Master Degree / Yüksek Lisans Tezleri

Permanent URI for this collectionhttps://hdl.handle.net/11147/3008

Browse

Filters

2007 - 20082

Settings

Subject: search.filters.subject.Hemodialysis

Search Results

Now showing 1 - 2 of 2
  • Master Thesis
    Modeling of Hemodialysis Operation
    (Izmir Institute of Technology, 2008) Abacı, Hasan Erbil; Alsoy Altınkaya, Sacide; Alsoy Altınkaya, Sacide; 03.02. Department of Chemical Engineering; 03. Faculty of Engineering; 01. Izmir Institute of Technology
    Recent studies have shown that the effectiveness of hemodialysis is based on module geometry, membrane properties and operating conditions. Various experimental work exist in the literature concentrated on the synthesis of new hemodialysis membranes. However, optimization of membrane structure requires extensive and time consuming experimentations. Therefore, mathematical models are neccessary that can be used to predict the performance of hemodialysis operation. In this study, a predictive theoretical model was developed to predict the solute concentrations in patient.s blood and optimize the efficiency of hemodialysis operation. The model takes into account simultaneous mass and momentum transfer along with the adsorption of rejected protein molecules on the surface of the membrane.Model predictions show that blood and dialysate flowrates are effective for all sizes of molecules. The change in structural properties of the membrane makes no effect on the total removal of urea beacause of its high clearance. On the other hand, a considerable increment in the clearance of larger molecular weight solutes occurs as the pore size and porosity of the membrane increases. The most important design parameter for dialysis unit which influence the solute clearances significantly is found to be the effective diameter among the fibers in the dialyzer.The model is extended to investigate the use of urease immobilized membranes on the efficiency of the hemodialysis operation. The results have shown that urease immobilization enhances the removal of urea from the blood and decreases the protein adsorption capacity of the polysulfone membrane.Model predictions are compared with different sets of clearance data available in the literature. The agreement is found to be satisfactory which suggests that the model can be used as a tool to design or test the performance of dialysis units.
  • Master Thesis
    Preparation and Characterization of Hemodialysis Membranes
    (Izmir Institute of Technology, 2007) Yaşar Mahlıçlı, Filiz; Alsoy Altınkaya, Sacide; Alsoy Altınkaya, Sacide; 03.02. Department of Chemical Engineering; 03. Faculty of Engineering; 01. Izmir Institute of Technology
    Hemodialysis is a widely used clinical therapy for end-stage renal failure and dialysis membranes are vital components of a hemodialysis unit. The most desirable properties of a hemodialysis membrane are high mass transfer of toxic solutes to reduce the dialysis time, blood compatibility and limited protein adsorption capacity. Protein adsorption or deposition on the surface or in its pores results in a progressive decline in flux, change of selectivity of the membrane and the activation of different defense systems in blood. To prepare hemodialysis membranes with improved transport properties and protein adsorption resistant surfaces, an enzyme immobilization technique was used. Asymmetric cellulose acetate membranes were prepared through dry phase inversion method and they were modified by blending urease enzyme directly into the casting solution. The effect of enzyme immobilization on the protein adsorption, solute transport rates and mechanical properties was investigated through static adsorption and permeation experiments, mechanical tests and structural characterization by scanning electron microscope. It was found that the solute permeation rates decreased exponentially while the maximum tensile strength of the membranes increased significantly by increasing the cellulose acetate (CA) to acetone weight fraction ratio in the membrane forming solution due to a change in the structure from porous to dense one. Modification of the CA membrane with urease immobilization increased the permeation coefficients of creatinine and uric acid by a factor of 1.2 and 1.7, respectively. Similarly, the % removal of urea from the donor compartment in 1 hour increased from 45.8% to 53.2% by using urease immobilized CA membrane. The protein adsorption capacity of the urease immobilized CA membrane was found to be 2 times lower than that of the regular CA membrane. Protein fouling on the membranes caused a decrease in the transport rates of all solutes. Due to protein fouling, the decrease in the permeation coefficients of creatinine and uric acid are 59.0% and 76.5%, respectively, through regular CA membranes. On the other hand, urease immobilization limited the decrease in the permeation rates by 39.2% and 33.4% for creatinine and uric acid, respectively. In a similar way, the rate of removal of urea through CA membrane and urease immobilized CA membrane decreased by 31.2% and 11.7%, respectively. While urease immobilization decreased the protein adsorption capacity, it did not cause any loss in mechanical strength of the membrane. These results indicate that urease immobilization can be used to improve transport properties and reduce protein adsorption capacity of the CA membranes. Urease immobilized CA membranes prepared in this study can be used as an alternative membrane in hemodialysis units.