Skip to Main Content
 

Global Search Box

 
 
 
 

Files

File List


Final Dissertation.pdf (22.3 MB)

ETD Abstract Container

Abstract Header

Understanding Polyelectrolytes to Mimic Biological Structures

Kozawa, Susan Kurumi
http://orcid.org/0000-0002-6218-0903
http://rave.ohiolink.edu/etdc/view?acc_num=case159259695499193

Abstract Details

2020, Doctor of Philosophy, Case Western Reserve University, Macromolecular Science and Engineering.
This research aims to study the dynamics of charged ions moving through a charged system, and the interactions they have on each other. The underlying principles that govern the movement through a polyelectrolyte system can give insight into biological fibers such as actin, muscles and neurons. This investigation seeks to: developing an electrolyte-based system that exhibits movement, understanding the driving forces of movement from a macromolecular perspective, and developing an actuating system based on the parameters developed therefrom. Understanding fundamental polyelectrolyte behavior is the key to inducing physiological movement mimicking muscles and neurons. Previously, we have verified that poly(acrylate) gels exhibit electrical potentials in the range normally afforded by living cells. However, we have unexpectedly found that poly(acrylate) gels in aqueous solutions of monovalent salts such as KH2PO4 in a narrow concentration range (ca. 8-16 mM) leads to a softening of gels without measurable volume changes. The electrical potentials of the gels, using standard electrophysiological methods, show an abrupt increase in gel potential (to ca. -100 mV) with no appreciable macromolecular size change or mechanical transition, seen by elastic and compressive modulus. Magnetic resonance imaging experiments reveal a change in water mobility in the same transition region. Small angle neutron scattering also does not demonstrate a structural change in mesh size at this transition, suggesting a change is due to the cation and anion type and association with the chain. Through this, we predict the counterions have a larger factor in polyelectrolyte theory than previously known. By utilizing this transition region, we can induce facile movement through a polyelectrolyte gel with salt solutions and active movement with electrical current. Generating movement of the whole gel solely due to ion concentrations of mono- and divalent salt, ion interactions with the polymer, and ion interactions with itself lays the central foundation on which to build a model from. Based on our understanding of polyelectrolytes, we have found the optimal conditions to induce movement and a phase transition through the gel passively. Electrical stimulus is tuned to actively induce movement in physiological conditions.
Gary Wnek (Advisor)
Michael Hore (Committee Member)
Horst von Recum (Committee Member)
LaShanda Korley (Committee Member)
Svetlana Morozova (Committee Member)
141 p.
Polymers
Polyelectrolytes, Biomimicry

Recommended Citations

Citations

  • Kozawa, S. K. (2020). Understanding Polyelectrolytes to Mimic Biological Structures [Doctoral dissertation, Case Western Reserve University]. OhioLINK Electronic Theses and Dissertations Center. http://rave.ohiolink.edu/etdc/view?acc_num=case159259695499193

    APA Style (7th edition)

  • Kozawa, Susan. Understanding Polyelectrolytes to Mimic Biological Structures. 2020. Case Western Reserve University, Doctoral dissertation. OhioLINK Electronic Theses and Dissertations Center, http://rave.ohiolink.edu/etdc/view?acc_num=case159259695499193.

    MLA Style (8th edition)

  • Kozawa, Susan. "Understanding Polyelectrolytes to Mimic Biological Structures." Doctoral dissertation, Case Western Reserve University, 2020. http://rave.ohiolink.edu/etdc/view?acc_num=case159259695499193

    Chicago Manual of Style (17th edition)

case159259695499193
91
© 2020, all rights reserved.
This open access ETD is published by Case Western Reserve University School of Graduate Studies and OhioLINK.
Release 3.2.12