Design and structural analysis of sofa frames

Dai, Li,

January 2007

Thesis (Ph.D)--Mississippi State University. Department of Forest Products. / Title from title screen. Includes bibliographical references.

3D bioprinted hydrogel scaffolds laden with Schwann cells for use as nerve repair conduits

2015 June 1900

The goal of nerve tissue engineering is to promote and guide axon growth across a site of nerve injury without misdirection. Bioengineered tissue scaffolds have been shown to be promising for the regeneration of damaged peripheral nerves. Schwann cells play a pivotal role following nerve injury by forming aligned “bands of Büngner” that promote and guide axon regeneration into the distal nerve segment. The incorporation of living Schwann cells into various hydrogels has therefore been urged during the fabrication of tissue engineered nerve scaffolds. The aim of this research is to characterize biomaterials suitable for 3D bioplotting of nerve repair scaffolds. Here a novel technique of scaffold fabrication has been optimized to print alginate-based three-dimensional tissue scaffolds containing hyaluronic acid and living Schwann cells. Alginate/hyaluronic acid scaffolds were successfully fabricated with good printability and cell viability. Addition of the polycation polyethyleneimine (PEI) during the fabrication process stabilized the structure of alginate through the formation of a polyelectrolyte complex and had a significant influence on the degree of swelling, degradation rate, mechanical property, and release kinetics of incorporated protein within the scaffolds. A preliminary in vivo study showed the feasibility of implanting 3D printed alginate/hyaluronic acid scaffolds as nerve conduits in Sprague-Dawley (SD) rats with resected sciatic nerves. However alginate/hyaluronic acid scaffolds were found to be unsuitable for axonal regeneration. Further in vitro culture of Schwann cells was performed in collagen type-I, fibrin, fibrin/hyaluronic acid, and their combination with alginate. It was found that Schwann cells had more favorable cell morphology in fibrin/hyaluronic acid or collagen without alginate. Schwann cell proliferation and alignment were better in fibrin/hyaluronic acid. Therefore fibrin/hyaluronic acid is more ideal than most other hydrogel formulations for use in the bioprinting of nerve repair tissue engineering scaffolds, which incorporate cellular elements. As Schwann cells also align along the long axis of the printed fibrin/hyaluronic acid strands, 3D bioprinting of multiple layers of crosslinked fibrin strands can be used to fabricate a nerve conduit mimicking the bands of Büngner.

Tissue engineered scaffolds

Nerve tissue engineering

Axonal regeneration

3D Bioprinting

Schwann cells

Nano-Engineered Contrast Agents : Toward Multimodal Imaging and Acoustophoresis

Kothapalli, Satya V.V.N.

January 2015

Diagnostic ultrasound (US) is safer, quicker and cheaper than other diagnostic imaging modalities. Over the past two decades, the applications of US imaging has been widened due to the development of injectable, compressible and encapsulated microbubbles (MBs) that provide an opportunity to improve conventional echocardiographic imaging, blood flow assessment and molecular imaging. The encapsulating material is manufactured by different biocompatible materials such as proteins, lipids or polymers. In current research, researchers modify the encapsulated shell with the help of advanced molecular chemistry techniques to load them with dyes (for fluorescent imaging), nanoparticles and radioisotopes (for multimodal imaging) or functional ligands or therapeutic gases (for local drug delivery). The echogenicity and the radial oscillation of MBs is the result of their compressibility, which undoubtedly varies with the encapsulated shell characteristics such as rigidity or elasticity. In this thesis, we present acoustic properties of novel type of polyvinyl alcohol (PVA)-shelled microbubble (PVA-MB) that was further modified with superparamagnetic iron oxide nanoparticles (SPIONs) to work as a dual-modal contrast agent for magnetic resonance (MR) imaging along with US imaging. Apparently, the shell modification changes their mechanical characteristics, which affects their acoustic properties. The overall objective of the thesis is to investigate the acoustic properties of modified and unmodified PVA-MBs at different ultrasound parameters. The acoustic and mechanical characterization of SPIONs modified PVA-MBs revealed that the acoustical response depends on the SPION inclusion strategy. However they retain the same structural characteristics after the modification. The modified MBs with SPIONs included on the surface of the PVA shell exhibit a soft-shelled behavior and produce a higher echogenicity than the MBs with the SPIONs inside the PVA shell. The fracturing mechanism of the unmodified PVA-MBs was identified to be different from the other fracturing mechanisms of conventional MBs. With the interaction of high-pressure bursts, the air gas core is squeezed out through small punctures in the PVA shell. During the fracturing, the PVA-MBs exhibit asymmetric (other modes) oscillations, resulting in sub- and ultra-harmonic generation. Exploiting the US imaging at the other modes of the oscillation of the PVA-MBs would provide an opportunity to visualize very low concentrations of (down to single) PVA-MBs. We further introduced the PVA-MBs along with particles mimicking red blood cells in an acoustic standing-wave field to observe the acoustic radiation force effect. We observed that the compressible PVA-MBs drawn toward pressure antinode while the solid blood phantoms moved toward the pressure node. This acoustic separation method (acoustophoresis) could be an efficient tool for studying the bioclearance of the PVA-MBs in the body, either by collecting blood samples (in-vitro) or by using the extracorporeal medical procedure (ex-vivo) at different organs. Overall, this work contributes significant feedback for chemists (to optimize the nanoparticle inclusion) and imaging groups (to develop new imaging sequences), and the positive findings pave new paths and provide triggers to engage in further research. / <p>QC 20150827</p> / 3MiCRON

Nano-engineered microbubbles

SPION nanoparticles

Acoustic characterization of MBs

Fracturing mechanism of MBs

Opto-acoustics

Acoustophoresis

Toxicity of Engineered Nanoparticles to Anaerobic Wastewater Treatment Processes

Gonzalez-Estrella, Jorge Gonzalez

January 2014

Nanotechnology is an increasing market. Engineered nanoparticles (NPs), materials with at least one dimension between 1 and 100 nm, are produced on a large scale. NPs are vastly used in industrial processes and consumer products and they are most likely discharged into wastewater treatment plants after being used. Activated Sludge is one of the most applied biological wastewater treatment processes for the degradation of organic matter in sewage. Activated sludge produces an excess of sludge that is commonly treated and stabilized by anaerobic digestion. Recent studies have found that NPs accumulate in the activated sludge; thus, there is a potential for the concentrations of NPs to magnify as concentrated waste sludge is fed into the anaerobic digestion process. For this reason, it is important to study the possible toxic effects of NPs on the microorganisms involved in the anaerobic digestion process and the approaches to overcome toxicity if necessary. The present work evaluates the toxic effect of NPs on anaerobic wastewater treatment processes and also presents approaches for toxicity attenuation. The first objective of this dissertation (Chapter III) was to evaluate the toxicity of high concentrations (1, 500 mg L⁻¹) of Ag⁰, Al₂O₃, CeO₂, Cu⁰, CuO, Fe⁰, Fe₂O₃, Mn₂O₃, SiO₂, TiO₂, and ZnO NPs to acetoclastic and hydrogenotrophic methanogens and the effect of a dispersant on the NPs toxicity to methanogens. The findings indicated that only Cu⁰ and ZnO NPs caused severe toxicity to hydrogenotrophic methanogens and Cu⁰, CuO, and ZnO NPs to acetoclastic methanogens. The dispersant did not impact the NPs toxicity. The concentrations of Cu⁰ and ZnO causing 50% of inhibition (IC₅₀) to hydrogenotrophic methanogens were 68 and 250 mg L⁻¹, respectively. Whereas the IC₅₀ values for acetoclastic methanogens were 62, 68, and 179 for Cu⁰, ZnO, and CuO-Cu NPs respectively. These findings indicate that acetoclastic methanogens are more sensitive to NP toxicity compared to hydrogenotrophic methanogens and that Cu⁰ and ZnO NPs are highly toxic to both. Additionally, it was observed that the toxicity of any given metal was highly correlated with its final dissolved concentration in the assay irrespective of whether it was initially added as a NP or chloride salt, indicating that corrosion and dissolution of metals from NPs may have been responsible for the toxicity. The second objective of this dissertation (Chapter IV) was to evaluate the Cu⁰ NP toxicity to anaerobic microorganisms of wastewater treatment processes. Cu⁰ is known to be toxic to methanogens; nonetheless, little is known about its toxic effects on microorganisms of upper trophic levels of anaerobic digestion or other anaerobic process used for nitrogen removal. This specific objective evaluated Cu⁰ NP toxicity to glucose fermentation, syntrophic propionic oxidation, methanogenesis, denitrification and anaerobic ammonium oxidation (anammox). Chapter IV showed that anammox and glucose fermentation were the least and most inhibited processes with inhibition constants (K(i)) values of 0.324 and 0.004 mM of added Cu⁰ NPs, respectively. The Ki values obtained from the residual soluble concentration of the parallel experiments using CuCl₂ indicated that Cu⁰ NP toxicity is most likely caused by the release of soluble ions for each one of the microorganisms tested. The results taken as a whole demonstrate that Cu⁰ NPs are toxic to a variety of anaerobic microorganisms of wastewater treatment processes. The third objective of this document (Chapter V) was to study the role of biogenic sulfide in attenuating Cu⁰ and ZnO NP toxicity to acetoclastic methanogens. Previous literature results and research presented in this dissertation indicated that the release of soluble ions from Cu and ZnO NPs cause toxicity to methanogens. In the past, the application of sulfide to precipitate heavy metals as inert non-soluble sulfides was used to attenuate the toxicity of Cu and Zn salts. Building on this principle, Chapter V evaluated the toxicity of Cu⁰ and ZnO NPs in sulfate-containing (0.4 mM) and sulfate-free conditions. The results show that Cu⁰ and ZnO were 7 and 14x less toxic in sulfate-containing than in sulfate-free assays as indicated by the differences in K(i) values. The K(i) values obtained based on the residual metal concentration of the sulfate-free and sulfate-containing assays were very similar, indicating that the toxicity is well correlated with the release of soluble ions. Overall, this study demonstrated that biogenic sulfide is an effective attenuator of Cu⁰ and ZnO NP toxicity to acetoclastic methanogens. Finally, the last objective (Chapter VI) of this dissertation was to evaluate the effect of iron sulfide (FeS) on the attenuation of Cu⁰ and ZnO toxicity to acetoclastic methanogens. FeS is formed by the reaction of iron(II) and sulfide. This reaction is common in anaerobic sediments where the reduction of iron(III) to iron(II) and sulfate to sulfide occurs. FeS plays a key role controlling the soluble concentrations of heavy metals and thus their toxic effects in aquatic sediments. This study evaluated the application of FeS as an approach to attenuate Cu⁰ and ZnO NP toxicity and their salt analogs to acetoclastic methanogens. Two particle sizes, coarse FeS (FeS-c, 500-1200 µm) and fine FeS (FeS-f, 25-75 µm) were synthesized and used in this study. The results showed 2.5x less FeS-f than FeS-c was required to recover the methanogenic activity to the same extent from the exposure to highly inhibitory concentrations of CuCl₂ and ZnCl₂ (0.2 mM). The results also showed that a molar ratio of FeS-f/Cu⁰, FeS-f/ZnO, FeS-f/Zn Cl₂, and FeS-f/CuCl₂ of 3, 3, 6, and 12 respectively, was necessary to provide a high recovery of methanogenic activity (>75%). The excess of FeS needed to overcome the toxicity indicates that not all the sulfide in FeS was readily available to attenuate the toxicity. Overall, Chapter VI demonstrated that FeS is an effective attenuator of the toxicity of Cu⁰ NP and ZnO NPs and their salt analogs to methanogens, albeit molar excesses of FeS were required.

Attenuation

Engineered Nanomaterials

Inhibition constants

Sulfide

Toxicity

Environmental Engineering

Anaerobic digestion

Evaluation of the impact of engineered nanoparticles on the operation of wastewater treatment plant

Eduok, Samuel

January 2013

The effect of engineered nanoparticles (ENPs) mixture consisting of silver oxide, (Agg0[Silver Oxide Nanopartical], 20 nm), titanium dioxide, (TiO2[Titanium dioxide], 30-40 nm) and zinc oxide, (ZnO, 20 nm) compared with their bulk metal salts was evaluated against unspiked activated sludge (control) using 3 parallel pilot-scale treatment plants. The total concentration of the ionic species of Ag+ Ti[Silver + Titanium] and Zn(2+) in the effluent of the ENP spiked activated sludge (AS) was below limits of detection and> 99% of the spiked ENP were found in the waste activated sludge (WAS), whereas 39 – 58 % of Ag0[Silver Oxide Nanopartical], 51 – 63 % and 58 – 74 % of ZnO ion concentrations were recovered in the anaerobic digestate (AD) cake suggesting higher affinity of ENPs to WAS than to anaerobic digestate. ENPs induced a 2-fold increase of the microbial community specific oxygen uptake rate (SOUR) compared with the control and > 98 % of ammonia and 80 % of COD were removed from the AS suggesting that the heterotrophic biomass retained their ability to nitrify and degrade organic matter at the spiked ENP concentration. The floc size and cultivable microbial abundance was reduced in the ENP spiked AS with no apparent disruption of the overall AS process efficiency. However, scanning electron microscopic analysis clearly showed damage to specific microbial cells. The lipid fingerprint and 16S rRNA gene-based pyrosequencing evidenced the dominance of Proteobacteria, Firmicutes, and Bacteriodetes with a clear temporal shift in microbial community structure. The prominent nano-tolerant bacterial species identified were Acidovorax, Rhodoferax, and Comamonas whereas Methanocorpusculum and Methanosarcina were recovered in AS and were the dominant Archaea in the AD with 99 and 98 % similarities to the closest culturable relative. Their presence in the AS suggests tolerance to ENPs and oxygen-dependent respiration. V. fisheri activity was not sensitive to the ionic concentrations of the ENP or metal salt mixture in the digestate samples and illustrates the need to develop bioassay using indigenous wastewater microorganisms to detect the potential effect of ENP. Overall, unlike other xenobiotic compounds, ENPs can hasten the natural selection of microbial species in activated sludge and anaerobic digestion processes.

628.3

CO₂ geological storage: hydro-chemo-mechanically coupled phenomena and engineered injection

Kim, Seunghee

08 August 2012

Global energy consumption will increase in the next decades and it is expected to largely rely on fossil fuels. The use of fossil fuels is intimately related to CO₂ emissions and the potential for global warming. Geological CO₂ storage aims to mitigate the global warming problem by sequestering CO₂ underground. Coupled hydro-chemo-mechanical phenomena determine the successful operation and long term stability of CO₂ geological storage. This research explores various coupled phenomena, identifies different zones in the storage reservoir, and investigates their implications in CO₂ geological storage. Spatial patterns in mineral dissolution and precipitation are examined based on a comprehensive mass balance formulation. CO₂-dissolved fluid flow is modeled using a novel technique that couples laminar flow, advective and diffusive mass transport of species, mineral dissolution, and consequent pore changes to study the reactive fluid transport at the scale of a single rock fracture. The methodology is extended to the scale of a porous medium using pore network simulations to study both CO₂ reservoirs and caprocks. The two-phase flow problem between immiscible CO₂ and the formation fluid (water or brine) is investigated experimentally. Plug tests on shale and cement specimens are used to investigate CO₂ breakthrough pressure. Sealing strategies are explored to plug existing cracks and increase the CO₂ breakthrough pressure. Finally, CO₂-water-surfactant mixtures are evaluated to reduce the CO₂-water interfacial tension in view of enhanced sweep efficiency. Results can be used to identify optimal CO₂ injection and remediation strategies to maximize the efficiency of CO₂ injection and to attain long-term storage.

CO₂ geological storage

Reactive fluid transport

Engineered injection

Hydro-chemo-mechanical coupling

Geological carbon sequestration

Transparency in Federal Policy-Making: the Case of Biotechnology in Animals Intended for Human Consumption

Lee, Heather

January 2013

This research project examines the degree of transparency of the Canadian Federal Government’s decision-making processes and institutions with respect to the human consumption of animals produced through modern biotechnology (biotechnology-produced animals). It provides a timely study of the Federal Government’s decision-making process; as of January 2013 the government has yet to determine whether, and how, biotechnology-produced animals are to be approved for human consumption. Foods that contain genetically modified organisms (GMOs) are already commercially widely available in Canada. Research is well underway to see if biotechnology-produced animals may also be developed and introduced into the food system. Government decisions regarding the human consumption of biotechnology-produced animals have the potential to revolutionize food systems globally and nationally. This thesis offers an analysis of primary and secondary data focusing on the degree of federal transparency with respect to regulating GMO foods generally and, more specifically, the emerging policy issues around biotechnology-produced animals. This exploration sets the stage for the following investigation of barriers as well as opportunities to fostering federal transparency with respect to policy and regulatory decisions regarding GMO foods. Findings are directed towards members of the communities of interest who are interested in questions relating to the degree of federal transparency and government approaches to foods that contain material produced through modern biotechnology.

Biotechnology

Genetically Engineered

Canada

Policy

Genetically Modified

Food

Federal

GMO

Environmental and Resource Studies

Radio frequency evaluation of oriented strand board

Liu, Xiaojian,

January 2008

Thesis (Ph.D.)--Mississippi State University. Department of Forest Products. / Title from title screen. Includes bibliographical references.

Optical Measurement of Strang Geometry and Orientation and Their Influence on Oriented Strand Composite Formation Quality

Gaete-Martinez, Victor

January 2009

No description available.

Composite materials -- Measurement

Engineered wood -- Measurement

Optical measurements

Strength of materials -- Measurement

Placental mesenchymal stem cell sheets: motivation for bio-MEMS device to create patient matched myocardial patches

Roberts, Erin

03 July 2018

Congenital heart defects are the number one cause of birth defect-related deaths. Cardiovascular diseases are the most common cause of death worldwide. Layered cellular sheet constructs offer one very valuable option for cardiac patch implantation during surgical treatment of both pediatric and adult patients with cardiac defects or damage. A very exciting, relatively unexplored, autologous, available cell source for making patches are placenta-derived mesenchymal stem cells (pMSCs). In this study, pMSCs were assessed as a potential cell source for cardiac repair and regeneration by evaluating their differentiation capacity into cardiomyocytes, their effects on cardiac cell migration and proliferation, and their ability to be grown into cell sheets. It was found that pMSC cardiac protein content was enhanced by differentiation media treatment, but no beating cells were produced. Undifferentiated pMSCs improved migration and proliferation of a cardiac cell population and formed intact, aligned cell sheets. However, like many new cell sources for cardiac repair, pMSCs should still be functionally characterized to understand how compatible they will be with resident heart tissue. Implanting non-autologous, potentially pluripotent, non-myocyte (non-beating) cells presents concerns regarding electromechanical mismatch and implant rejection. The characterization of non-traditional cell sources such as pMSCs motivated the design of a bio-MEMS device that assesses contractile force and conduction velocity in response to electrical and mechanical stimulation of a cell source as it is grown and once it forms a cellular sheet. This ideally creates the ability for patient specific cell sheets to be cultured, characterized, and conditioned to be compatible with the patient’s cardiac environment in vitro, prior to implantation. In this work, the device was designed to achieve the following: cellular alignment, electrical stimulation, mechanical stimulation, conduction velocity readout, contraction force readout, and upon characterization, cell sheet release. The platform is based on a set of comb electrical contacts which are three dimensional wall contacts made of polydimethylsiloxane and coated with electrically conductive metals. Device fabrication and initial validation experiments were completed as part of this study; ultimately the device will allow for the complete functional characterization and conditioning of variable cell source cell sheet implants for myocardial implantation. / 2019-07-02T00:00:00Z

Biomedical engineering

Conduction velocity

Contractility

Electrical stimulation

Engineered heart tissue

Mechanical conditioning