898 resultados para 3D scaffold
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Nell’area dell’ingegneria tissutale si sta affermando una nuova tecnica che consiste nell’utilizzo di scaffold per la rigenerazione dell’apparato renale. Nella presente tesi, dopo un’introduzione fatta sulle terapie per la sostituzione renale, sono state analizzate le tecniche, le caratteristiche e presentati i risultati finora raggiunti nella decellularizzazione e ricellularizzazione di scaffold renali.
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This dissertation describes the technical further development of the microclimate simulation ENVI-met in the years from 2007 to 2010 and shows examples of how ENVI-met can help solve typical microclimatic questions within an urban environment.
Towards the 3D attenuation imaging of active volcanoes: methods and tests on real and simulated data
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The purpose of my PhD thesis has been to face the issue of retrieving a three dimensional attenuation model in volcanic areas. To this purpose, I first elaborated a robust strategy for the analysis of seismic data. This was done by performing several synthetic tests to assess the applicability of spectral ratio method to our purposes. The results of the tests allowed us to conclude that: 1) spectral ratio method gives reliable differential attenuation (dt*) measurements in smooth velocity models; 2) short signal time window has to be chosen to perform spectral analysis; 3) the frequency range over which to compute spectral ratios greatly affects dt* measurements. Furthermore, a refined approach for the application of spectral ratio method has been developed and tested. Through this procedure, the effects caused by heterogeneities of propagation medium on the seismic signals may be removed. The tested data analysis technique was applied to the real active seismic SERAPIS database. It provided a dataset of dt* measurements which was used to obtain a three dimensional attenuation model of the shallowest part of Campi Flegrei caldera. Then, a linearized, iterative, damped attenuation tomography technique has been tested and applied to the selected dataset. The tomography, with a resolution of 0.5 km in the horizontal directions and 0.25 km in the vertical direction, allowed to image important features in the off-shore part of Campi Flegrei caldera. High QP bodies are immersed in a high attenuation body (Qp=30). The latter is well correlated with low Vp and high Vp/Vs values and it is interpreted as a saturated marine and volcanic sediments layer. High Qp anomalies, instead, are interpreted as the effects either of cooled lava bodies or of a CO2 reservoir. A pseudo-circular high Qp anomaly was detected and interpreted as the buried rim of NYT caldera.
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This work illustrates a soil-tunnel-structure interaction study performed by an integrated,geotechnical and structural,approach based on 3D finite element analyses and validated against experimental observations.The study aims at analysing the response of reinforced concrete framed buildings on discrete foundations in interaction with metro lines.It refers to the case of the twin tunnels of the Milan (Italy) metro line 5,recently built in coarse grained materials using EPB machines,for which subsidence measurements collected along ground and building sections during tunnelling were available.Settlements measured under freefield conditions are firstly back interpreted using Gaussian empirical predictions. Then,the in situ measurements’ analysis is extended to include the evolving response of a 9 storey reinforced concrete building while being undercrossed by the metro line.In the finite element study,the soil mechanical behaviour is described using an advanced constitutive model. This latter,when combined with a proper simulation of the excavation process, proves to realistically reproduce the subsidence profiles under free field conditions and to capture the interaction phenomena occurring between the twin tunnels during the excavation. Furthermore, when the numerical model is extended to include the building, schematised in a detailed manner, the results are in good agreement with the monitoring data for different stages of the twin tunnelling. Thus, they indirectly confirm the satisfactory performance of the adopted numerical approach which also allows a direct evaluation of the structural response as an outcome of the analysis. Further analyses are also carried out modelling the building with different levels of detail. The results highlight that, in this case, the simplified approach based on the equivalent plate schematisation is inadequate to capture the real tunnelling induced displacement field. The overall behaviour of the system proves to be mainly influenced by the buried portion of the building which plays an essential role in the interaction mechanism, due to its high stiffness.
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Die vorliegende Arbeit beschäftigt sich mit der Darstellung zweikerniger Koordinationsverbindungen, bei denen zweiwertige Ionen der 3d-Übergangsmetalle über einen bestimmten Liganden verbrückt sind. Dieser Brückenligand, das N,N,N‘,N‘-Tetrakis-(2-methylpyridyl)-benzol-1,4-diamin (TPBD), besteht aus einem p-Phenylendiamin-Gerüst, an dessen Stickstoffe je zwei Methylpyridin-Gruppen gebunden sind. In diesen zwei jeweils dreizähnigen Bindungstaschen wurden 3d-Übergangsmetallionen komplexiert, wobei deren Koordinationssphäre mit einem zweizähnigen capping-Liganden vom Typ des 1,10-Phenanthrolins und einem einzähnigen dritten Liganden abgesättigt wird. Die strukturellen, magnetischen und elektronischen Eigenschaften der so erhaltenen homometallischen Komplexe mit Mn(II), Fe(II), Co(II), Ni(II), Cu(II) und Zn(II) wurden untersucht. Dabei wurde besonderes Augenmerk auf die Veränderung dieser Eigenschaften bei dem Einsatz unterschiedlicher capping- und dritter Liganden gerichtet. Die schwach antiferromagnetische Wechselwirkung der metallzentrierten Spins über den Brückenliganden führt dabei stets zu einem diamagnetischen Grundzustand, was diese als mögliche Einzelmolekülmagnete ausschließt. Mit der Oxidierbarkeit des Liganden zu seiner radikalischen Spezies besteht die Möglichkeit, einen zusätzlichen Spin in dem System zu erzeugen, woraus ein Spingrundzustand von ungleich null resultiert. Es zeigte sich, dass die Lebensdauer der radikalischen Spezies eine starke Abhängigkeit sowohl von den eingesetzten Metallionen als auch den weiteren Liganden besitzt. Auch vier Derivate des ursprünglichen Brückenliganden konnten synthetisiert und deren Oxidierbarkeit zu den entsprechenden Radikalformen gezeigt werden. Neben der Darstellung homometallischer Komplexe gelang zudem die Synthese und Strukturaufklärung dreier heterometallischer zweikerniger Komplexe mit Mn(II), Co(II) und Ni(II) als Metallionen. Es konnte gezeigt werden, dass diese auch ohne die Oxidation des Brückenliganden bei schwacher antiferromagnetischer Wechselwirkung der Spins einen paramagnetischen Spingrundzustand besitzen.
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In order to reduce the costs of crystalline silicon solar cells, low-cost silicon materials like upgraded metallurgical grade (UMG) silicon are investigated for the application in the photovoltaic (PV) industry. Conventional high-purity silicon is made by cost-intensive methods, based on the so-called Siemens process, which uses the reaction to form chlorosilanes and subsequent several distillation steps before the deposition of high-purity silicon on slim high-purity silicon rods. UMG silicon in contrast is gained from metallurgical silicon by a rather inexpensive physicochemical purification (e.g., acid leaching and/or segregation). However, this type of silicon usually contains much higher concentrations of impurities, especially 3d transition metals like Ti, Fe, and Cu. These metals are extremely detrimental in the electrically active part of silicon solar cells, as they form recombination centers for charge carriers in the silicon band gap. This is why simple purification techniques like gettering, which can be applied between or during solar cell process steps, will play an important role for such low-cost silicon materials. Gettering in general describes a process, whereby impurities are moved to a place or turned into a state, where they are less detrimental to the solar cell. Hydrogen chloride (HCl) gas gettering in particular is a promising simple and cheap gettering technique, which is based on the reaction of HCl gas with transition metals to form volatile metal chloride species at high temperatures.rnThe aim of this thesis was to find the optimum process parameters for HCl gas gettering of 3d transition metals in low-cost silicon to improve the cell efficiency of solar cells for two different cell concepts, the standard wafer cell concept and the epitaxial wafer equivalent (EpiWE) cell concept. Whereas the former is based on a wafer which is the electrically active part of the solar cell, the latter uses an electrically inactive low-cost silicon substrate with an active layer of epitaxially grown silicon on top. Low-cost silicon materials with different impurity grades were used for HCl gas gettering experiments with the variation of process parameters like the temperature, the gettering time, and the HCl gas concentration. Subsequently, the multicrystalline silicon neighboring wafers with and without gettering were compared by element analysis techniques like neutron activation analysis (NAA). It was demonstrated that HCl gas gettering is an effective purification technique for silicon wafers, which is able to reduce some 3d transition metal concentrations by over 90%. Solar cells were processed for both concepts which could demonstrate a significant increase of the solar cell efficiency by HCl gas gettering. The efficiency of EpiWE cells could be increased by HCl gas gettering by approximately 25% relative to cells without gettering. First process simulations were performed based on a simple model for HCl gas gettering processes, which could be used to make qualitative predictions.
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Viene proposto un porting su piattaforma mobile Android di un sistema SLAM (Simultaneous Localization And Mapping) chiamato SlamDunk. Il porting affronta problematiche di prestazioni e qualità delle ricostruzioni 3D ottenute, proponendo poi la soluzione ritenuta ottimale.
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Traditional cell culture models have limitations in extrapolating functional mechanisms that underlie strategies of microbial virulence. Indeed during the infection the pathogens adapt to different tissue-specific environmental factors. The development of in vitro models resembling human tissue physiology might allow the replacement of inaccurate or aberrant animal models. Three-dimensional (3D) cell culture systems are more reliable and more predictive models that can be used for the meaningful dissection of host–pathogen interactions. The lung and gut mucosae often represent the first site of exposure to pathogens and provide a physical barrier against their entry. Within this context, the tracheobronchial and small intestine tract were modelled by tissue engineering approach. The main work was focused on the development and the extensive characterization of a human organotypic airway model, based on a mechanically supported co-culture of normal primary cells. The regained morphological features, the retrieved environmental factors and the presence of specific epithelial subsets resembled the native tissue organization. In addition, the respiratory model enabled the modular insertion of interesting cell types, such as innate immune cells or multipotent stromal cells, showing a functional ability to release pertinent cytokines differentially. Furthermore this model responded imitating known events occurring during the infection by Non-typeable H. influenzae. Epithelial organoid models, mimicking the small intestine tract, were used for a different explorative analysis of tissue-toxicity. Further experiments led to detection of a cell population targeted by C. difficile Toxin A and suggested a role in the impairment of the epithelial homeostasis by the bacterial virulence machinery. The described cell-centered strategy can afford critical insights in the evaluation of the host defence and pathogenic mechanisms. The application of these two models may provide an informing step that more coherently defines relevant molecular interactions happening during the infection.
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Until few years ago, 3D modelling was a topic confined into a professional environment. Nowadays technological innovations, the 3D printer among all, have attracted novice users to this application field. This sudden breakthrough was not supported by adequate software solutions. The 3D editing tools currently available do not assist the non-expert user during the various stages of generation, interaction and manipulation of 3D virtual models. This is mainly due to the current paradigm that is largely supported by two-dimensional input/output devices and strongly affected by obvious geometrical constraints. We have identified three main phases that characterize the creation and management of 3D virtual models. We investigated these directions evaluating and simplifying the classic editing techniques in order to propose more natural and intuitive tools in a pure 3D modelling environment. In particular, we focused on freehand sketch-based modelling to create 3D virtual models, interaction and navigation in a 3D modelling environment and advanced editing tools for free-form deformation and objects composition. To pursuing these goals we wondered how new gesture-based interaction technologies can be successfully employed in a 3D modelling environments, how we could improve the depth perception and the interaction in 3D environments and which operations could be developed to simplify the classical virtual models editing paradigm. Our main aims were to propose a set of solutions with which a common user can realize an idea in a 3D virtual model, drawing in the air just as he would on paper. Moreover, we tried to use gestures and mid-air movements to explore and interact in 3D virtual environment, and we studied simple and effective 3D form transformations. The work was carried out adopting the discrete representation of the models, thanks to its intuitiveness, but especially because it is full of open challenges.
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This thesis work deals, principally, with the development of different chemical protocols ranging from environmental sustainability peptide synthesis to asymmetric synthesis of modified tryptophans to a series of straightforward procedures for constraining peptide backbones without the need for a pre-formed scaffold. Much efforts have been dedicated to the structural analysis in a biomimetic environment, fundamental for predicting the in vivo conformation of compounds, as well as for giving a rationale to the experimentally determined bioactivity. The conformational analyses in solution has been done mostly by NMR (2D gCosy, Roesy, VT, titration experiments, molecular dynamics, etc.), FT-IR and ECD spectroscopy. As a practical application, 3D rigid scaffolds have been employed for the synthesis of biological active compounds based on peptidomimetic and retro-mimetic structures. These mimics have been investigated for their potential as antiflammatory agents and actually the results obtained are very promising. Moreover, the synthesis of Amo ring permitted the development of an alternative high effective synthetic pathway for obtaining Linezolid antibiotic. The final section is, instead, dedicated to the construction of a new biosensor based on zeolite L SAMs functionalized with the integrin ligand c[RGDfK], that has showed high efficiency for the selective detection of tumor cells. Such kind of sensor could, in fact, enable the convenient, non-invasive detection and diagnosis of cancer in early stages, from a few drops of a patient's blood or other biological fluids. In conclusion, the researches described herein demonstrate that the peptidomimetic approach to 3D definite structures, allows unambiguous investigation of the structure-activity relationships, giving an access to a wide range bioactive compounds of pharmaceutical interest to use not only as potential drugs but also for diagnostic and theranostic applications.
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La presente tesi ha riguardato lo studio numerico con un modello 3D dell' interazione tra lo scavo di una galleria urbana e un edificio esistente in muratura, la Stazione di Ferrara Porta Reno (risalente ai primi del '900). A tale scopo è stato utilizzato il programma di calcolo agli elementi finiti Plaxis 3D. Nello studio numerico, per il terreno è stato adottato un modello costitutivo avanzato elasto-plastico con incrudimento isotropo, l’Hardening soil model with small strain stiffness, mentre per la muratura e stato utilizzato il criterio di Mohr-Coulomb. Inoltre, lo scavo della galleria è stato simulato con una procedura per passi, tenendo in conto i principali aspetti del processo. La subsidenza in superficie è stata controllata applicando una contrazione fittizia lungo lo scudo. E’ stata svolta un'analisi numerica in condizione di campo libero, ossia in assenza di strutture, al fine di valutare i movimenti del terreno indotti dal processo di scavo; successivamente sono state eseguite diverse analisi accoppiate, in condizioni di simmetria e con eccentricità della costruzione rispetto all'asse della galleria, per studiare il complesso fenomeno di interazione galleria-terreno-struttura. I risultati di tali analisi accoppiate sono stati utilizzati per effettuare una stima del livello di danno atteso per l'edificio. Le analisi numeriche condotte hanno messo in luce, confermando quanto già noto in letteratura, che la presenza di un edificio a piano campagna interagente con l’opera di scavo modifica la forma del profilo dei cedimenti relativa alle condizioni di campo libero. Tale modifica, che dipende dalle specifiche caratteristiche di rigidezza e peso della struttura presa in esame, generalmente si traduce in una riduzione del cedimento differenziale che può influenzare in modo significativo la stima del danno sull’edificio. Ciò è tanto più evidente, quanto maggiore è la perdita di volume indotta dallo scavo della galleria.
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The kinematics is a fundamental tool to infer the dynamical structure of galaxies and to understand their formation and evolution. Spectroscopic observations of gas emission lines are often used to derive rotation curves and velocity dispersions. It is however difficult to disentangle these two quantities in low spatial-resolution data because of beam smearing. In this thesis, we present 3D-Barolo, a new software to derive the gas kinematics of disk galaxies from emission-line data-cubes. The code builds tilted-ring models in the 3D observational space and compares them with the actual data-cubes. 3D-Barolo works with data at a wide range of spatial resolutions without being affected by instrumental biases. We use 3D-Barolo to derive rotation curves and velocity dispersions of several galaxies in both the local and the high-redshift Universe. We run our code on HI observations of nearby galaxies and we compare our results with 2D traditional approaches. We show that a 3D approach to the derivation of the gas kinematics has to be preferred to a 2D approach whenever a galaxy is resolved with less than about 20 elements across the disk. We moreover analyze a sample of galaxies at z~1, observed in the H-alpha line with the KMOS/VLT spectrograph. Our 3D modeling reveals that the kinematics of these high-z systems is comparable to that of local disk galaxies, with steeply-rising rotation curves followed by a flat part and H-alpha velocity dispersions of 15-40 km/s over the whole disks. This evidence suggests that disk galaxies were already fully settled about 7-8 billion years ago. In summary, 3D-Barolo is a powerful and robust tool to separate physical and instrumental effects and to derive a reliable kinematics. The analysis of large samples of galaxies at different redshifts with 3D-Barolo will provide new insights on how galaxies assemble and evolve throughout cosmic time.
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Questa tesi compilativa prende in esame la cartilagine, partendo dalla composizione dei suoi diversi tipi rappresentati nel corpo umano e delle funzioni qui svolte, per descrivere i metodi utilizzati per riprodurla artificialmente mediante cellule staminali, fattori di crescita e scaffold dedicati coltivati in ambiente controllato. La cartilagine è un tessuto molto particolare perché, diversamente dagli altri tessuti, non possiede una rete di capillari e quindi riceve un limitati apporto di ossigeno e sostanze nutritive, che spiega la sua poverissima capacità intrinseca di riparazione. La cartilagine è però un tessuto soggetto a numerosi stress di vario tipo e quindi è soggetta a traumi che possono essere di natura sportiva o accidentale (soprattutto la cartilagine di tipo articolare) ed è anche colpita da malattie degenerative. Questo ha stimolato gli studi che intendono ingegnerizzare un tessuto artificiale in grado di aumentare la capacità di riparare la zona colpita. In quest’ottica, vengono attivamente condotti esperimenti in grado di definire protocolli che inducano cellule staminali al differenziamento in cellule di tipo cartilagineo. Tali cellule, seminate su supporti (scaffolds) 3D biocompatibili di diversa natura, naturali o sintetici, eventualmente bioattivi, possono essere coltivate in ambienti dedicati, detti bioreattori, che utilizzino stimoli fisici (p. es. vibrazionali, microgravità, ultrasonici, regolazione della tensione di ossigeno, sforzi di taglio, compressione dinamica e compressione idrostatica ciclica) che si sono dimostrati utili per indurre l’appropriato fenotipo cellulare, valutabile attraverso una batteria di approcci di misura morfologica e funzionale.
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Die Transmissionselektronenmikroskopie gepaart mit bioinformatischen Methoden zur digitalen Bildverarbeitung ist ein schneller Weg zur Erstellung dreidimensionaler Rekonstruktionen großer Proteinkomplexe. Durch die Kombination der 3D-Elektronenmikroskopie mit der Röntgenstruktur von Untereinheiten erhält man ein pseudoatomares Modell der Quartärstruktur.rnIn dieser Arbeit wurden auf diese Weise die Quartärstrukturen von drei unterschiedlichen respiratorischen Proteinen analysiert (einem Hämoglobin und zwei Hämocyaninen). Zudem wurden spezielle Software-Tools entwickelt, um vorhandene Softwarepakete besser miteinander kombinieren zu können.rnDie ca. 15Å 3D-Rekonstruktion des Hämoglobins vom Wasserfloh Daphnia pulex klärt die umstrittene Frage, wie viele Untereinheiten die Quartärstruktur aufbauen: Es sind 16 (mit je zwei Häm-Domänen), angeordnet in zwei Schichten als D4-symmetrisches Sandwich. Die ca. 15 Å 3D-Rekonstruktion des 2x6meren Hämocyanins des Flusskrebses Astacus leptodactylus gibt neue Einblicke in die Kontaktstelle zwischen den beiden Hexameren; sie liegt im Bereich der Domäne 3. Bei dem aus 48 Untereinheiten bestehenden Hämocyanin des Pfeilschwanzes Limulus polyphemus wurde eine Auflösung von ca. 7 Å erreicht. Die Homologiemodelle der Untereinheiten wurden flexibel gefittet. An einer der Kontaktstellen zwischen den beiden Halbmolekülen wurden Molekulardynamik (MD)-Simulationen durchgeführt, um mehr über die Art der chemischen Bindung an dieser Kontaktstelle zu erfahren.rnSpeziell für die Kombination von 3D-Elektronenmikroskopie und MD-Simulation wurden verschiedene bioinformatische Werkzeuge und eine leicht zu erweiternde universelle grafische Benutzeroberfläche (GUI) entwickelt.
