Global ETD Search

211	Materials and microfabrication approaches for completely biodegradable wireless micromachined sensors Luo, Mengdi 12 January 2015 (has links) Implantable sensors have been extensively investigated to facilitate diagnosis or to provide a means to generated closed loop control of therapy by yielding in vivo measurements of physical and chemical signals. Biodegradable sensors which degrade gradually after they are no longer functionally needed exhibit great potential in acute or shorter-term medical diagnostic and sensing applications due to the advantages of (a) exclusion of the need to a secondary surgery for sensor removal, and (b) reduction of the risk of long-term infection. The objective of this research is to design and characterize microfabricated RF wireless pressure sensors that are made of completely biodegradable materials and degrade at time-controlled manner (in the order of years and months). This was achieved by means of investigation of appropriate biodegradable materials and development of appropriate fabrication processes for these non-standard (Microelectromechanical systems) MEMS materials. Four subareas of research are performed: (1) Design of sensors that operate wirelessly and are made of biodegradable materials. The structure of the wireless sensor consists a very compact and relatively simple design of passive LC resonant circuits embedded in a polymer dielectric package. To design the sensor with a particular resonant frequency range, an electromagnetic model of the sensor and a mechanical model for circular plate are developed. The geometry of the sensor is established based on the analytical and finite element simulations results. (2) Investigation of the biodegradable materials in the application of implantable biodegradable wireless sensors to achieve controllable degradation lifetimes. Commercially available and FDA approved biodegradable polymers poly(L-lactic acid) (PLLA) and a "shell-core" structure of poly(lactic-co-glycolic acid) (PLGA) and polyvinyl alcohol (PVA) are utilized as the dielectric package for slow and rapid degradation sensors, respectively. Biodegradable metallic zinc and zinc/iron couples are chosen as conductor materials. The degradation behavior of Zn and Zn/Fe-couple are investigated in vitro. (3) Development of novel fabrication processes. The process exploit the advantages of MEMS technology in fabricating miniaturized devices, while protecting vulnerable biodegradable materials from the strong and/or hazardous chemicals that are commonly used in conventional MEMS fabrication process. These new processes enable the fabrication of biocompatible and biodegradable 3-D devices with embedded, near-hermetic cavities. (4) Testing the pressure response functionality and studying the degradation behavior of the wireless biodegradable pressure sensors. Both PLLA-based and PLGA/PVA-based sensors are characterized in vitro by being immersed in 0.9% saline for prolonged time. All the sensors exhibit three stages of behavior in vitro: equilibration, functional lifetime, and performance degradation. During the functional lifetime, most sensors exhibit fully stable functionality. The PLLA-based sensors show no significant weight loss within 8 month and are expected to fully degrade after 2 years, while the PLGA/PVA-based sensors can degrade completely within 26 days. MEMS Biodegradable sensors Wireless passive sensors RF pressure sensors Galvanic corrosion Poly(lactic acid) Poly(lactic-co-glycolic acid) In vitro degradation
212	3D Printing and Characterization of PLA Scaffolds for Layer-by-Layer BioAssembly in Tissue Engineering / Impression 3D et Caractérisation des Scaffolds en PLA pour Assemblage Couche par Couche en Ingénierie Tissulaire Guduric, Vera 13 December 2017 (has links) L’Ingénierie tissulaire (IT) est un domaine interdisciplinaire qui applique les principes de l'ingénierie et des sciences de la vie au développement de substituts biologiques afin de restaurer, maintenir ou améliorer la fonction tissulaire. Sa première application consiste à remplacer les tissus endommagés par des produits cellulaires artificiels. Une autre application de l’IT est basée sur la production des modèles en 2 et 3 dimensions (2D et 3D) pour des études biologiques et pharmacologiques in vitro. Ces modèles ou remplacements de tissus peuvent être fabriqués en utilisant des différentes méthodes de médecine, biologie, chimie, physique, informatique et mécanique, fournissant un micro-environnement spécifique avec différents types de cellules, facteurs de croissance et matrice. L'un des principaux défis de l'IT la pénétration cellulaire limitée dans les parties internes des biomatériaux poreux. Une faible viabilité cellulaire au centre du produit d'IT est la conséquence de la diffusion limitée d'oxygène et de nutriments du fait d’un réseau vasculaire insuffisant dans l'ensemble de la construction 3D. Le BioAssembage couche-par-couche est une nouvelle approche basée sur l'assemblage de petites constructions cellularisées permettant une distribution cellulaire homogène et une vascularisation plus efficace dans des produits d’IT.Notre hypothèse est que l'approche couche-par-couche est plus adaptée à la régénération osseuse que l'approche conventionnelle de l'IT. L'objectif principal de cette thèse était d'évaluer les avantages de l'approche couche-par-couche en utilisant des membranes de polymères imprimées en 3D et ensemencées avec des cellules primaires humaines. Nous avons évalué l'efficacité de la formation du réseau vasculaire in vivo dans toute la construction 3D en utilisant cette approche et en la comparant à l'approche conventionnelle basée sur l'ensemencement des cellules sur la surface des scaffolds massives. Il n'y avait pas de différence significative dans le nombre de vaisseaux sanguins formés en 3D au niveau des parties externes des constructions implantées en site souscutanée chez des souris. Mais dans les parties internes des implants qui n'étaient pas en contact direct avec un tissu hôte, nous avons pu observer une formation des vaisseaux sanguins statistiquement plus efficace lorsque l'approche du bio-assemblage couche-par-couche a été utilisée. Cette formation de réseau vasculaire était plus importante dans le cas de co-cultures que de mono-cultures.Il y avait plusieurs objectifs secondaires dans ce travail. Le premier était de fabriquer des constructions 3D cellularisées pour l'IT en utilisant des membranes d'acide polylactique (PLA) et des cellules primaires humaines : des cellules de stroma de moelle osseuse humaine (HBMSCs) isolées de la moelle osseuse et des cellules progénitrices endothéliales (EPCs) isolées du sang du cordon ombilical. Ensuite, nous avons comparé différentes technologies de fabrication des scaffolds: impression 3D directe à partir de poudre de PLA et impression par fil fondu en utilisant une imprimante commerciale et une autre fabriquée sur mesure. L'imprimante sur mesure a permis le plus haut niveau de résolution d'impression spécialement adaptée à la forme et la taille des pores. Par ailleurs, nous avons évalué différents systèmes de stabilisation pour l'assemblage couche par couche : l’utilisation de clips en PLA imprimés en 3D a fourni une stabilisation plus efficace pour empiler les membranes PLA couche par couche. Un autre avantage de ce système de stabilisation est qu'il peut être implanté avec des implants. Ensuite, nous avons observé une prolifération et une différenciation cellulaire plus efficaces lorsque le système de co-culture était utilisé, en comparaison avec des mono-cultures.L'approche du bioassemblage couche-par-couche semble être une solution appropriée pour une vascularisation efficace dans des structures 3D entières d'ingénierie tissulaire. / Tissue Engineering (TE) is “an interdisciplinary field that applies principles of engineering and the life sciences toward development of biological substitutes that restore, maintain, or improve tissue function”. The First application of TE is to replace damaged tissues by artificial cell-materials products of tissue engineering (TE). Another TE application is to produce 2 or 3 dimensional (2D and 3D) models for biological and pharmacological in vitro studies. These models or tissue replacements can be fabricated using a combination of different interdisciplinary methods of medicine, biology, chemistry, physics, informatics and mechanics, providing specific micro-environment with different cell types, growth factors and matrix.One of the major challenges of tissue engineering is related to limited cell penetration in the inner parts of porous biomaterials. Poor cell viability in the center of engineered tissue is a consequence of limited oxygen and nutrients diffusion due to insufficient vascular network within the entire construct. Layer-by-layer (LBL) BioAssembly is a new approach based on assembly of small cellularized constructs that may lead to homogenous cell distribution and more efficient three dimensional vascularization of large tissue engineering constructs.Our hypothesis is that LBL Bioassembly approach is more suitable for bone regeneration than conventional tissue engineering approach. The primary objective of this thesis was to evaluate the advantages of LBL Bioassembly approach using 3D-printed polymer membranes seeded with human primary cells. We have evaluated the efficiency of vascular network formation in vivo within entire 3D tissue engineering construct using LBL bioassembly approach and comparing it to the conventional approach based on seeding of cells on the surface of massive 3D scaffolds. There was no significant difference in number of formed blood vessels in 3D at the outer parts of constructs implanted subcutaneously in mice 8 weeks post-implantation. But in the inner parts of implants which were not in direct contact with a host tissue, we could observe statistically more blood vessel formation when LBL bioassembly approach was used. This vascular network formation was more important in the case of co-cultures than mono-vultures of HBMSCs.There were several secondary objectives in this work. The first was to fabricate cellularized 3D constructs for bone tissue engineering using poly(lactic) acid (PLA) membranes and human primary cells: human bone marrow stroma cells (HBMSCs) isolated from the bone marrow, and endothelial progenitor cells (EPCs) isolated from the umbilical cord blood. Then, we have compared different Additive manufacturing technologies to fabricate scaffolds: direct 3D printing (3DP) starting from PLA powder dissolved in chloroform and fused deposition modelling (FDM) using a commercial or a custom-made printer with different resolutions.The custom-made printer equipped with 100 μm nozzle allowed the highest level of printing resolution concerning pores shape and size. In the meantime we evaluated different stabilization systems for layer-by-layer assembling of PLA membranes with human primary cells: the use of 3D printed PLA clips provided the most efficient stabilization to stack PLA membranes in 3D. Another advantage of this stabilization system is that it could be implanted together with LBL constructs. Then we investigated the most suitable cell culture system for such constructs and we observed more efficient cell proliferation and differentiation when co-culture system is used, comparing to mono-cultures.LBL bioassembly approach seems to be suitable solution for efficient vascularization within entire large 3D tissue engineering constructs especially when co-cultures of mesenchymal and endothelial cells are used. Impression 3D Acide Poly(lactic) BioAssemblage Couche par Couche Ingénierie Tissulaire Osseuse Biofabrication 3D printing Poly(lactic) acid Layer-by-Layer BioAssembly Bone Tissue Engineering Biofabrication
213	3D woven scaffolds for bone tissue engineering Persson, M. (Maria) 02 December 2014 (has links) Abstract Bone tissue engineering has become a rapidly expanding research area because it offers a promising new approach for bone repair and regeneration. Compared to traditional autograft and allograft procedures, bone tissue engineering techniques based on the use of scaffolding materials in combination with autogenous stem cells can eliminate problems of donor site morbidity associated with the harvest of bone tissue, and its short supply. Clearly, the choices of material as well as a scaffold design that enhance bone regeneration are major challenges in the tissue engineering approach. Fibers in the micro-range in combination with textile-based technologies are consider as potential routes for the production of complex scaffolds since they can be used to generate a wide range of morphological structures and geometrically varied structures with high precision. Therefore in this thesis the specific objects were to: (i) develop a biocompatible composite fiber from poly(lactic acid) (PLA) and hydroxyapatite (HA) by melt spinning, (ii) design a 3D textile scaffold utilizing weaving and (iii) evaluate the scaffolds’ performance as a bone substitute material in vitro. In the present study PLA/HA composite fibers were successfully produced, and found to possess sufficient mechanical strength even at high loading concentrations (i.e. 20wt %), to be useful in a textile process. In addition, the material was shown to be biocompatible and the presence of HA in the PLA composite significantly enhanced the initial cell attachment. In a 3D woven scaffold, bone marrow derived human mesenchymal stem cells (hMSCs) differentiated into osteoblasts and mineralized bone formation in vitro was observed through-the-thickness of the scaffold. Taken together, these results indicate the potential feasibility of PLA/HA composite fiber in a 3D woven scaffold for use as a bone substitute material in tissue engineering applications. / Tiivistelmä Luupuutosten korvaaminen kudosteknologisesti on kehittynyt nopeasti ja tutkimustulokset tarjoavat lupaavia mahdollisuuksia tuottaa uutta luuta luupuutosalueelle. Perinteisiin potilaan omasta luusta tehtyihin luusiirteisiin ja pankkiluusiirteisiin verrattuna potilaan omat kantasolut voivat vähentää ongelmia, joita ovat siirremateriaalin rajallinen saatavuus ja vieraan kudoksen aiheuttamat reaktiot. On tärkeä etsiä hyviä materiaaleja, joista voidaan valmistaa sellaisia kolmiulotteisia (3D) rakenteita, joilla tehostetaan luun paranemista ja uuden luun muodostumista. Kutomalla tuotetut tukirakenteet mahdollistavat kantasolusiirteille kolmiulotteisuuden, jota voidaan säädellä monipuolisesti ja tarkasti. Tämän väitöstutkimuksen tarkoituksena oli: (i) kehittää bioyhteensopiva kuitu maitohappopolymeeristä poly lactic acid (PLA) ja hydroksiapatiitista (HA) kuituekstruusiolla, (ii) suunnitella ja kutoa tästä kuidusta 3D tekstiilirakenne, ja (iii) tutkia sen toimivuus ja ominaisuudet luunmuodostusta tukevana materiaalina soluviljelyolosuhteissa. Tämä tutkimus osoittaa, että PLA kuitua voidaan seostaa hydroksiapatiitilla, ja PLA/HA kuidut ovat mekaanisesti kestäviä sisältäessään jopa 20 painoprosenttia hydroksiapatiittia. Siten kuidut ovat tekstiilin valmistuksessa käyttökelpoisia. Lisäksi materiaali osoittautui bioyhteensopivaksi, ja hydroksiapatiitti paransi solujen tarttumista PLA kuituun viljelyn alkuvaiheessa. Ihmisen luuytimestä peräisin olevat sidekudoksen kantasolut (hMSCs) erilaistuivat soluviljelmässä luuta muodostaviksi soluiksi eli osteoblasteiksi, ja tuottivat mineralisoitunutta luun väliainetta kautta koko kudotun tukirakenteen. Johtopäätöksenä on, että PLA/HA yhdistelmäkuitua voidaan kutoa kolmiulotteiseksi tukirakenteeksi, ja sitä on mahdollista käyttää apuna korvattaessa luupuutoksia kudosteknologian keinoin. bone tissue engineering hydroxyapatite composite melt spinning mesenchymal stem cell poly lactic acid textile scaffolds hydroksiapatiitti komposiitti kuituekstruusio tekstiili luun kudosteknologia mesenkymaaliset kantasolut poly lactic acid
214	Hydrogen and lactic acid synthesis through capnophilic lactic fermentation by Thermotoga neapolitana / Production d'hydrogéne et d'acide lactique par Thermotoga neapolitana au cours de la fermentation lactique Pradhan, Nirakar 15 December 2016 (has links) Les énergies non-renouvelables ont été d’un apport capital dans l’industrialisation et l’urbanisation dans les derniers centenaires. L’exploitation excessive des réserves d’hydrocarbures et son impact environnemental ont contribué au developpement de plusieurs technologies durables à caractère néo-carbone neutre. A cet effet, les processus biologiques comme la fermentation pourraient être exploités pour convertir biologiquement le hydrates de carbone en énergies comme l’hydrogène (H2) ou des acides organiques commercialement rentables. Ce travail a étudié les techniques d’ingénierie pour améliorer la synthèse simultanée d’H2 et d’acide lactique à travers des conditions de fermentation capnophile lactique (CLF) par une souche de labo de Thermotoga neapolitana.En un premier temps, une comparaison génotypique entre la souche de labo et celle sauvage a révélé une ressemblance de 88,1 (±2,4) %. En plus, les analyses du génotypage par RiboPrint® et par spectroscopie de masse matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF MS) ont montré une différentiation génétique au-delà du niveau sous-espèce ; et par conséquent la souche de labo a été proposée comme sous-espèce, T. neapolitana subsp. lactica. Basé sur la caractérisation phénotypique, la souche de labo produisait 10-90% plus d’acide lactique que celle sauvage sous les mêmes conditions sans pour autant affecté le taux de production d’H2.La souche de labo a donc été étudiée pour aussi bien optimiser les conditions de croissance que pour estimer les paramètres cinétiques de croissance. Un nouveau modèle cinétique basé sur les principes de fermentation à l’obscurité (DF) et les expressions mathématiques Monod ont été développés pour permettre la simulation de la croissance en biomasse, la consommation de substrat, et la formation de produit. Le modèle n’a cependant pas pu faire une estimation des acides acétique et lactique avec précision du fait que le modèle DF n’a pas considéré la carboxylation de l’acide acétique en acide lactique par l’enzyme pyruvate ferrédoxine oxydoréductase (PFOR) sous les conditions CLF.Le model a été associé avec le mécanisme CLF et les paramètres cinétiques ont été recalibrés. Les paramètres cinétiques que sont le taux d’absorption spécifique maximum (k), la constante semi-saturation (ks), le coefficient en rendement biomasse (Y), et le taux de décomposition interne (kd) étaient de 1,30 l/h, 1,42 g/L, 0,12 et 0,02 l/h. Fait intéressant, le nouveau modèle CLF s’est parfaitement adapté avec les résultats expérimentaux et a estimé que près de 40-80% de la production d’acide lactique est attribué au recyclage de l’acide acétique et le CO2.En plus, l’adsorption de l’acide lactique par le carbone actif et les résines polymères anioniques a été appliquée avec succès comme technique de transformation en aval dans la récupération et la purification de l’acide lactique à partir du modèle de fermentation type T. neapolitana. Pour ce faire, ce travail de recherche constitue une étape majeure dans le domaine de la fermentation bactérienne utilisable pour de vastes applications scientifiques prenant en compte le développement d’énergies renouvelables et la production industrielle d’acide lactique / The environmental impact of excessive exploitation of fossil fuel reserves has inspired the innovation of several sustainable neo-carbon-neutral technologies. To that end, the biological processes like fermentation may be leveraged to bioconvert carbohydrate-rich feedstocks to fuels like hydrogen (H2) or commercially valuable organic acids like lactic acid. This research work investigated the engineering techniques for improving simultaneous synthesis of H2 and lactic acid under capnophilic (CO2-dependent) lactic fermentation (CLF) conditions by a lab strain of Thermotoga neapolitana.Primarily, the genotypic comparison between the lab strain and the wild-type revealed DNA homology of 88.1 (± 2.4)%. Genotyping by RiboPrint® and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) analyses showed a genetic differentiation beyond subspecies level, hence the lab strain was proposed as a new subspecies, T. neapolitana subsp. lactica. The lab strain produced 10-90% more lactic acid, based on the phenotypic characterization, than the wild-type strain under similar operating conditions without impairing the H2 yield.The lab strain was then studied to optimize the growth conditions as well as to estimate the growth kinetic parameters. A new mathematical model based on the dark fermentation (DF) principles and Monod-like kinetic expressions was developed to enable the simulation of biomass growth, substrate consumption and product formation. The model failed to estimate acetic and lactic acid accurately, as the DF model did not consider the carboxylation of acetic acid to lactic acid by the pyruvate:ferredoxin oxidoreductase (PFOR) enzyme under CLF conditions. The model was then incorporated with the CLF mechanism and the kinetic parameters were recalibrated.The calibrated kinetic parameters, i.e. maximum specific uptake rate (k), semi-saturation constant (kS), biomass yield coefficient (Y) and endogenous decay rate (kd) were 1.30 1/h, 1.42 g/L, 0.12 and 0.02 1/h, respectively, under CLF conditions. The new CLF-based model fitted very well with the experimental results and estimated that about 40-80% of the lactic acid production is attributed to the recycling of acetic acid and CO2.In addition, the adsorption of lactic acid by activated carbon and anionic polymeric resins was successfully applied as a downstream processing technique for the recovery of lactic acid from a model T. neapolitana fermentation broth. This research work serves as a practical milestone in the field of microbial fermentation with a scope for wider scientific applications, including the development of bio-based renewable energy and industrial lactic acid production Hydrogène Adsorption Modèle cinétique Acide lactique Acide acétique Fermentation capnophile lactique Hydrogen Adsorption Kinetic model Lactic acid Acetic acid Capnophilic lactic fermentation
215	Controlled Release System for Localized and Sustained Drug Delivery Applications Rodriguez, Lidia Betsabe 19 June 2013 (has links) No description available. Biomedical Engineering Biomedical Research Chemical Engineering Materials Science chitosan controlled aspirin sodium tripolyphosphate poly lactic acid poly lactic co glycolic acid poly glycolic acid degradation release
216	Biodegradable poly(lactic acid) nanocomposites: synthesis and characterization Li, Yonghui January 1900 (has links) Doctor of Philosophy / Department of Grain Science and Industry / X. Susan Sun / Biobased polymers derived from renewable resources are increasingly important due to acute concerns about the environmental issues and limited petroleum resources. Poly(lactic acid) (PLA) is such a polymer that has shown great potential to produce biodegradable plastics. However, low glass transition temperature (Tg), low thermal stability, slow biodegradation rate, and high cost limit its broad applications. This dissertation seeks to overcome these limitations by reinforcing PLA with inorganic nanoparticles and low-cost agricultural residues. We first synthesized PLA nanocomposites by in situ melt polycondensation of L-lactic acid and surface-hydroxylized nanoparticles (MgO nanocrystals and TiO2 nanowires) and investigated the structure-property relationships. PLA grafted nanoparticles (PLA-g-MgO, PLA-g-TiO2) were isolated from the bulk nanocomposites via repeated dispersion/centrifugation processes. The covalent grafting of PLA chains onto nanoparticle surface was confirmed by Fourier transform infrared spectroscopy and thermalgravimetric analysis (TGA). Transmission electron microscopy and differential scanning calorimetry (DSC) results also sustained the presence of the third phase. Morphological images showed uniform dispersion of nanoparticles in the PLA matrix and demonstrated a strong interfacial interaction between them. Calculation based on TGA revealed that more than 42.5% PLA was successfully grafted into PLA-g-MgO and more than 30% was grafted into PLA-g-TiO2. Those grafted PLA chains exhibited significantly increased thermal stability. The Tg of PLA-g-TiO2 was improved by 7 °C compared with that of pure PLA. We also reinforced PLA with low-value agricultural residues, including wood flour (WF), soy flour (SF), and distillers dried grains with solubles (DDGS) by thermal blending. Tensile measurements and morphological images indicated that methylene diphenyl diisocyanate (MDI) was an effective coupling agent for PLA/WF and PLA/DDGS systems. MDI compatibilized PLA/WF and PLA/DDGS composites showed comparable tensile strength and elongation at break as pure PLA, with obviously increased Young’s modulus. Increased crystallinity was observed for PLA composites with SF and DDGS. Such PLA composites have similar or superior properties compared with pure PLA, especially at a lower cost and higher biodegradation rate than pure PLA. The results from this study are promising. These novel PLA thermoplastic composites with enhanced properties have potential for many applications, such as packaging materials, textiles, appliance components, autoparts, and medical implants. Poly(lactic acid) Nanoparticles Nanocomposites Composites Biodegradable Materials Science (0794) Polymer Chemistry (0495)
217	Optically pure D (-) lactic acid biosynthesis from diverse renewable biomass: microbial strain development and bioprocess analysis Zhang, Yixing January 1900 (has links) Doctor of Philosophy / Department of Grain Science and Industry / Praveen V. Vadlani / Lactic acid is an important platform chemical that has long history and wide applications in food, polymer, pharmaceutics and cosmetic industries. Lactic acid has two optical isomers; namely D-lactic acid and L-lactic acid. Racemic mixture of lactic acid are usually used as preservatives and ingredients in solvents, or as precursors for different chemicals. Currently there is an increasing demand of optical pure lactic acid as a feedstock for the production of poly-lactic acid (PLA). PLA is a biodegradable, biocompatible and environmental friendly alternative to plastics derived from petroleum based chemicals. Optically pure D or L-lactic acid is used for the synthesis of poly D or L- lactic acid (PDLA, PLLA). Blend of PDLA with PLLA results in a heat-resistant stereocomplex PLA with excellent properties. As a consequence, large quantity of cost effective D-lactic acid is required to meet the demand of stereocomplex PLA. Lignocellulosic biomass is a promising feedstock for lactic acid production because of its availability, sustainability and cost effectiveness compared to refined sugars and cereal grain-based sugars. Commercial use of lignocellulosic biomass for economic production of lactic acid requires microorganisms that are capable of using all sugars derived from lignocellulosic biomass. Therefore, the objectives of this study were: 1) to produce high level of optically pure D-lactic acid from lignocellulosic biomass-derived sugars using a homofermentative strain L. delbrueckii via simultaneous saccharification and fermentation (SSF); 2) to develop a co-culture fermentation system to produce lactic acid from both pentose and hexose sugars derived from lignocellulosic biomass; 3) to produce D-lactic acid by genetically engineered L. plantarum NCIMB 8826 ∆ldhL1 and its derivatives; 4) to construct recombinant L. plantarum by introduction of a plasmid (pLEM415-xylAB) used for xylose assimilation and evaluate its ability to produce D-lactic acid from biomass sugars; and 5) to perform metabolic flux analysis of carbon flow in Lactobacillus strains used in our study. Our results showed that D-lactic acid yield from alkali-treated corn stover by L. delbrueckii and L. plantarum NCIMB 8826 ∆ldhL1 via SSF were 0.50 g g[superscript]-1 and 0.53 g g[superscript]-1 respectively; however, these two D-lactic acid producing strains cannot use xylose from hemicellulose. Complete sugar utilization was achieved by co-cultivation of L. plantarum ATCC 21028 and L. brevis ATCC 367, and lactic acid yield increased to 0.78 g g[superscript]-1 from alkali-treated corn stover, but this co-cultivation system produced racemic mixture of D and L lactic acid. Simultaneous utilization of hexose and pentose sugars derived from biomass was achieved by introduction of two plasmids pCU-PxylAB and pLEM415-xylAB carrying xylose assimilation genes into L. plantarum NCIMB 8826 ∆ldhL1, respectively; the resulting recombinant strains ∆ldhL1-pCU-PxylAB and ∆ldhL1-pLEM415-xylAB used xylose and glucose simultaneously and produced high yield of optically pure D-lactic acid. Metabolic flux analysis verified the pathways used in these Lactobacillus strains and provided critical information to judiciously select the desired Lactobacillus strain to produce lactic acid catering to the composition of raw material and the optical purity requirement. This innovative study demonstrated strategies for low-cost biotechnological production of tailor-made lactic acid from specific lignocellulosic biomass, and thereby provides a foundational manufacturing route for a flexible and sustainable biorefinery to cater to the fuel and chemical industry. Lactic acid Lactobacilli SSF corn stover fermentation xylose assimilation Agriculture, General (0473)
218	Water vapour permeability of bio-based polymers Duan, Zhouyang January 2013 (has links) This project investigates the moisture barrier properties of bio-based polymers and ways of improving them. The first section addresses the effect of crystallinity on the water permeability of poly(lactic acid) (PLA). The second section investigates PLA/talc composites and PLA/ montmorillonite nanocomposites. The third section is focused on a new polymer, polybutylene succinate (PBS), and its nanocomposites with montmorillonite. In the first section, the water vapour transmission rates (WVTR) through samples of polylactic acid of different crystallinities have been measured. Three different grades of commercial PLA were used with different ratios of L-lactide and D-lactide to give a range of crystallinities from 0 to 50%. Sheets of PLA were prepared by melt compounding followed by compression moulding and annealing at different temperatures and for different times to give the range of crystallinities required. Crystallinity was measured by differential scanning calorimetry (DSC) and the morphology of the samples was observed under crossed polars in a transmitted light microscope. Water vapour transmission rates through the films were measured at 38°C and at a relative humidity of 90%. It was found that the measured values of WVTR decreased linearly with increasing crystallinity of the PLA from 0 to 50%. The results are discussed in terms of the effect of crystallinity on solubility and shown to fit the tortuous path model. The model was also successfully used to explain published data on water permeability of polyethylene terephthalate. In the second section, a series of PLA/talc composites and PLA/ montmorillonite nanocomposites were prepared by melt compounding followed by compression moulding. The morphologies of the composites were investigated using transmission electron microscopy (TEM) and wide-angle X-ray diffraction (WAXD) and it was found that the fillers were well dispersed in the polymer matrix. The average aspect ratio of the compounded talc was found to be 8, and that of the nanoclay was found to be 50. Water vapour transmission rates (WVTR) through the films were measured at 38°C and at a relative humidity of 90%. It was found that the measured values of WVTR decreased with increasing filler content and the results gave good agreement with predictions from the Nielsen tortuous path model. In the third section, PBS/ montmorillonite nanocomposites were prepared by melt compounding followed by compression moulding. The melting and crystallisation behaviour of the pure PBS samples were investigated using differential scanning calorimetry (DSC) and cross polarised optical microscopy. A slight decrease of the degree of crystallinity was found in PBS containing 5% nanoclay. The morphology of the composites was investigated using transmission electron microscopy (TEM) and wide-angle X-ray diffraction (WAXD) and it was confirmed that that composite structures were intercalated. Water vapour transmission rates (WVTR) through the PBS sheets were measured using a MOCON Permatran-W®398. The measured values of WVTR decreased with increasing nanoclay content. However, the experimental values were all higher than the values predicted by the Nielsen tortuosity model. This result shows that in the case of PBS, which is a highly crystalline polymer, the nanoclay is not as well dispersed and is not as effective in reducing water vapour permeability as in the case of PLA. 668.4
219	Identification of lactic acid bacteria isolated from vinegar flies and Merlot grapes Groenewald, W. H. 10 1900 (has links) Thesis (MSc)--University of Stellenbosch, 2005. / ENGLISH ABSTRACT: Thirty lactic acid bacteria were isolated from the intestinal tract of Drosophila simulans Stuvervant and nine lactic acid bacteria from Merlot grapes collected from the same winery in the Stellenbosch region, South Africa. The isolates were grouped according to morphological, biochemical and physiological characteristics. Isolates selected from each group were identified to species level by PCR with species-specific primers, PCR-based DGGE and 16S rDNA sequencing. The majority of isolates from the intestinal tract of Drosophila simulans Stuvervant belonged to the species Lactobacillus plantarum, but Lactobacillus paracasei, Lactobacillus sanfranciscensis, Leuconostoc mesenteroides subsp. mesenteroides, Lactococcus lactis subsp. lactis, Enterococcus faecalis and Pediococcus pentosaceus were also identified. As far as we could determine, this is the first report on the isolation of L. paracasei, L. sanfranciscensis, L. mesenteroides subsp. mesenteroides, L. lactis subsp. lactis, E. faecalis and P. pentosaceus from vinegar flies. Lactobacillus plantarum has previously been isolated from Merlot grapes. The genotypic relatedness among isolates of L. plantarum isolated from the intestinal tract of vinegar flies and from Merlot grapes were determined by RAPD-PCR. The isolates were grouped into four genotypically well-separated clusters. Thirteen isolates from grape must and five from flies yielded identical RAPD-PCR banding patterns and grouped into one cluster, suggesting that they are descendants from the same strain. This suggests that L. plantarum has the ability to use vinegar flies as a vector. / AFRIKAANSE OPSOMMING: Dertig melksuurbakterieë is vanuit die dermkanaal van Drosophila simulans Stuvervant geïsoleer en nege melksuurbakterieë vanuit Merlot-druiwe. Die druiwe is afkomstig van dieselfde wynkelder in die Stellenbosch-area van Suid-Afrika. Die isolate is volgens morfologiese, biochemiese en fisiologiese eienskappe gegroepeer. Verteenwoordigende isolate vanuit die fenotipiese groepe is tot spesievlak met behulp van lukraak ge-amplifiseerde polimorfe-DNA (RAPD) polimerase ketting-reaksie (PKR), PKR met spesie-spesifieke inleiers, PKR-gebaseerde denaturerende gradient-jel elektroforese (DGGE) en 16S rDNA sekwensering geïdentifiseer. Die meerderheid isolate uit die ingewande van Drosophila simulans Stuvervant is as Lactobacillus plantarum geklassifiseer. Stamme van Lactobacillus paracasei, Lactobacillus sanfranciscensis, Leuconostoc mesenteroides subsp. mesenteroides, Lactococcus lactis subsp. lactis, Enterococcus faecalis en Pediococcus pentosaceus is ook geïdentifiseer. Sover bekend, is dit die eerste keer dat L. paracasei, L. sanfranciscensis, L. mesenteroides subsp. mesenteroides, L. lactis subsp. lactis, E. faecalis en P. pentosaceus uit asynvlieë geïsoleer is. Lactobacillus plantarum is voorheen uit Merlot-druiwe geïsoleer. Die genotipiese ooreenkoms tussen die stamme van L. plantarum wat uit die asynvlieë en Merlot-druiwe geïsoleer is, is deur middel van RAPD-PKR bepaal. Hiervolgens is die stamme in vier genotipies goed-gedefinieerde groepe geplaas. Dertien isolate vanuit druiwemos en vyf vanuit asynvlieë het identiese RAPD-PKR bandpatrone vertoon en het in een groep gesorteer. Hierdie resultate dui daarop dat die stamme heel moontlik uit een voorouer ontstaan het en dat asynvlieë heel moontlik as vektor vir L. plantarum dien. Lactic acid bacteria -- Identification Drosophilidae -- Microbiology Grapes -- Microbiology Theses -- Microbiology Dissertations -- Microbiology
220	Studies on regulation of the plantaricin 423 gene Cohen, Francisca 12 1900 (has links) Thesis (MSc) -- University of Stellenbosch, 2004. / ENGLISH ABSTRACT: Lactic acid bacteria play an essential role in the majority of fermented foods by producing organoleptic compounds and increasing the shelf life. The best-studied antimicrobial compounds are bacteriocins, i.e. ribosomally synthesized peptides. Most of these peptides have a narrow spectrum of activity and are usually only active against bacteria from the same ecological niche. The fact that all bacteriocins are degraded by proteolytic enzymes enlarges their potential use as natural food preservatives. The ideal would be to replace or reduce chemical preservatives such as sulfur dioxide, nitrates and nitrites. Bacteriocins are classified into four groups according to their structural and functional characteristics. Plantaricin 423, produced by Lactobacillus plantarum 423, is heat stable, plasmid encoded, relatively small (3.5 kDa) and is classified as a class Iia bacteriocin. The peptide is active from pH 1.0 to 10.0 and inhibits Gram-positive bacteria, including Lactobacillus spp., Leuconostoc spp., Oenococcus oeni, Pediococcus spp., Enterococcus spp., Propionibacterium spp. and pathogens such as Bacillus cereus, Clostridium spp. and Listeria monocytogenes. Production of bacteriocins may occur constitutively or may be regulated by a cell-density dependent system called quorum sensing. Plantaricin 423 is produced throughout logarithmic growth, with no apparent change in production levels when the producer strain is cultured in the presence of plantaricin 423 or Listeria innocua and Lactobacillus sakei. This led us to believe that plantaricin 423 may be produced constitutively. A reporter system was constructed which consisted of the plantaricin 423 promoter, P423, fused to the luxAB genes and cloned into a shuttle vector, pTRKH2. The newly constructed plasmid, pTAB4, was transformed to a bacteriocin-negative mutant of L. plantarum (423 B} Despite several repeats, no luciferase activity was recorded and no RNA homologous to the luxAB genes was detected. The region necessary for expression of plantaricin 423 may be located stream-up of the -80 region homologous to the -80 and -40 conserved repeats of regulated class II bacteriocins. Inclusion of the latter region in the reporter construct may result in the successful expression of luxAB. / AFRIKAANSE OPSOMMING: Melksuurbakteriee speel 'n belangrike rol in die meeste gefermenteerde voedselsoorte deur die produksie van organoleptiese komponente en die verlenging van rakleeftyd. Van aile antimikrobiese komponente is bakteriosiene (ribosomaal gesintetiseerde peptiede) die beste bestudeer. Hierdie peptiede het gewoonlik 'n nou spektrum van antimikrobiese werking en is meestal aktief teen bakteriee in dieselfde ekologiese nis. Die feit dat bakteriosiene deur proteolitiese ensieme in die spysverteringskanaal vernietig word, verhoog die potensiele gebruik van bakteriosiene as preserveermiddels. Die ideaal sal wees om die konsentrasie van chemiese preserveermiddels soos swaweldioksied, nitrate en nitriete te verlaag of rnoontlik te vervang met bakteriosiene. Bakteriosiene word in vier groepe op grond van hul strukturele en funksionele karaktereienskappe geklassifiseer. Plantarisien 423, geproduseer deur Lactobacillus plantarum 423, is hitte-stabiel, word deur 'n plasmied gekodeer, is relatief klein (3.5 kDa) en sorteer onder die klas Iia bakteriosiene. Die peptied is aktief oor 'n wye pH-reeks (pH 1.0-10.0) en inhibeer Gram-positiewe bakteriee, insluitend Lactobacillus spp., Leuconostoc spp., Oenococcus oeni, Pediococcus spp., Enterococcus spp., Propionibacterium spp. en patogene soos Bacillus cereus, Clostridium spp. en Listeria monocytogenes. Produksie van bakteriosiene kan konstitutief plaasvind of kan gereguleer word deur 'n seldigtheids- afhanklike sisteem naamlik "quorum sensing". Plantarisien 423 word regdeur logaritmiese groei geproduseer, met geen verandering in produksievlakke wanneer die produserende stam in die teenwoordigheid van plantarisien 423 of Listeria innocua en Lactobacillus sakei gekweek word nie. Dit het gelei tot die hipotese dat plantarisien 423 moontlik konstitutief geproduseer word. 'n Verklikkersisteem bestaande uit 'n fusie van die plantarisien 423 promoter, P423, aan die luxAB gene is gekonstrueer en in die pendelplasmied pTRKH2 gekloneer. Die nuutgekonstrueerde plasmied, pTAB4, is na 'n bakteriosien-negatiewe mutant van L. plantarum (stam 423 B-) getransfonneer. Ten spyte van etlike herhalings kon geen lusiferase-aktiwiteit opgespoor word nie en kon ook geen homologie in die RNA met die luxAB gene opgespoor word nie. Dit is moontlik dat die area nodig vir uitdrukking van plantarisien 423 verder stroom-op van die -80 area, homoloog aan die -80 en -40 gekonserveerde herhalings van reguleerbare klas II bakteriosiene, gesetel is. Insluiting van laasgenoemde area in die verklikker-konstruk mag lei tot die suksesvolle uitdrukking van luxAB. Genetic regulation Bacteriocins Lactic acid bacteria -- Genetics Lactobacillus plantarum Plantaricin 423 gene Dissertations -- Microbiology

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