Global ETD Search

461	Micromechanics of softwoods in the transverse plane : effects on cell and annual ring scales Modén, Carl S. January 2008 (has links) Transverse mechanical properties of wood are important in many practial applications and an interesting scientific subject. A very low transverse shear modulus has been identified in spruce, which causes large strain concentrations in wood structures. In this thesis, experimental characterization of local density variations as well as local strain fields are carried out using the SilviScan apparatus and digital speckle photography, respectively. This is combined with micromechanical modeling based on hexagonal wood cells in combination with finite element analysis. Problems addressed include the moduli in the transverse plane, including variations at the scale of individual annual rings. The relative importance of cell wall bending and stretching deformation mechanisms is analysed as a function of wood cell geometry, relative density and direction of loading (radial, tangential and shear). Transverse anisotropy is also analyzed, including its dependency of earlywood and latewood characteristics. The wood cell shape angle variation and density effects are sufficient to explain transverse anisotropy in softwoods (no ray effects), and the influence of earlywood/latewood ratio is explained. As a practical test method for shear modulus measurements, an off-axis compression test with full-field strain determination is proposed. The advantage is a simple fixture and large region of representative strain required for a heterogeneous material such as wood. As an alternative, the single cube apparatus (SCA) for shear tests is evaluated. The SCA is used to determine the shear strain distribution within the annual rings. Based on the density distribution of the shear test specimen and a micromechanics model, a finite element model is developed, and predictions are compared with the measured shear strains. The agreement between predicted and measured shear strains at the annual ring scale are remarkably good. It shows that the low GRT of spruce is due to the low earlywood density and the large cell wall bending deformation resulting from shear loading. Furthermore, it illustrates the need for improved understanding of annual ring scale effects. For example, fairly low transverse global loads will lead to lage local shear strains. / Transversella mekaniska egenskaper hos trä är viktiga i många praktiska tillämpningar och är av vetenskapligt intresse. Gran har exemplevis mycket låg transversell skjuvmodul, vilket leder till stora lokala töjningskoncentrationer i trästrukturer. I den här avhandlingen utförs experimentella mätningar av densitetsfördelning och lokal töjningsfördelning med hjälp av SilviScan utrustning (röntgen) och digital speckelfoto grafi (DSP). Det kombineras med mikromekanisk modellering med hexagonala cellmodeller som utgångspunkt, ibland i kombination med finita elementberäkningar. Transversella moduler bestäms liksom töjningseffekter på skalan individuella årsringar. Den relativa betydelsen av böjning och sträckning av cellväggen analyseras som funktion av relativ densitet och belastningsriktning (radiell, tangentiell och skjuvning). Stor andel böjdeformation ger låg modul och proportionerna mellan de båda mekanismerna styr graden av anisotropi. Transversell anisotropi analyseras därför, inklusive dess beroende av karakteristiken hos vårved och sommarved. Formvinkeln på vedcellen och inverkan av densitet är tillräckliga för att förklara graden av anisotropi (utan inverkan från märg- strålar). Inverkan av förhållandet mellan mängden vårved och sommarved på anisotropin analyseras särskilt. En enkel tryckbelastningsmetod (“off-axis metod”) används för att bestämma transversell skjuvmodul hos trä. Metoden kombineras med DSP. Fördelen är en enkel fixtur i kombination med det stora område av ren skjuvdeformation som uppstår i provstaven. Som ett alternativ utvärderas också en metod baserad på kubiskt prov (SCA). Metoden används för att bestämma lokala skjuvtöjningar på skalan individuella årsringar. Baserat på densitetsfördelningen i provet och en mikromekanisk modell så utvecklas en finita element-modell. Den utnyttjas för att beräkna lokala skjuvtöjningar. Jämförelsen mellan beräkningar och uppmätta skjuvtöjningar ger enastående god överensstämmelse. Det visar att den låga skjuvmodulen för gran orsakas av låg densitet i kombination med att böjning av cellväggarna dominerar som deformationsmekanism. Det illustrerar också att vi behöver förbättra vår förståelse för deformationsfält på årsringsnivå. En praktisk konsekvens är t ex att relativt låga globala laster ger upphov till mycket hög lokal skjuvdeformation. / QC 20100830 Wood fibre and forest products Träfiber- och virkeslära Engineering mechanics Teknisk mekanik Biomaterials Biomaterial
462	Understanding the role topographical features play in stimulating the endogenous peripheral nerve regeneration across critically sized nerve gaps Mukhatyar, Vivek 11 November 2011 (has links) Severe traumatic injuries and surgical procedures like tumor resection often create peripheral nerve gaps, accounting for over 250,000 injuries in the US annually. The clinical "gold standard" for bridging peripheral nerve gaps is autografts, with which 40-50% of patients regain useful function. However, issues including their limited availability and collateral damage at the donor site limit the effectiveness and use of autografts. Therefore, it is critical to develop alternative bioengineered approaches that match or exceed autograft performance. With the use of guidance channels, the endogenous regeneration process spontaneously occurs when successful bridging of short gaps (< 10mm) occurs, but fails to occur in the bridging of longer gaps (≥15mm). Several bioengineered strategies are currently being explored to bridge these critical size nerve gaps. Other labs and ours have shown how filler materials that provide topographical cues within the nerve guides are able to enhance nerve growth and bridge critical length gaps in rats. However, the mechanism by which intra-luminal fillers enhance nerve regeneration has not been explored. The main goal of this dissertation was to explore the interplay between intra-luminal scaffolds and orchestrated events of provisional fibrin matrix formation, glial cell infiltration, ECM deposition and remodeling, and axonal infiltration - a sequence we term the 'regenerative' sequence. We hypothesized that the mechanism by which thin films with topographical cues enhance regeneration is by serving as physical 'organizing templates' for Schwann cell infiltration, Schwann cell orientation, extra-cellular matrix deposition/organization and axon infiltration. We demonstrate that aligned topographical cues mediate their effects to the neuronal cells through optimizing fibronectin adsorption in vitro. We also demonstrate that aligned electrospun thin films are able to enhance bridging of a critical length nerve gap in vivo by stabilizing the provisional matrix, creating a pro-inflammatory environment and influencing the maturation of the regenerating cable leading to faster functional recovery compared to smooth films and random fibers. This research will advance our understanding of the mechanisms of peripheral nerve regeneration, and help develops technologies that are likely to improve clinical outcomes after peripheral nerve injury. Biomaterials Neural tissue engineering Topography Regenerative medicine Autotransplantation Autografts Tissue engineering Nervous system Regeneration
463	Synthesis and Characterization of Tissue-engineered Collagen Hydrogels for the Delivery of Therapeutic Cells McEwan, Kimberly A. 12 March 2013 (has links) The expanding field of tissue engineering provides a new approach to regenerative medicine for common ailments such as cardiovascular disease and type-I diabetes. Biomaterials can be administered as a delivery vehicle to introduce therapeutic cells to sites of damaged or diseased tissue. A specific class of biomaterials, termed hydrogels, is suitable for this application as they can provide a biocompatible, biodegradable scaffold that mimics the physical properties of the native soft tissue. Injectable hydrogels are increasingly being developed for biomedical applications due to their ability to be delivered in a minimally invasive manner. One potential use for such materials is in the delivery of therapeutics such as cells or growth factor-releasing particles. In this study, the first aim was to determine the interactive effects between collagen-based hydrogels and additives (cells and microspheres) for cardiac regeneration. The results demonstrated that the addition of either cells or microspheres to a collagen-based hydrogel decreased its gelation time and increased its viscosity. Increased cross-linker concentrations resulted in lower cell viability. However, this cell loss could be minimized by delivering cells with the cross-linker neutralizing agent, glycine. As a potential application of these materials, the second aim of this study was to develop a hydrogel for use as an ectopic islet transplant site. Specifically, collagen-chitosan hydrogels were synthesized and characterized, with and without laminin, and tested for their ability to support angiogenic and islet cell survival and function. Matrices synthesized with lower chitosan content (20:1 collagen:chitosan) displayed greater cell compatibility for both angiogenic cells and for islets and weaker mechanical properties, while matrices with higher chitosan content (10:1 collagen:chitosan) had the opposite effect. Laminin did not affect the physical properties of the matrices, but did improve angiogenic cell and islet survival and function. Overall the proposed collagen-based hydrogels can be tailored to meet the physical property requirements for cardiac and islet tissue engineering applications and demonstrated promising cell support capabilities. biomaterials collagen hydrogels type-I diabetes cardiovascular disease islet cells angiogenic cells
464	Three-Dimensional Biomimetic Patterning to Guide Cellular Migration and Organization Hoffmann, Joe 24 July 2013 (has links) This thesis develops a novel photopatterning strategy for biomimetic scaffolds that enables spatial and biochemical control of engineered cellular architectures, such as the microvasculature. Intricate tools that allow for the three dimensional (3D) manipulation of biomaterial microenvironments will be critical for organizing cellular behavior, directing tissue formation, and ultimately, developing functional therapeutics to treat patients with critical organ failure. Poly(ethylene glycol) (PEG) based hydrogels, which without modification naturally resist protein adsorption and cellular adhesion, were utilized in combination with a two-photon laser patterning approach to covalently immobilize specific biomolecules in custom-designed, three-dimensional (3D) micropatterns. This technique, known as two-photon laser scanning lithography (TP-LSL), was shown in this thesis to possess the capability to micropattern multiple different biomolecules at modular concentrations into a single hydrogel microenvironment over a broad range of size scales with high 3D resolution. 3D cellular adhesion and migration were then explored in detail using time-lapse confocal microscopy to follow cells as they migrated along micropatterned tracks of various 3D size and composition. Further, in a valuable modification of TP-LSL, images from the endogenous microenvironment were converted into instructions to precisely direct the laser patterning of biomolecules within PEG-based hydrogels. 3D images of endogenous microvasculature from various tissues were directly converted into 3D biomolecule patterns within the hydrogel scaffold with precise pattern fidelity. While tissue engineers have previously demonstrated the formation of vessels through the encapsulation of endothelial cells and pericyte precursor cells within PEG-based hydrogels, the vessel structure had been random, uncoordinated, and therefore, ultimately non-functional. This thesis has utilized image guided TP-LSL to pattern biomolecules into a 3D structure that directs the organization of vessels to mimic that of the endogenous tissue vasculature. TP-LSL now stands as a valuable tool to control the microstructure of engineered cellular architectures, thereby providing a critical step in the development of cellularized scaffolds into functional tissues. Ultimately, this thesis develops new technologies that advance the field of regenerative medicine towards the goal of engineering viable organs to therapeutically treat the 18 patients who die every day waiting on the organ transplant list. Tissue Engineering Hydrogel Biomaterials Two-photon photolithography Microvasculature Poly(ethylene glycol)
465	Developing Novel Protein-based Materials using Ultrabithorax: Production, Characterization, and Functionalization January 2011 (has links) Compared to 'conventional' materials made from metal, glass, or ceramics, protein-based materials have unique mechanical properties. Furthermore, the morphology, mechanical properties, and functionality of protein-based materials may be optimized via sequence engineering for use in a variety of applications, including textile materials, biosensors, and tissue engineering scaffolds. The development of recombinant DNA technology has enabled the production and engineering of protein-based materials ex vivo . However, harsh production conditions can compromise the mechanical properties of protein-based materials and diminish their ability to incorporate functional proteins. Developing a new generation of protein-based materials is crucial to (i) improve materials assembly conditions, (ii) create novel mechanical properties, and (iii) expand the capacity to carry functional protein/peptide sequences. This thesis describes development of novel protein-based materials using Ultrabithorax, a member of the Hox family of proteins that regulate developmental pathways in Drosophila melanogaster . The experiments presented (i) establish the conditions required for the assembly of Ubx-based materials, (ii) generate a wide range of Ubx morphologies, (iii) examine the mechanical properties of Ubx fibers, (iv) incorporate protein functions to Ubx-based materials via gene fusion, (v) pattern protein functions within the Ubx materials, and (vi) examine the biocompatibility of Ubx materials in vitro . Ubx-based materials assemble at mild conditions compatible with protein folding and activity, which enables Ubx chimeric materials to retain the function of appended proteins in spatial patterns determined by materials assembly. Ubx-based materials also display mechanical properties comparable to existing protein-based materials and demonstrate good biocompatibility with living cells in vitro . Taken together, this research demonstrates the unique features and future potential of novel Ubx-based materials. Applied sciences Pure sciences Biological sciences Ultrabithorax Spaital patterning Self-assembly Biomaterials Biochemistry Nanotechnology Biophysics
466	Development of a Thermoresponsive and Chemically Crosslinkable Hydrogel System for Craniofacial Bone Tissue Engineering January 2011 (has links) A novel injectable hydrogel system for cell delivery in craniofacial bone tissue engineering was developed in this work. The hydrogel employs a dual solidification mechanism by containing units that gel upon temperature increase to physiological temperature and groups that allow for covalent crosslinking. The successful synthesis of macromers for hydrogel fabrication was demonstrated and structure-property relations were established. The hydrophilic-hydrophobic balance of the macromers was found to be an important design criterion towards their resulting thermal gelation properties. When tested with cells in vitro , macromers with different molecular compositions, molecular weights and transition temperatures were all found to be cytocompatible. The introduction of a chemically crosslinkable group in the macromers resulted in hydrogels with improved stability. The effect of the addition of these highly reactive groups on cell viability was evaluated and parameters that enable viable cell encapsulation in the hydrogels were determined. It was shown that there was a dose- and time-dependent effect of the macromers on cell viability. Increased degrees of modification were found to decrease the thermal transition temperature as well as the cytocompatibility of the macromers. Hydrogels were fabricated at physiological temperature upon physical gelation and chemical crosslinking with the addition of a thermal free radical initiator system. The swelling behavior of the hydrogels was characterized and it was found to be controlled by the chemistry of the macromer end group, the concentration of the initiator system used, the fabrication interval as well as the incubation temperature and medium. In order to evaluate the hydrogels as cell carriers, mesenchymal stems cells were encapsulated in the hydrogels over a 21-day period. Cells retained their viability over the duration of the study and exhibited markers of osteogenic differentiation when cultured with appropriate supplements. These findings hold promise for the use of these hydrogel systems for cell encapsulation in tissue engineering applications. Applied sciences Thermoresponsive Tissue engineering Biomaterials Hydrogels Cell encapsulation Craniofacial bone Biomedical engineering
467	Osteoblast Behaviour on Injectable Biomaterials Intended for Augmentation of Vertebral Compression Fractures Ramstedt, Sandra January 2007 (has links) Biomaterials used for stabilization of compressed vertebraes due to osteoporosis, have mainly been based on resin materials, like PMMA (polymethyl methacrylate), but have recently expanded to consist of injectable ceramics, such as calcium-aluminate. In this in vitro study human osteoblast-like cells, MG-63, were cultured on three different injectable biomaterials based on: Ca-aluminate, Bis-GMA (bisphenol A-glycidylmethacrylate) and PMMA, to investigate the cellular response elicited by these materials. Cell proliferation was measured by the NucleoCounter® system, cell viability was investigated by LDH (lactate dehydrogenase) analysis, cell differentiation and mineralization was evaluated by mRNA gene expression of the osteoblastic markers: ALP (alkaline phosphatase), OC (osteocalcin) and COLL-I (collagen type I) by qPCR (quantitative polymerase chain reaction) analysis. Two control materials were used: TCP (tissue culture polystyrene, negative control) and PVC (polyvinyl chloride, positive control). The results showed that all the bone cement materials were non-toxic and biocompatible, i.e. they provided good cell viability and proliferation of the MG-63 cells. They are specific for bone cells, since they expressed high values of the osteoblast-specific differentiation markers, and are thus promising as injectable bone cement materials. Among the bone cements, Xeraspine appears to be the most biocompatible material for bone cells. It is followed by Cortoss and then Vertebroplastic. vertebral compression fractures osteoblasts injectable biomaterials Ca-aluminate Bis-GMA PMMA cell studies TECHNOLOGY TEKNIKVETENSKAP
468	Biomimetic Composite Scaffolds for the Functional Tissue Engineering of Articular Cartilage Moutos, Franklin Thomas January 2009 (has links) <p>Articular cartilage is the connective tissue that lines the ends of long bones in diarthrodial joints, providing a low-friction load-bearing surface that can withstand a lifetime of loading cycles under normal conditions. Despite these unique and advantageous properties, the tissue possesses a limited capacity for self-repair due to its lack of vasculature and innervation. Total joint replacement is a well-established treatment for degenerative joint disease; however, the materials used in these procedures have a limited lifespan in vivo and will likely fail over time, requiring additional - and increasingly complicated - revision surgeries. For younger or more active patients, this risk is unacceptable. Unfortunately, alternative surgical options are not currently available, leaving pain management as the only viable treatment. In seeking to discover a new therapeutic strategy, the goal of this dissertation was to develop a functional tissue-engineered cartilage construct that may be used to resurface an entire diseased or damaged joint.</p><p> A three-dimensional (3-D) woven textile structure, produced on a custom-built miniature weaving loom, was utilized as the basis for producing novel composite scaffolds and cartilage tissue constructs that exhibited initial properties similar to those of native articular cartilage. Using polyglycolic acid (PGA) fibers combined with chondrocyte-loaded agarose or fibrin hydrogels, scaffolds were engineered with anisotropic, inhomogeneous, viscoelastic, and nonlinear characteristics prior to cultivation. However, PGA-based constructs showed a rapid loss of mechanical functionality over a 28 day culture period suggesting that the inclusion of other, less degradable, biomaterial fibers could provide more stable properties. </p><p> Retaining the original 3-D architecture and fiber/hydrogel composite construction, poly (epsilon-caprolactone) (PCL)-based scaffolds demonstrated initial biomechanical properties similar to those of PGA-based scaffolds. Long-term culture of 3-D PCL/fibrin scaffolds seeded with human adipose-derived stem cells (ASCs) showed that scaffolds maintained their baseline properties as new, collagen-rich tissue accumulated within the constructs.</p><p> In an attempt to improve the bioactivity of the PCL scaffold and further induce chondrogenic differentiation of seeded ASCs, we produced a hybrid scaffold system by embedding the 3-D woven structure within a porous matrix derived from native cartilage. We then demonstrated how this multifunctional scaffold could be molded, seeded, and cultured in order to produce an anatomically accurate tissue construct with potential for resurfacing the femoral head of a hip. </p><p>In summary, these findings provide valuable insight into a new approach for the functional tissue engineering of articular cartilage. The results of this work will hopefully lead to the discovery of new strategies for the long-term treatment of cartilage pathology.</p> / Dissertation Engineering, Biomedical adipose stem cells biomaterials composite scaffolds textile tissue engineering
469	Affinity-Modulation Drug Delivery Using Thermosensitive Elastin-Like Polypeptide Block Copolymers Simnick, Andrew Joseph January 2010 (has links) <p>Antivascular targeting is a promising strategy for tumor therapy. This strategy overcomes many of the transport barriers and has shown efficacy in many preclinical models, but targeting epitopes on tumor vasculature can also promote accumulation in healthy tissues. We used Elastin-like Polypeptide (ELP) to form block copolymers (BCs) consisting of two separate ELP blocks seamlessly fused at the genetic level. ELPBCs self-assemble into spherical micelles at a critical micelle temperature (CMT), allowing external control over monovalent unimer and multivalent micelle forms. We hypothesized that thermal self-assembly could trigger specific binding of ligand-ELPBC to target receptors via the multivalency effect as a method to spatially restrict high-avidity interactions. We termed this approach Dynamic Affinity Modulation (DAM). The objectives of this study were to design, identify, and evaluate protein-based drug carriers that specifically bind to target receptors through static or dynamic multivalent ligand presentation.</p> <p>ELPBCs were modified to include a low-affinity GRGDS or GNGRG ligand and a unique conjugation site for hydrophobic compounds. This addition did not disrupt micelle self-assembly and facilitated thermally-controlled multivalency. The ability of ligand-ELPBC to specifically interact with isolated AvB3 or CD13 was tested using an in vitro binding assay incorporating an engineered cell line. RGD-ELPBC promoted specific receptor binding in response to multivalent presentation but NGR-ELPBC did not. Enhanced binding with multivalent presentation was also observed only with constructs exhibiting CMT < body temperature. This study establishes proof-of-principle of DAM, but ELPBC requires thermal optimization for use with applied hyperthermia. Static affinity targeting of fluorescent ligand-ELPBC was then analyzed in vivo using intravital microscopy (IM), immunohistochemistry (IHC), and custom image processing algorithms. IM showed increased accumulation of NGR-ELPBC in tumor tissue relative to normal tissue while RGD-ELPBC and non-ligand ELPBC did not, and IHC verified these observations. This study shows (1) multivalent NGR presentation is suitable for static multivalent targeting of tumors and tumor vasculature, (2) multivalent RGD presentation may be suitable for DAM with thermal optimization, and (3) ELPBC micelles may selectively target proteins at the tumor margin.</p> / Dissertation Engineering, Biomedical Engineering, Materials Science Biology, Molecular Biomaterials Block Copolymers Cancer Drug Delivery Multivalency Vascular Targeting
470	Assembly and dynamic behavior of microgel thin films and their application to biointerfacees South, Antoinette Bonhivert 20 May 2010 (has links) Hydrogels, which are polymeric cross-linked networks that swell in aqueous environments, are versatile materials that can contain a variety of chemical functionalities, mechanical properties, and topographical features. Microgels are the stable colloidal form of hydrogel materials that range in size from approximately 100 nm to a few microns in diameter. While they also can exhibit similar properties to those of macrogels, microgels can be used as building blocks in a bottom-up approach to assemble films of higher complexity. In this dissertation, work is focused on understanding the assembly and behavior of microgel thin films as non-fouling surfaces, centrifugally deposited materials, self-healing coatings, and degradable constructs. Non-fouling films were assembled using PEG cross-linked microgels to reduce non-specific protein adsorption and mitigate cellular adhesion. These constructs were assembled in a polyelectrolyte multi-layered fashion, of alternating anionic microgels and cationic linear polymer, to effectively block the substrate from the biological environment and consequently exhibited control over cellular adhesion with the surface. The utility and application of these non-fouling microgel coatings on functional implants was also explored. Centrifugal deposition was used to rapidly generate non-fouling microgel multi-layered interfaces on planar surfaces, and upon closer inspection of the microgel monolayers, it was found that the centrifugally deposited films contained closer-packed microgel assemblies with microgels of smaller footprint size, compared to microgels that are passively adsorbed to the surface. Microgels that are centrifugally deposited may adopt a higher energy chain conformation than passively adsorbed microgels, and this higher energy chain conformation may translate into the multi-layered materials. Nonetheless, the centrifugally deposited non-fouling microgel multi-layered films were found to effectively block macrophage adhesion. Films were also assembled in a polyelectrolyte fashion on soft substrates, and were observed to become significantly damaged under mechanical manipulation (poking, bending, or stretching), but then self-heal upon addition of water. By altering the building blocks of the polyelectrolyte multi-layered films, such as the molecular weight of the polycation between microgel layers or by using anionic rigid spheres as the particle in the assembly, changes in the observed film damage suggest that particle-linear polymer interpenetration and polyvalency likely play an important role in the strength and integrity of the microgel thin films. Fluorescently-labeled microgels were also used to interrogate how the films reorganize in the lateral direction, and these early studies suggest that the microgel multi-layered films reorganize when damaged and also possibly when they are undamaged and simply incubated in an aqueous environment. Additional studies were also conducted on microgels synthesized with a hydrolyzable cross-linker, and by supporting these degradable constructs on substrates, detailed single-particle morphological changes during erosion could be interrogated in complex media such as serum. This work, as a collection, demonstrates the ability to obtain information about microgel thin film assemblies and their behavior using microscopy techniques such as ambient and in liquid atomic force microscopy, brightfield optical microscopy, and fluorescence microscopy. The observations made here illustrate how microgels can be used to fabrication thin films that can be utilized in biological applications (non-fouling, self-healing, and erodable constructs), and how different deposition methods (centrifugal deposition and polyelectrolyte multi-layers) can dictate their behavior. Biomaterials Film assembly Colloids Thin films Biomedical materials Colloids in medicine Centrifugation

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