The Effects of Acid-Base Parameters, Oxygen and Heparin on the Ability to Detect Changes in the Blood Status of End-Stage Renal Disease Patients Undergoing Hemodialysis Using Whole Blood-Based Optical Spectroscopy

Atanya, Monica

18 April 2011

Relative changes are detectable in the blood of end-stage renal disease (ESRD) patients during hemodialysis (HD) treatment using optical spectroscopy. However, the potential impacts of several confounding factors that could affect the detection of these changes have not been evaluated. The objectives of this thesis were to: 1) investigate how the variations and/or changes in acid-base and oxygen parameters during HD treatment can affect the optical signature of whole blood of ESRD patients, 2) to investigate the effect of heparin on the optical properties of whole blood and its impact on our method. Blood samples were drawn from 23 ESRD patients at 5 time points during a 4 hour HD treatment and sent for blood gas and blood spectroscopy analyses. No significant correlations were found between the changes in the blood transmittance spectra and acid-base and oxygen parameters. This indicates that the perturbations in these parameters due to HD procedures do not confound the detection of changes in the blood transmittance spectra of ESRD patients during HD treatment. Additionally, the effect of heparin in modifying the optical properties of whole blood does not confound the detection of changes in the blood of ESRD patients due to HD treatment using whole blood-based optical spectroscopy. ANOVA revealed significant (P<0.05) measurable changes in the blood transmittance spectra of ESRD patients during HD treatment. Significant spectral differences (P<0.05) were found between ESRD patients. The lack of uniform spectral characteristics across patients is

Chronic kidney disease

End-stage renal disease

Hemodialysis

Acid-base

Oxygenation

Heparin

Optical spectroscopy

Biomolecule Functionalization of Diamond Surfaces for Implant Applications - A Theoretical Study

Tian, Yuan

January 2015

Diamond is a promising material with unique chemical properties. In this thesis, nano-scale diamond quantum size effects were investigated using several chemical property indicators. The results show that the chemical properties are strongly dependent on size for film thicknesses smaller than 1 nm (1D), and for nanodiamond particle diameters less than 2 nm (3D). When the sizes exceed these ranges there are no longer any quantum effects. The influence of surface termination coverage on the surface chemical properties has been calculated for the 2×1 reconstructed diamond (100) surface and for the diamond (111) surface. The terminating species included COOH and NH2 groups, which both are beneficial for the immobilization of biomolecules. The results of the calculations show that it is energetically possible to terminate the diamond surfaces up to 100% with NH2, while it is only possible to cover the surfaces up to 50% with COOH species. The reason for the latter result is most probably the larger sterical hindrance amongst the adsorbates. Both types of termination species were shown to influence the diamond surface electronic properties (e.g., HOMO/LUMO levels). In order to extend the diamond utility for biomedical applications, especially implant design, interactions of various growth factors with the diamond surfaces were also simulated. For non-solvent diamond-biomolecule systems, the results show that adhesion affinities are strongly dependent on biomolecule molecular weights. When including a water based solvent in the systems, the results show good physisorption affinities between proteins and diamond. Proteins structures, before and after physisorption, were visualized, and further investigated with respect to electrostatic properties and functional groups. By comparing the biomolecular structural changes during the adhesion processes, it can be concluded that both the general structures, as well as the binding pocket structures, were kept intact after the adhesion to the diamond surfaces (regardless of the adhesion affinities). In addition, the surface electronic potential distributions were maintained, which indicate preserved biomolecule functionalities. / Vascubone

Diamond

Biomolecules

Functionalization

VEGF

BMP2

Fibronectin

Chitosan

Heparin

RGD peptide

Angiopoietin

Theoretical

Cancer nanotechnology: engineering multifunctional nanostructures for targeting tumor cells and vasculatures

Kim, Gloria J.

06 April 2007

Significant progress has been made in the development of new agents against cancer and new ways of delivering existing and new agents. Yet, the major challenge to target and selectively kill cancer cells while affecting as few healthy cells as possible remains. When linked with tumor targeting moieties such as tumor-specific ligands or monoclonal antibodies, nanoparticles can be used to target cancer-specific receptors, tumor biomarkers as well as tumor vasculatures with high affinity and precision. Recently, the use of nanoparticles for drug delivery and targeting has emerged as one of the most exciting and clinically important areas in cancer nanotechnology. In this work, we tested the hypothesis that our novel ternary biomolecular nanostructures of folic acid (FA), biodegradable polymer, and paclitaxel will improve the delivery and tumor-specific distribution of the anticancer drug. The design was based on three principles: 1) Passive targeting via enhanced permeation and retention (EPR) effect; 2) active targeting via a tumor-specific ligand; and 3) prodrug that would release the drug upon delivery. First, self-assembled polymer-paclitaxel-FA nanostructures were synthesized. Their physicochemical properties were examined and biological efficacy was tested. The conjugates had significantly improved solubility in water, enabling cremophor-free formulation. Second, in vitro cellular toxicity and targeting ability of the nanostructures were investigated. In cancer cell lines with high folate receptor (FR) expression, the ternary conjugates were efficiently taken up whereas no detectable association was found in cells with minimal or no FR expression. Third, in vivo investigation in human xenograft mice models was carried out. Ternary nanostructures drastically inhibited tumor growth without inducing systemic toxicity or side effects. The ternary nanostructures displayed remarkable anti-angiogenic effect on tumor vasculature. Heparin-paclitaxel-FA was also very effective in drug resistant tumors, potentially overcoming multidrug resistance. Studies in other cancer models are in progress to determine the spectrum of applicability of these ternary nanostructures. The design principles applied in these nanoparticles can be extended to delivery and targeting of diagnostic and imaging agents. The ability to engineer multifunctional nanostructures will have a significant impact on cancer diagnostics, molecular profiling, and the integration of cancer therapy and imaging.

Drug resistance

Cancer

Heparin

Drug delivery

Folate targeting

Nanotechnology

Nanoparticles

Cancer Treatment

Drug targeting

A biocompatible, heparin-binding polycation for the controlled delivery of growth factors

Zern, Blaine Joseph

06 April 2009

The delivery of growth factors has been attempted for a number of different therapies. The approach of delivering therapeutic growth factors in a safe and efficient manner is difficult and certain criteria should be met. These criteria include: binding the appropriate growth factors, maintaining their bioactivity, and delivering these proteins with controllable release kinetics for an extended period of time. These criteria encompass a set of guidelines that hope to mimic in vivo biological events such as neovascularization. The central goal of this thesis is to meet these criteria by introducing a novel delivery strategy for growth factors using a biocompatible polycation and heparin. It was hypothesized that a polycation could interact with heparin to form a complex with the potential to deliver bioactive growth factors with an adaptable release. This hypothesis was tested by examining the release kinetics of bFGF from the complex and investigating whether the released bFGF maintained its bioactivity. The [polycation:heparin:bFGF] complex was formed by mixing the components in water, resulting in a precipitate. This precipitate was able to deliver bFGF with controllable release kinetics and the bioactivity of the released bFGF was higher than bolus bFGF and comparable to heparin stabilized bFGF. This system is expected to have the ability to bind and deliver numerous heparin-binding growth factors. In conclusion, the delivery system developed in this research provides a novel mechanism for controlled release of growth factors. This delivery strategy has met the criteria listed earlier and this research has laid the foundation for a successful delivery vehicle. Further, a biocompatible polycation was synthesized, which is a critical component of the delivery system. This polycation exhibited in vitro and in vivo biocompatibility that was orders of magnitude higher than existing polycations and has the potential to be very useful in a variety of biomedical applications. This design principle is also expected to serve as a platform for the synthesis of other biocompatible polycations.

Polycation

Growth factor delivery

Heaprin

Growth factors

Drug delivery systems

Heparin

Biocompatibility

Approaches to pharmacological treatment and gene therapy of cystic fibrosis /

Dragomir, Anca,

January 2004

Diss. (sammanfattning) Uppsala : Univ., 2004. / Härtill 5 uppsatser.

Functions of heparan sulfate during mouse development : studies of mice with genetically altered heparan sulfate biosynthesis /

Ringvall, Maria,

January 2004

Diss. (sammanfattning) Uppsala : Univ., 2004. / Härtill 4 uppsatser.

Heparan sulfate dependent sequestration during Plasmodium falciparum malaria /

Vogt, Anna,

January 2004

Diss. (sammanfattning) Stockholm : Karol. inst., 2004. / Härtill 4 uppsatser.

Thrombomodulin/heparin functionalized membrane-mimetic assemblies strategies for generating an actively anti-thrombogenic surface /

Tseng, Po-Yuan.

January 2005

Thesis (Ph. D.)--Chemical Engineering, Georgia Institute of Technology, 2006. / Chaikof, Elliot, Committee Chair ; Hanson, Stephen, Committee Member ; Lollar, John "Pete", Committee Member ; Sambanis, Athanassios, Committee Member ; Yoganathan, Ajit, Committee Member.

Characterization of mutations in the terminal repeats and capsid proteins of the adeno-associated virus type-2

Opie, Shaun Rueben,

January 2003

Thesis (Ph. D.)--University of Florida, 2003. / Title from title page of source document. Includes vita. Includes bibliographical references.

Synthesis and function of bioactive, block copolymer surfactant constructs as relevant to the preparation of anticoagulant and antibacterial medical implant surfaces /

Joshi, Pranav R.

January 1900

Thesis (Ph. D.)--Oregon State University, 2007. / Printout. Includes bibliographical references. Also available on the World Wide Web.