Design, synthesis and characterization of polymeric nanostructures for protein sensing and delivery

Gonzalez-Toro, Daniella Cristina

01 January 2013

Increasing motivation for the development of nanotechnology with applications in sensing, nanotheranostics, combinatorial therapy and drug/protein delivery have brought a broad spectrum of multifunctional polymeric materials. With interest in obtaining more efficient methods for fast and accurate diagnostics, nanostructures able to rapidly obtain large sets of data for analyte sensing are necessary. Likewise, interests in, not only obtaining accurate diagnostics, but also being able to concurrently and accurately provide therapy has inspired us to develop such technologies. We particularly focus on understanding the assembly and disassembly processes of polymeric nanostructures in response to biologically relevant stimuli. We are interested in mimicking natural sensing events and take advantage of the differential binding affinity of a set of receptors to generate analyte-specific patterns to use as sensors. Receptors developed in our laboratories have demonstrated impressive recognition capabilities for proteins. When a set of polyelectrolytes and surfactants with different hydrophobic and electronic properties, as well as the guest molecule (transducer) with different characteristics, are combined, fluorescence patterns for proteins can be generated. Creating patterns using protein-induced disassembly not only provides the opportunity to have a new method for sensing analytes that are not electronically complementary to the fluorescent transducers, but also reduces the synthetic complexity even further, since these are assembled from its components noncovalently. A versatile and efficient delivery vehicle should have a tunable particle size, provide protection and stability to the cargo to prevent premature release before approaching the target site and should provide ease of cargo incorporation strategies. This ease of incorporation becomes more challenging when we are talking about incorporating molecules with different characteristics. Here we demostrate the versatility of self-crosslinked polymeric nanogels on the incorporation of lipophilic small molecules on its interior and hydrophilic proteins at the surface. Also, different approaches of protein incorporation can be obtained using these polymeric nanogels, which provide differences in protein release and cell internalization. These technologies were found to be potential candidates for applications such as nanotheranostics, combinatorial therapy and protein delivery.

Design and synthesis of a new class of self-cross-linked polymer nanogels

Jiwpanich, Siriporn

01 January 2011

The design and engineering of nanoscopic drug delivery vehicles that stably encapsulate lipophilic drug molecules, transport their loaded cargo to specific target sites, and release their payload in a controlled manner are of great interest in therapeutic applications, especially for cancer chemotherapy. This dissertation focuses on chemically cross-linked, water-soluble polymer nanoparticles, termed nanogels, which constitute a promising scaffold and offer the potential to circumvent encapsulation stability issues. A facile synthetic method for a new class of self-cross-linked polymer nanogels, synthesized by an intra/intermolecular disulfide cross-linking reaction in aqueous media, is described here. This simple emulsion-free method affords noncovalent lipophilic guest encapsulation and surface functionalization that may allow for targeted delivery. The encapsulation stability of lipophilic molecules sequestered within these nanoscopic containers is evaluated by a fluorescent resonance energy transfer (FRET) based method developed by our research group. We demonstrate that the encapsulation stability of noncovalently encapsulated guest molecules in disulfide cross-linked polymer nanogels can be tuned and that guest release can be achieved in response to a biologically relevant stimulus (GSH). In addition, varied hydrophobicity in the self-cross-linked nanogels affects the lipophilic loading capacity and encapsulation stability. We reveal that optimal loading capacity is limited by encapsulation stability, where over-loading of lipophilic molecules in the nanoscopic containers may cause undesirable leakage and severely compromise the viability of such systems for drug delivery and other biological applications.

Discrete, one-, two-, and three-dimensional copper(I) coordination networks towards the rational design of extended solids /

Lopez, Susan,

January 2000

Thesis (Ph. D.)--University of Missouri-Columbia, 2000. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.

Discrete, one-, two-, and three-dimensional copper(I) coordination networks : towards the rational design of extended solids /

Lopez, Susan,

January 2000

Thesis (Ph. D.)--University of Missouri-Columbia, 2000. / Typescript. Vita. Includes bibliographical references. Also available on the Internet.

Magnetic and Structural Investigation of Manganese Doped SnO_2 and In_2 O_3 Nanocrystals

Sabergharesou, Tahereh

January 2013

Diluted magnetic semiconductor oxides (DMSOs) have received great attention recently due to their outstanding applications in optoelectronic and spintronic devices. Ever since the initial observation of ferromagnetism at room temperature in cobalt-doped titania, extensive effort is concentrated on preparation of transition metal doped wide band gap semiconductors, especially Mn- doped ZnO. Compared to Mn-doped ZnO, magnetic interactions in SnO! and In!O! semiconductors have been underexplored. SnO! and In!O! semiconductors have many applications, owing to their high charge carrier density and mobility as well as high optical transparency. Investigation on electronic structure changes induced by dopants during the synthesis procedure can effectively influence magnetic interactions between charge carriers. In this work, a combination of structural and spectroscopic methods was used to probe as-synthesized SnO! and In!O! nanocrystals doped with Mn!! and Mn!! as precursors. X-ray absorption near edge structure (XANES) and extended X-ray absorption fine structure (EXAFS) spectroscopy are powerful techniques to explore formal oxidation state of manganese dopant, electronic environment, number of nearest neighbors around the absorbent, and bond lengths to the neighboring atoms. Analysis reveals the presence of multiple oxidation states in the doped nanocrystals, and establishes a relation between !"!! ratio and expansion or contraction of lattice parameters. !"!! Although doping semiconductors are crucial for manipulating the functional properties, the influence of dopants on nanocrystals structure is not well understood. Nanocrystalline films prepared from colloidal Mn-doped SnO! and In!O! nanocrystals through spin coating process exhibit ferromagnetic behavior in temperatures ranging from 5 K to 300 K. Magnetic transformation from paramagnetic in free-standing Mn-doped nanocrystals to strong ferromagnetic ordering in nanocrystalline films is attributed to the formation of extended structural defects, e.g., oxygen vacancies at the nanocrystals interface. Magnetic circular dichroism (MCD) studies clearly show that Mn!! occupies different symmetry sites in indium oxide, when bixbyite and rhombohedral In!O! nanocrystals (NCs) are compared.

X-ray Absorption Spectroscopy (XAS)

Mn-doped SnO2 and In2O3

Chemistry (Nanotechnology)

Magnetic and Structural Investigation of Manganese Doped SnO_2 and In_2 O_3 Nanocrystals

Sabergharesou, Tahereh

January 2013

Diluted magnetic semiconductor oxides (DMSOs) have received great attention recently due to their outstanding applications in optoelectronic and spintronic devices. Ever since the initial observation of ferromagnetism at room temperature in cobalt-doped titania, extensive effort is concentrated on preparation of transition metal doped wide band gap semiconductors, especially Mn- doped ZnO. Compared to Mn-doped ZnO, magnetic interactions in SnO! and In!O! semiconductors have been underexplored. SnO! and In!O! semiconductors have many applications, owing to their high charge carrier density and mobility as well as high optical transparency. Investigation on electronic structure changes induced by dopants during the synthesis procedure can effectively influence magnetic interactions between charge carriers. In this work, a combination of structural and spectroscopic methods was used to probe as-synthesized SnO! and In!O! nanocrystals doped with Mn!! and Mn!! as precursors. X-ray absorption near edge structure (XANES) and extended X-ray absorption fine structure (EXAFS) spectroscopy are powerful techniques to explore formal oxidation state of manganese dopant, electronic environment, number of nearest neighbors around the absorbent, and bond lengths to the neighboring atoms. Analysis reveals the presence of multiple oxidation states in the doped nanocrystals, and establishes a relation between !"!! ratio and expansion or contraction of lattice parameters. !"!! Although doping semiconductors are crucial for manipulating the functional properties, the influence of dopants on nanocrystals structure is not well understood. Nanocrystalline films prepared from colloidal Mn-doped SnO! and In!O! nanocrystals through spin coating process exhibit ferromagnetic behavior in temperatures ranging from 5 K to 300 K. Magnetic transformation from paramagnetic in free-standing Mn-doped nanocrystals to strong ferromagnetic ordering in nanocrystalline films is attributed to the formation of extended structural defects, e.g., oxygen vacancies at the nanocrystals interface. Magnetic circular dichroism (MCD) studies clearly show that Mn!! occupies different symmetry sites in indium oxide, when bixbyite and rhombohedral In!O! nanocrystals (NCs) are compared.

X-ray Absorption Spectroscopy (XAS)

Mn-doped SnO2 and In2O3

Chemistry (Nanotechnology)