Synthesis and study of crystalline hydrogels, guided by a phase diagram. Metadata

Title

• Main Title Synthesis and study of crystalline hydrogels, guided by a phase diagram.

Creator

• Author: Huang, Gang
  Creator Type: Personal

Contributor

• Chair: Hu, Zhibing
  Contributor Type: Personal
  Contributor Info: Major Professor
• Committee Member: Marshall, Paul, 1960-
  Contributor Type: Personal
• Committee Member: Wilson, Angela K.
  Contributor Type: Personal
• Committee Member: Golden, Teresa D.
  Contributor Type: Personal
• Committee Member: Gnade, Bruce
  Contributor Type: Personal

Publisher

• Name: University of North Texas
  Place of Publication: Denton, Texas

Date

• Creation: 2004-12
• Digitized: 2007-12-06

Language

• English

Description

• Content Description: Monodispersed nanoparticles of poly-N-isopropylacrylamide-co-allylamine (PNIPAM-co-allylamine) and PNIPAM-co-acrylic acid (AA) have been synthesized and used as building blocks for creating three-dimensional networks. The close-packed PNIPAM-co-allylamine and PNIPAM-co-AA nanoparticles were stabilized by covalently bonding neighboring particles at room temperature and at neutral pH; factors which make these networks amicable for drug loading and release. Controlled release studies have been performed on the networks using dextran markers of various molecular weights as model macromolecular drugs. Drug release was quantified under various physical conditions including a range of temperature and molecular weight. These nanoparticle networks have several advantages over the conventional bulk gels for controlling the release of biomolecules with large molecular weights. Monodispersed nanoparticles of poly-N-isopropylacrylamide-co-allylamine (PNIPAM-co-allylamine) can self-assemble into crystals with a lattice spacing on the order of the wavelength of visible light. By initiating the crystallization process near the colloidal crystal melting temperature, while subsequently bonding the PNIPAM-co-allylamine particles below the glass transition temperature, a nanostructured hydrogel has been created. The crystalline hydrogels exhibit iridescent patterns that are tunable by the change of temperature, pH value or even protein concentration. This kind of soft and wet hydrogel with periodic structures may lead to new sensors, devices, and displays operating in aqueous solutions, where most biological and biomedical systems reside. The volume-transition equilibrium and the interaction potential between neutral PINPAM particles dispersed in pure water were investigated by using static and dynamic light-scattering experiments. From the temperature-dependent size and energy parameters, the Sutherland-like potential provides a reasonable representation of the inter-particle potential for PNIPAM particles in swollen and in collapsed phases. An aqueous dispersion of PNIPAM particles can freeze at both high and low temperatures. At low temperatures, the freezing occurs at a large particle volume fraction, similar to that in a hard-sphere system; while at high temperature, the freezing occurs at low particle concentrations, driven by the strong van der Waals attraction due to the collapsed microgel particles. The calculated phase diagram has been confirmed semi-quantitatively by experiments.

Subject

• Library of Congress Subject Headings: Colloids.
• Library of Congress Subject Headings: Crystallization.
• Keyword: microgel
• Keyword: light scattering
• Keyword: controlled release
• Keyword: PNIPAM-co-allylamine

Collection

• Name: UNT Theses and Dissertations
  Code: UNTETD

Institution

• Name: UNT Libraries
  Code: UNT

Rights

• Rights Access: public
• Rights License: copyright
• Rights Holder: Huang, Gang
• Rights Statement: Copyright is held by the author, unless otherwise noted. All rights reserved.

Resource Type

• Thesis or Dissertation

Format

• Text

Identifier

• OCLC: 58553965
• Archival Resource Key: ark:/67531/metadc4698

Degree

• Degree Name: Doctor of Philosophy
• Degree Level: Doctoral
• Degree Discipline: Analytical Chemistry
• Academic Department: Department of Chemistry
• Degree Grantor: University of North Texas

Note