Mechanical properties and shear bond strength of denture teeth to different denture base materials

Alsulaimani, Othman Saleh

13 June 2021

OBJECTIVES: The aim of this in vitro study is to investigate the mechanical properties and bond strength of denture teeth to recently introduced denture base materials. MATERIALS AND METHODS: From high-impact pourable acrylic HIPA (Dentsply Sirona), DSDM Lucitone 199 puck (Dentsply Sirona), and digitally printed (Dentsply Sirona) denture base materials, bar specimens were fabricated for flexural testing (10 × 3.3 × 64 mm3) and fracture toughness testing (8 × 4 × 39 mm3). Tensile strength specimens were fabricated to form dumbbell-shaped specimens (3 × 6 mm cross-section) with a central bar. Micro-tensile specimens were fabricated into 10 × (1.5 ± 0.2) × (1.5 ± 0.2) mm3 bars. The treated specimens were subjected to thermal cycling. Square plates (3 × 18 mm2) were prepared for bonding to IPN denture teeth rods (3.85 mm) for evaluation of shear bond strength after surface treatment with airborne particle abrasion of 50 m aluminum oxide powder. The means were compared using an ANOVA Tukey HSD test, paired Student’s t-test, and contingency test (α = 0.05). RESULTS: DSDM had statistically higher flexural strength (p < 0.0001) than the other tested materials, as determined by one-way ANOVA. However, all denture base materials’ flexural moduli were not statistically different (p = 0.22). The effect of thermal aging on flexural strength (p = 0.18) and moduli of tested materials (p = 0.83) was not statistically significant. DSDM demonstrated statistically higher fracture toughness values (p = 0.0013) than the other materials. HIPA, however, had statistically higher work of fracture values than the other materials tested (p < 0.0001). The effect of thermal aging on Kmax and fracture work of all tested materials (pooled) was statistically different (p = 0.0002 and p = 0.0132, respectively). DSDP had the statistically highest tensile strength, followed by DSDM, and HIPA had the lowest (p < 0.0001). The effect of thermal aging on tensile strength (pooled) was statistically different (p <0.0001). The HIPA material’s mean micro-tensile strength was significantly lower than the DSDM and DSDP materials (p < 0.0001). Furthermore, the effect of thermal aging on the micro-tensile strength of all tested materials (pooled) was statistically different (p = 0.0005). Each paired Student’s t-test showed that surface abrasion increased the shear bond strength of DSDM, DSDP, and HIPA materials significantly (p < 0.0001, p = 0.0037, and p = 0.0035, respectively). Contingency analysis of the effect of the surface abrasion on each material’s failure mode revealed a 100% adhesive failure mode in DSDM. In DSDP, 5% of the failure mode was mixed. In contrast, the analysis showed 40% cohesive, 50% adhesive, and 10% mixed failure modes in HIPA material, although this finding was not statistically significant (p = 0.32). CONCLUSIONS: DSDM had higher flexural strength than the other tested materials and maximum stress intensity factors. However, HIPA performed better in terms of flexural modulus work of fracture. DSDP material had higher tensile strength values than the other materials. Thermocycling increased flexural strength, modulus values, and fracture toughness values, except for DSDP material which its work of fracture reduced after thermocycling. The tensile strength values of all tested materials was reduced after thermocycling. Air abrasion treatment enhanced the bonding strength between denture teeth and denture base material. Fractographic analysis of fragmented HIPA and DSDM specimens revealed varying degrees of plastic deformation, while DSDP material exhibiting less plastic deformation. / 2021-12-13T00:00:00Z

Materials science

Synthesis of Carbon Nanotube Fabric for Firefighter Garments

Ng, Vianessa

23 May 2022

No description available.

Materials Science

Engineering the Dermal-Epidermal Junction

Malara, Megan Marie

02 September 2020

No description available.

Materials Science

Design, synthesis, and evaluation of poly(1,2-glycerol carbonate)-paclitaxel conjugate nanoparticles for the tunable delivery of paclitaxel

Ekladious, Iriny

03 July 2018

Since their initial conceptualization, polymer-drug conjugate nanocarriers have been a mainstay of the drug delivery field. The conjugation of therapeutic agents to polymeric carriers offers several critical advantages including improved drug solubilization, controlled release, and enhanced safety. Accordingly, polymer-drug conjugate nanocarriers are uniquely positioned to remedy some of the limitations of conventional small molecule chemotherapeutics, namely their narrow window of therapeutic efficacy, rapid clearance, and limited tumor exposure. This dissertation describes the design, synthesis, and evaluation of a novel sustained release, biodegradable polymeric nanocarrier as a single administration replacement of multi-dose paclitaxel (PTX) treatment regimens. The synthesis of poly(1,2-glycerol carbonate)-graft-succinic acid-paclitaxel (PGC-PTX) is presented, and its use enables high, controlled PTX loadings. Moreover, the polymer backbone is composed of biocompatible building blocks—glycerol and carbon dioxide. When formulated as nanoparticles (NPs), PGC-PTX NPs exhibit high aqueous PTX concentrations, sub-100 nm diameters, narrow dispersity, prolonged storage stability, and sustained and controlled PTX release kinetics. In murine models of peritoneal carcinomatosis, in which the clinical implementation of multi-dose intraperitoneal (IP) treatment regimens is limited by catheter-related complications, PGC-PTX NPs exhibit improved safety at high doses, tumor localization, and efficacy even after a single IP injection, with comparable therapeutic effect to multi-dose IP PTX treatment regimens. The PGC-PTX NP platform is additionally amenable to optimization via modulation of nanocarrier properties. Specifically, the dual conjugation and physical entrapment of PTX in the NPs harnesses the physicochemical interactions between free and conjugated PTX to achieve unprecedented ultra-high drug loadings as well as facile control of nanomechanical properties and release kinetics. Optimization of these programmable carriers consequently enables the safe delivery of high drug doses as well as sustained therapeutic efficacy. In a murine model of peritoneal carcinomatosis, a single high dose of dual-loaded PGC-PTX nanocarriers affords significantly improved survival compared to weekly, multi-dose PTX treatment. Modulation of nanocarrier properties via the incorporation of poly(lactide-co-glycolide) (PLGA) is additionally explored. Although the integration of PLGA does not significantly alter NP physical properties, the polymer blend nanocarriers exhibit improved in vitro potency relative to PGC-PTX NPs, warranting the continued evaluation of the mechanism by which PLGA modulates nanocarrier efficacy. / 2020-07-02T00:00:00Z

Materials science

Chromium poisoning in cathodes of solid oxide fuel cells: the role of current density, humidity, and cathode composition, and strategies for mitigation

Gong, Yiwen

03 July 2018

Power generation systems based on solid oxide fuel cells (SOFCs) offer a pathway to a highly efficient and pollution free energy economy. Operation of SOFCs at intermediate temperatures allow the use of metallic interconnects. However, the chromium oxide scale that forms on the metallic interconnect can volatilize and transport and deposit on the cathode, leading to cell performance degradation. The objectives of this dissertation are to understand the role of current density, cathode overpotential, humidity, and cathode composition on Cr-poisoning and suggest mitigation strategies based on this understanding. Conventional (La,Sr)MnO3 (LSM) cathode half-cells have been electrochemically studied to understand the mechanism of Cr-poisoning. The cells have been tested as a function of current density (and thus cathode overpotential), and humidity levels in the oxidant gas. The half-cell measurements have revealed that Cr-poisoning accelerated with cathode overpotential (i.e. current density) and humidity. Microstructural characterization of tested cells found evidence of Cr-rich species at the cathode/ electrolyte interface at high cathode overpotential and humidity. Based on the experimental results, a mechanism of Cr-poisoning has been proposed. With the objective of mitigating Cr-poisoning observed in LSM cathodes, lanthanum nickelate, La2NiO4+δ (LNO) has been studied as an alternative cathode material. Both half-cells and full single SOFCs featuring LNO as the working electrode/cathode, and ferritic stainless steel current collectors have been fabricated. The cells have been tested under the same conditions as the LSM cells. The chromium deposition at the cathode/ electrolyte interface was much reduced for LNO compared to LSM, and the cell performance of cell featuring LNO cathode continually improved with time in contrast to the LSM cell which started to degrade during cathodic current application. Based on the deconvolution of the polarization losses, it was concluded that the higher tolerance of the LNO cathode to Cr-poisoning compared to LSM, can be attributed to maintaining a low cathode activation polarization. The differences in the mechanisms of Cr-poisoning between LSM and LNO has been clarified. A two-pronged strategy combining chromium-tolerant cathodes and interconnect protective coatings is suggested to mitigate long-term performance degradation arising from chromium poisoning.

Materials science

Phase transformations and chemical interactions in materials exposed to high temperatures

Guo, Jicheng

22 October 2018

Phase transformations and chemical interactions occur in many materials systems exposed to elevated temperatures. In this study, materials exposed to high temperatures in three distinctive applications, have been examined. The first application involves the fabrication of semiconductor-core optical fibers for mid-infrared transmission. Such fibers can be used for chemical sensing, threat detection, and bio-imaging. In this study, germanium-core borosilicate glass cladded fibers were fabricated using rod-in-tube drawing. An analytical model for the deformation and heat transfer in the fiber preform during the high temperature fabrication process was developed. The solidification of the germanium core was experimentally studied using a proxy system of melting ice in a tube. The relative roles of conductive and convective heat transfer in determining the melting mechanism was analyzed. The fabricated fibers were characterized by various electron microscopy based techniques to understand impurity diffusion from the cladding to the core, as well as to study the crystalline quality of the Ge core. The second application involves solid oxide membrane (SOM) based electrolytic production of silicon, where the interaction between the ceramic membrane and the molten salt is the key in determining the lifetime of the membrane. The yttria-stabilized zirconia (YSZ) membrane was found to degrade over time due to chemical interactions with the silica-containing molten oxy-fluoride flux. These interactions led to the formation of a yttria depletion layer in the YSZ in contact with the molten salt. A series of flux compositions were designed to systematically test the correlation between flux optical basicity, yttria activity and YSZ membrane degradation. The results provide a guideline for eliminating membrane degradation during the production of silicon using the SOM electrolysis process. The third application involves molten mixtures of lithium chloride and metallic lithium for metal oxide reduction application. These mixtures exhibit anomalous physical properties that lack a comprehensive explanation. In this study, the structures of bulk molten LiCl and LiCl-Li mixtures were investigated using an in-situ high-energy x-ray diffraction (HEXRD) technique. The structure factors and the pair distribution functions (PDF) of LiCl-Li mixtures were compared with those of pure LiCl. The results suggest Li disperses in LiCl as nano-clusters.

Materials science

Microfluidic device for rapid detection of fibrinolysis of blood clots

Jiang, Han

04 June 2019

This thesis presents a method to detect fibrin formation based on electrical impedance sensing. A polydimethylsiloxane (PDMS) microfluidic device was designed and fabricated to detect fibrin formation in artificial blood samples (solution of fibrinogen, thrombin and CaCl2) by measuring changes in electrical impedance during the process of coagulation. The electrical measurements were performed using a lock-in amplifier. The optical properties of the fibrin in the microfluidic device were observed in an inverted microscope to confirm the clot formation. In the study, the dimensions of the microfluidic devices and the sensing electrodes were optimized to improve the sensitivity and to ensure electrical contact between the electrodes and analyte. An equivalent circuit model was developed to fit the change in the electrical signal of the channel accurately and to determine the optimal measurement frequency. The measured electrical impedances exhibited an expected increase with the blood coagulation. In summary, the technique and the device were shown promising for detecting the blood coagulation process.

Materials science

Developing Oxygen-sensitive Probes for Long-term Oxygen Monitoring

Li, Chao

12 October 2018

No description available.

Materials Science

Development of Low-cost Casting Titanium Alloys: An Integrated Computational Materials Engineering (ICME) Guided Study

Liang, Zhi

January 2018

No description available.

Materials Science

MATERIALS DISCOVERY AND DESIGN USING HERITAGE DATA:APPLICATION TO 9 – 12 wt% Cr MARTENSITIC STEELS

Kumar, Amit

23 May 2019

No description available.

Materials Science