micronsized particles are not predictive of the linear viscoelastic response of the mucin gels, and that taken together, the results from both techniques help to provide complementary insight into the structure of the network. In particular, we show that macroscopic stiffening of MUC5AC gels can be brought about in different ways by targeting specific associations within the network using environmental triggers such as modifications to the pH, surfactant, and salt concentration. Our work may be important for understanding how environmental factors, including pathogens and therapeutic agents, alter the mechanical properties of fully-constituted mucus.
Author	Rubinstein, Michael Wagner, Caroline E Turner, Bradley S McKinley, Gareth H Ribbeck, Katharina
AuthorAffiliation	Department of Chemistry Massachusetts Institute of Technology Department of Mechanical Engineering University of North Carolina Department of Biological Engineering
AuthorAffiliation_xml	– name: University of North Carolina – name: – name: Department of Mechanical Engineering – name: Department of Chemistry – name: Massachusetts Institute of Technology – name: Department of Biological Engineering – name: 1 Department of Mechanical Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139 – name: 3 Department of Chemistry, University of North Carolina, Chapel Hill, North Carolina 27599-3290 – name: 2 Department of Biological Engineering, Massachusetts Institute of Technology, Cambridge, MA 02139
Author_xml	– sequence: 1 givenname: Caroline E orcidid: 0000-0001-5193-2797 surname: Wagner fullname: Wagner, Caroline E – sequence: 2 givenname: Bradley S surname: Turner fullname: Turner, Bradley S – sequence: 3 givenname: Michael surname: Rubinstein fullname: Rubinstein, Michael organization: University of North Carolina – sequence: 4 givenname: Gareth H surname: McKinley fullname: McKinley, Gareth H – sequence: 5 givenname: Katharina orcidid: 0000-0001-8260-338X surname: Ribbeck fullname: Ribbeck, Katharina email: ribbeck@mit.edu
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Snippet	The details of how a mucus hydrogel forms from its primary structural component, mucin polymers, remain incompletely resolved. To explore this, we use a... The details of how the mucus hydrogel forms from its primary structural component, mucin polymers, remain incompletely resolved. To explore this, we use a...
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SubjectTerms	Animals Hydrogels - chemistry Hydrogen-Ion Concentration Mucin 5AC - chemistry Mucin 5AC - genetics Particle Size Polymers - chemistry Rheology Salts - chemistry Surface-Active Agents - chemistry Swine Viscosity
Title	A Rheological Study of the Association and Dynamics of MUC5AC Gels
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