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191	Synthèse et caractérisation de matériaux magnétiques pour l'adsorption de polluants présents dans les eaux / Synthesis and characterization of magnetic materials for the adsorption of pollutants in water Obeid, Layaly 26 September 2014 (has links) L'objectif de ce travail est le développement et la caractérisation de matériaux magnétiques (magsorbants) qui pourraient être intégrés dans un procédé assisté magnétiquement dont la finalité est de compléter les procédés actuellement utilisés dans les filières de traitement des eaux. Pour s'inscrire dans une démarche d'écoconception, nos matériaux sont des billes millimétriques constituées d'une matrice biopolymère (alginate ou chitosane) dans laquelle sont encapsulées des nanoparticules magnétiques. Ces billes sont bifonctionnelles, elles possèdent des propriétés adsorbantes permettant l'extraction de polluants organiques. Mais leur originalité réside dans leurs propriétés magnétiques qui sont mises à profit pour les séparer magnétiquement de l'eau à dépolluer. Les propriétés d'adsorption des billes magnétiques vis-à-vis de polluants organiques modèles ont été étudiées en regardant l'effet de différents paramètres tels que le pH et la force ionique de la solution, la concentration initiale en polluant et le temps de contact. Dans un premier temps, les polluants modèles considérés sont des colorants chargés. Nous avons montré que les billes d'alginate sont efficaces pour adsorber le bleu de méthylène chargé positivement alors que les billes de chitosane adsorbent le méthylorange chargé négativement. Par contre, le p-nitrophénol est faiblement adsorbé par les billes d'alginate et de chitosane. Pour pallier ce problème, deux solutions ont été proposées dans le but d'augmenter l'hydrophobicité des billes. La première consiste à ajouter un tensioactif cationique aux billes d'alginate. La deuxième solution est d'encapsuler une organobentonite dans les billes. / The aim of this thesis is the development and characterization of multifunctional materials called magsorbents that could be integrated in a water-treatment process to improve current methods or to develop new methods. These materials are millimetric beads with a polymer matrix in which are encapsulated magnetic nanoparticles of maghemite; in order to develop an environment-friendly product, biopolymers such alginate and chitosan were selected for the matrix. Our materials possess adsorbing properties allowing the extraction of organic pollutants from water. The originality of these materials lies in their magnetic properties that could be exploited for their magnetic separation from the treated medium. The adsorption characteristics of the magnetics beads were assessed by using two dyes: methyl orange (negatively charged) and methylene blue (positively charged). We showed that alginate beads are efficient for the removal of positively charged pollutants while chitosan beads adsorb preferentially negatively charged pollutants. p-nitrophenol is weakly adsorbed by both, alginate and chitosan beads. To overcome this problem, two solutions have been proposed in order to increase the beads hydrophobicity. The first one is adding a cationic surfactant, cetylpyridinium chloride, into alginate beads. The second solution is to encapsulate pillared clay into alginate beads. Both solutions show their efficiency in improving p-nitrophenol adsorption by alginate beads. Magsorbant Ferrofluide Adsorption Alginate Chitosane Polluant organique Cationic surfactant Adsorption 541.37
192	Manufacturing Microfluidic Flow Focusing Devices For Stimuli Responsive Alginate Microsphere Generation And Cell Encapsulation Karasinski, Michael A. 01 January 2017 (has links) In this paper a novel stimuli responsive hydrogel material, methacrylated sodium alginate beta-cyclodextrin (Alg-MA-β-CD), was used in combination with a microfluidic device to create microspheres. Currently there is no reliable method for fabricating homogeneous stimuli-responsive microspheres, in-house microfluidic devices are not reliable in manufacture quality or long-term use. Alginate hydrogels have many attractive characteristics for bioengineering applications and are commonly used to mimic the features and properties of the extracellular matrix (ECM). Human mesenchymal stem cells (hMSCs) are of top interest to tissue engineers. hMSCs are widely available and can be harvested and cultured directly out of human bone marrow. hMSCs have the ability to differentiate into osteoblasts, adipocytes, chondrocytes, muscle cells, and stromal fibroblasts depending on mechanical signals transmitted through surrounding ECM. The biomechanical properties of alginate based stimuli-responsive hydrogels can be tuned to match those of different types of tissues. When trying to transport and control the differentiation of hMSCs into generating new tissues or regenerating damaged tissues, it is highly beneficial to encapsulate the cells inside a microsphere made from these hydrogels. The proposed research objectives are: 1) To optimize fabrication techniques and create functional microfluidic devices; 2) Analyze the effects of flow parameters on microsphere production; and 3) Encapsulate viable hMSCs inside multi-stimuli responsive alginate microspheres using the fabricated microfluidic devices (MFDs). In this study, photolithography microfabrication methods were used to create flow-focusing style MFDs. The hydrogel materials were characterized via rheological methods. Syringe pumps controlled flow rates of fluids through the devices. Active droplets formation was monitored through a camera attached to an inverted microscope, where images were analyzed. Microsphere production was analyzed optically and characterized. Alg-MA-β-CD polymer solutions containing hMSCs were encapsulated, and a live/dead florescence assay was preformed to verify cell viability. Using a modified fabrication process it was possible to manufacture Alg-MA-β-CD microspheres and encapsulate and maintain viable hMSCs inside. alginate cell encapsulation hydrogel microfluidics stem cell stimli responsive Engineering Mechanical Engineering
193	Liberação sustentada do antisséptico clorexidina em micropartículas de quitosana e alginato / Sustained release of the antiseptic chlorhexidine from microparticles composed of chitosan and alginate Barboza, Ana Cláudia Rueda Nery, 1973- 24 August 2018 (has links) Orientador: Francisco Benedito Teixeira Pessine / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Química / Made available in DSpace on 2018-08-24T11:11:00Z (GMT). No. of bitstreams: 1 Barboza_AnaClaudiaRuedaNery_D.pdf: 6657696 bytes, checksum: 97ec0acb030267fe87c6983093726afb (MD5) Previous issue date: 2013 / Resumo: O objetivo foi deste trabalho foi obter, caracterizar e avaliar suspensões aquosas de micropartículas poliméricas bioadesivas para liberação sustentada do antisséptico digluconato de clorexidina (CHG), trabalhando somente em meio aquoso e com substâncias reconhecidamente biocompatíveis e de baixa toxicidade, para potencial aplicação na cavidade bucal. As micropartículas foram obtidas por complexação dos polieletrólitos quitosana e alginato de sódio, com auxílio de íons cálcio, e da clorexidina. O método de obtenção desenvolvido permitiu obter suspensões com distribuição de diâmetros de partículas adequada e boa estabilidade. Através de delineamento experimental fatorial, avaliou-se o efeito dos principais componentes da suspensão sobre o diâmetro médio das micropartículas e sobre a incorporação de CHG. A liberação de CHG em meio simulador da cavidade oral (saliva artificial) ocorreu de forma gradual e por longos períodos, indicando existência de interação entre o ativo, de natureza catiônica, e as terminações aniônicas do biopolímero alginato. A cinética de liberação de sistemas onde tais interações ocorrem é complexa e sua compreensão envolve diversos fenômenos físico-químicos, que se procurou identificar e discutir. Realizou-se, de forma simplificada, a modelagem da cinética de liberação através do modelo matemático semiempírico de Peppas-Korsmeyer, o que também indicou a combinação de diferentes fenômenos influenciadores da liberação. Testes preliminares de eficácia antimicrobiana indicaram que a clorexidina do sistema de liberação sustentada manteve sua eficácia sobre os microrganismos padrão avaliados em comparação com a clorexidina livre / Abstract: The objective of this project was to obtain, characterize and evaluate aqueous suspensions of bioadhesive polymeric microparticles for sustained release of the antiseptic chlorhexidine digluconate (CHG), working in aqueous media and with substances recognized as biocompatible and of low toxicity, for potential application to the oral cavity. Microparticles were obtained by complexation of the polyelectrolytes chitosan and sodium alginate, with pre-gelation by calcium ions, and CHG. The method of obtention developed resulted in suspensions with adequate particle size distribution and good stability. Through factorial experimental design, the effect of main suspension components on the median particle diameter and CHG incorporation was evaluated. Chlorhexidine release in oral cavity simulating media (artificial saliva) occurred gradually and for extended periods, indicating the presence of interactions between the cationic active substance, and the anionic moieties of the alginate biopolymer. The release kinetics where those interactions occur is somewhat complex and its understanding involves various physicochemical phenomena that we tried to identify and discuss. Simplified modeling of the release kinetics through the Peppas-Korsmeyer semi-empirical mathematical model was done, also indicating the combination of various release-influencing phenomena. Preliminary microbiological tests indicated that sustained-release CHG kept its efficacy against standard microorganisms evaluated in comparison to free CHG / Doutorado / Físico-Química / Doutora em Ciências Liberação sustentada Clorexidina Quitosana Alginatos Micropartículas Sustained release Chlorhexidine Chitosan Alginate Biopolymer microparticles
194	Carbon Dioxide Nucleation as a Novel Cleaning Method for Sodium Alginate Fouling Removal from Reverse Osmosis Membranes desalination Alnajjar, Heba 05 1900 (has links) The use of Reverse osmosis (RO) membranes have been significantly increasing in water desalination, and the main operational obstacle in RO desalination plants is membrane fouling. Among other solutes, dissolved biopolymers, such as polysaccharides can lead to severe membrane fouling especially with the addition of calcium ions because of the complexation formation between the surface of membrane and foulants materials. However, this complexation can also take place in the feed bulk, resulting in foulants aggregates formation. Although there are some physical techniques that can maintain the membrane performance without reducing its lifetime, only chemical cleanings are still commonly used in RO plants. In this study, a novel cleaning method is proposed to restore the membrane performance by removing the deposited foulants without reducing the membrane lifetime. The cleaning method is based on using water saturated with dissolved CO2 gas, and its principle is based on producing spontaneous CO2 bubbles due to local pressure difference leading to nucleation of bubbles throughout the membrane surface, especially at nucleation sites, which improve the cleaning efficiency. Alginic acid sodium salt was used as a model of polysaccharides foulants in presence of different concentrations of NaCl and calcium ions aiming to enhance membrane fouling, and then CO2 cleaning solution efficiency, in terms flux recovery (FR), was tested under different operating conditions and compared to other cleaning methods. Average FR of 20%±3, 25%±3 and 80%±3 for MilliQ water, a cleaning solution at pH4, and CO2 solution at 6 bar, 0.17 m/s, and 23 ̊C ±0.2 for 6 minutes were obtained, respectively. The efficiency of this novel cleaning method was also compared to direct osmosis overnight, and the average flux was comparable (about 60%±3), though that the cleaning time was significantly different. Various calcium concentrations (0-10 mM) were added in the alginate solution to study the fouling behavior in terms of the potential for bulk complexation to form cake alginate layer on the membrane surface rather than a gel layer, and the role of CO2 bubbles nucleation to remove foulants was investigated. This cleaning method can be considered as an alternative more environmentally friendly technique in RO application. Carbon Dioxide Nucleation Sodium Alginate Fouling Reverse Osmosis Membranes Membranes Desalination Membrane Cleaning Physical Cleaning
195	INTERVENTIONS TO REDUCE MICROBIAL LOAD OF FOODBORNE PATHOGENS AT THE SURFACE OF FRESH PRODUCE Yezhi Fu (7036865) 12 October 2021 (has links) <div>Fresh produce has been the leading source of foodborne illness outbreaks in the US, surpassing typical pathogen carriers such as meat, dairy, and seafood. Among the fresh produce popular to the consumers, cantaloupe and sprouts are mostly susceptible to pathogen contaminations and outbreaks. However, it has been a challenge to address the key factor in the contamination - the biofilms formed by pathogens are highly resistant to conventional washing and cleaning procedures. For cantaloupe, the net-like and porous surface forms a barrier for washing. For sprouts, the fragile texture of seedlings prevents aggressive cleaning operation and biofilm removal.</div><div><br></div><div>In this study, innovative interventions were developed to improve microbial safety of fresh produce, using cantaloupe and alfalfa sprouts as models. For cantaloupe, abrasive brushing was designed to remove pathogen biofilm from cantaloupe. Our research found pathogens could form biofilm at cantaloupe rind surface as the residence time of pathogens increased. Biofilm formed on cantaloupe rind was imaged by cryo-scanning electron microscopy (cryo-SEM), and its resistance to sodium hypochlorite and lauroyl arginate ethyl (LAE) was confirmed. Furthermore, abrasive brushing with peroxyacetic acid (PAA) could effectively remove biofilm formed at cantaloupe rind. The efficacy of this novel cleaning technique was highly desirable, which could achieve 3 log reduction in pathogen population. Mechanism of abrasive brushing to remove biofilm at cantaloupe rind surface was also proposed. Conceivably, brushing with diatomaceous earth (DE) and PAA could be an innovative and cost-effective method to remove pathogen biofilm from cantaloupe rind.</div><div><br></div><div>For alfalfa sprouts, since most of the outbreaks are linked to the sprouting seeds, seed disinfection treatments are considered to be the most effective method to improve microbial safety of sprouts. In this study, a newly developed alginate-based, antimicrobial seed coating treatment was evaluated for its efficacy to reduce foodborne pathogens from alfalfa seeds and sprouts. The calcium alginate coating in the presence of 2.5% lactic acid (CA-LA coating) reduced foodborne pathogens inoculated on alfalfa seeds to an undetectable level on day 1 during 28 day-seed storage, while chlorine (20,000 ppm) or lactic acid (2.5%) treatment took longer time to reach the same level. With sprouts, CA-LA coating resulted in > 2.5 log reduction for pathogen cells. In contrast, log reduction was < 0.6 for either chlorine (20,000 ppm) or lactic acid (2.5%) treatment. In general, this study indicated the effect of calcium alginate coating on reducing bacterial load of alfalfa seeds and sprouts, however, the germination rate of treated seeds was compromised due to the addition of lactic acid in the seed coating. Further study is needed to select antimicrobial compounds with minimum impact on germination rate of seeds.</div><div><br></div> Food Packaging, Preservation and Safety Cantaloupe Alfalfa seeds Sprouts Foodborne pathogens Biofilm Abrasive brushing Calcium alginate coating
196	Příprava a charakterizace krytů ran / Preparation and characterization of wound dressings Dzurická, Lucia January 2020 (has links) The diploma thesis if focused on the study of bioactive hydrogél and nanofiber wound dressings composed of natural biopolymers, which were functionalized by active compounds in the form of analgesic, antibiotics and enzymes. Hydrogél wound dressings were constituted from alginate and chitosan and nanofibers were created from polyhydroxybutyrate. The following 7 active compounds were selected to be added to the wound dressings: ampicillin, streptomycin, ibuprofen, papain, bromelain, collagenase and trypsin. In the theoretical part the structure of the skin and types of wound injuries were described. This part also talks about types of wound dressing and their applications, as well as treatment of skin wounds using enzymes and compounds with analgesic and antimicrobial properties. In addition, this section describes safety assays, in particular cytotoxicity assays on human cells. At the beginning of the experimental part, the process of preparation of hydrogél wound dressing was optimised. Subsequently, the dressings were enriched with active compounds and the rate of gradual releasing of the substances into model environment was monitored. In the case of enzymes, their proteolytic activity was also tested after their incorporation to the wound dressings. Furthermore, the prepared bioactive wound dressings were analyzed for possible cytotoxic effect on human keratinocytes. Finally, the wound dressing with combined content of active substances was created and also characterized for the rate of substance release, proteolytic activity and cytotoxicity. Antimicrobial activity of this wound dressings, against two selected strains of microorganisms: Escherichia coli and Staphylococcus epidermidis, was also evaluated.
197	Izolace a charakterizace přírodních aktivních látek a možnosti jejich aplikace při přípravě doplňků stravy / Isolation and characterization of natural active components and their application in food supplements Šmídová, Veronika January 2021 (has links) The diploma thesis is focused on the characterisation and isolation of naturally occurred active compounds, especially on lipophilic compounds. The next part of the thesis deals with enzymes and their encapsulation into alginate particles to suggest new enzymatic dietary supplement for children with optimal nutrient composition. The theoretical part is focused on the issue of child nutrition, accordingly the necessary nutrients that children need to grow without any health difficulties. It is also focused on the availability of enzymatic food supplements for children. Finally, the theoretical part deals with the lack of chosen natural substances and their effects in connection with cancer. In the experimental part, four types of oils obtained from seeds were characterized. The oils were obtained by two methods: cold pressing with a Yoda kitchen press and extraction in an organic solvent with Soxtherm. Seeds were linseed, sesame, pumpkin, and cumin. With these oils were characterized natural active substances, polyphenols, flavonoids, antioxidants, carotenoids, chlorophylls, and fatty acids. Liposomes were also prepared from selected extracts, in which an effect on intestinal tumour cells were observed. Furthermore, some enzymes were selected, and they were encapsulated into alginate particles with average size 450 µm. In these particles was specified encapsulation efficiency as well as the proteolytic activity after testing in digest juices. The last part of this thesis was focused on the optimization of a complete enzymatic food supplement with addition of alginate particles as enzyme carriers. Samples of these supplements were finally subjected to a sensory analysis.
198	Enkapsulace vybraných přírodních extraktů pro využití v potravinářství / Encapsulation of selected natural extract for food application. Vyskočilová, Terezie January 2014 (has links) This diploma thesis deals with encapsulation of natural extracts. In the theoretical part the methods of encapsulation, materials for particle preparation, as well as application of encapsulation techniques in food industry were described. In experimental part selected natural extracts of propolis, green barley and probiotics were characterized. There substances were encapsulated into alginate and chitosan. In the total of 25 types of prepared particles long-term stability in some model physiological conditions as well as in four different model foods was evaluated. Additionally, stability of selected particles in several real milk-based products was followed too. The stability of particles was determined spectroptohometrically. In natural extract a content of polyphenols, proteins, chlorophylls, as well as total antioxidant activity were analysed. To analysis of probiotics optical and fluorescence microscopy were used. In propolis and green barley antimicrobial activity was tested too. Moreover, in the sample of propolis also cytotoxic assay was applied. Agar-chitosan was chosen as the best shell material for propolis due to its optimal stability in model physiological conditions as well as model foods. Liposomes were evaluated as unstable and were not recommended for further application. As the suitable shell material for powdered green barley starch-alginate (rate 1:4) and agar-chitosan were proposed, while the second one showed better stability for released proteins. Agar-chitosan shell material was usable for fresh green barley too. For probiotics encapsulation alginate or alginate-starch were chosen because of their porosity and possibility of nutrients diffusion. In real foods the best results were reached with application of probiotic particles into milk. Coencapsulation of powdered barley and probiotics did not confirm inhibition of culture growth. Neither the antimicrobial effect of propolis and barley nor the cytotoxic effect of propolis were confirmed.
199	Targeted delivery of GFP loaded polymeric nanoparticles to CD4 expressing cells using a CD4 specific aptamer Mirfin, Tayla Michele January 2020 (has links) >Magister Scientiae - MSc / Human Immunodeficiency Virus (HIV), which is the cause of Acquired Immunodefiency Syndrome (AIDS) is a major global public health issue affecting over 37 million people worldwide and is responsible for claiming over 32 million lives since the discovery of the disease in 1981. Through effective diagnosis, treatment and prevention HIV is a manageable disease. Today, advanced antiretrovirals, known as HAART, serve as effective, first-line drug regimens, consisting of a variety of viral inhibitors, and have successfully helped viral suppression. However, issues arise with antiretrovirals due to patient non-adherence and the development of drug resistant mutations. Coupled with dormant HIV reservoirs, viral extinction is attenuated. It is therefore essential that effective alternative treatments are investigated. The exploration of nanomedicine for targeted drug delivery has shown an ability to prolong the drug circulation time, target drugs to specific sites in the body, and enhance drug effectiveness. A previous study demonstrated a novel therapeutic strategy that was based on a mutant version of the caspase-3 enzyme that can induce apoptosis in HIV infected cells. This therapeutic strategy has the potential to wipe out reservoirs of HIV infection. However, the therapeutic strategy lacked selectivity because the delivery mechanism was based on protein transduction technology which will result in the nonselective delivery of the drug. In this study, preliminary work towards the development of a targeted nanoparticle delivery system for this mutant caspase-3 enzyme is described. The study describes the synthesis of green fluorescent protein loaded alginate/chitosan nanoparticles that were functionalized with a DNA aptamer intended to target the nanoparticles to CD4 expressing cells, that are also targeted by HIV. The THP-1 cell line was used due to the ability of the cells to express CD4 receptors on the cell surface. The nanoparticles were synthesized through ionotropic gelation. The size, polydispersity, zeta potential and morphology were investigated by Dynamic Light Scattering and Scanning Electron Microscopy, respectively. The strongly negative zeta potential studies revealed stability of the nanoparticles in suspension and Scanning Electron Microscopy results showed an indicative collapse of the polymer network for the empty nanoparticles (i.e. nanoparticles not loaded with GFP), whereas solid, cuboid nanoparticles were shown for the GFP-loaded nanoparticles. Image-based fluorescence cytometry demonstrated that the GFP-loaded nanoparticles bind to the THP-1 cells that express the CD4 receptor. The results obtained are indicative of a potential drug delivery system for HIV treatment however, adjustments would need to be made to the current study to further develop this nanocarrier. Aptamers Alginate Chitosan CD4 Electrostatic complexation HIV Lonotropic gelation Polymeric nanoparticles Nanomedicine
200	Studies on breeding of yeast Saccharomyces cerevisiae for effective macroalgae utilization based on the metabolism of marine bacterium / 海洋細菌の代謝を基盤とした大型藻類有効利用のための酵母育種の研究 Takagi, Toshiyuki 23 March 2017 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第20440号 / 農博第2225号 / 新制\|\|農\|\|1049(附属図書館) / 学位論文\|\|H29\|\|N5061(農学部図書室) / 京都大学大学院農学研究科応用生命科学専攻 / (主査)教授植田充美, 教授小川順, 教授渡邊隆司 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM Saccharomyces cerevisiae Macroalgae Alginate Saccharophagus degradans Quantitative proteomic analysis Yeast cell surface engineering Ethanol fermentation 610

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