Vitrificação de embriões Mus domesticus domesticus contidos em volumes diferentes de 9,0 m de etileno glicol. / Vitrification of mus domesticus domesticus embryos exposed to differents volumes of 9.0 m ethylene glycol solution

Assaf, Sabrina Silveira

January 2003

Os experimentos tiveram como objetivo determinar a taxa de eclosão dos embriões vitrificados em volumes diferentes de 9,0 M de etileno glicol. Simultaneamente, testou-se dois procedimentos de estocagem dos fios de teflon, denominados caixa de aço inoxidável e globete/raque. No experimento I, os 881 embriões coletados foram distribuídos em 4 tratamentos: tratamento 1 (T1= controle): 307 embriões foram cultivados in vitro em meio PBSm, acrescido de 0,4% de BSA; tratamento 2 (T2): 292 embriões foram expostos à solução de glicerol 10% acrescida de 0,4% de BSA, envasados em palhetas de 0,25 mL e submetidos ao congelamento pelo método rápido em Biocool; tratamento 3 (T3): 138 embriões foram expostos durante 2 minutos à solução de desidratação (10% de EG + 6% BSA em PBSm) e então transferidos para a solução de vitrificação (50% de EG + 6% de BSA em PBSm), onde permaneceram por 30 segundos e foram colocados em volume de 1 μL no interior de um fio de teflon, medindo 0,4 mm de diâmetro, 2,0 cm de comprimento e 0,05 mm de espessura. Os fios foram acondicionados em uma caixa de aço inoxidável para serem armazenados em nitrogênio líquido; tratamento 4 (T4): 144 embriões foram expostos à solução de desidratação (10% de EG + 6% BSA em PBSm) e após 2 minutos, foram transferidos para a solução de vitrificação (50% de EG + 6% BSA em PBSm), onde permaneceram por 30 segundos, sendo após transferidos para um volume de 1 μL no interior do fio de teflon. Os fios de teflon foram estocados em globetes unidos às raques e mantidos em nitrogênio líquido. Após o aquecimento, os embriões foram cultivados em PBSm suplementado com 0,4% de BSA. As taxas de eclosão embrionária observadas foram: T1=76,29% (245/307); T2=41,05% (117/292); T3=37,98% (54/138) e T4=26,78% (37/144). No segundo experimento, 747 embriões foram distribuídos em 3 tratamentos: tratamento 1 (T1= controle): 80 embriões foram cultivados in vitro em meio KSOM acrescido de 0,4% de BSA; tratamento 2 (T2): 334 embriões expostos em solução de glicerol 10% acrescida de 0,4% de BSA, foram envasados em palhetas de 0,25 mL e submetidos ao congelamento pelo método rápido em Biocool; tratamento 3 (T3): 333 blastocistos foram expostos durante 2 minutos à solução de desidratação (10% de EG + 0,4% BSA em PBSm) e então transferidos para tubos eppendorf de 2,0 mL em contato com a solução de vitrificação (50% de EG + 0,4% BSA em PBSm). Após o cultivo in vitro, as taxas de eclosão embrionária observadas nos 3 tratamentos foram respectivamente: 88,75% (71/80), 40,44% (141/334) e 19,70% (66/333). Baseado nesses resultados conclui-se que embriões Mus domesticus domesticus submetidos à técnica de vitrificação após exposição à solução de 9,0 M de etileno glicol e envase em fios de teflon assegurou índices satisfatórios de sobrevivência embrionária. As taxas de sobrevivência dos embriões Mus domesticus domesticus foi independente do procedimento de estocagem em botijão de nitrogênio líquido. A vitrificação em solução de 9,0 M de etileno glicol com envase em tubos eppendorf não foi eficiente para promover altas taxas de sobrevivência embrionária, mas proporcionou segurança biológica aos embriões, durante o armazenamento. / This work was performed with Mus domesticus domesticus embryos to verify the in vitro viability of vitrified embryos using differents volumes of ethylene glycol–based solution. The experiment I consisted of four treatments. The 881 collected embryos were arranged as follows: treatment 1(control): 307 fresh embryos were cultured in vitro in PBSm + 0.4% BSA without being exposed to either dehydration or cryoprotectants agents; treatment 2: 292 embryos were loaded into 0.25 mL french straws containing 10% glycerol + 0.4% BSA in PBSm and after 10 minutes the straws were submitted to the rapid-freezing procedure (Biocool®, controlled freezer); treatment 3:138 embryos were exposed during 2 minutes to a dehydration solution (10% ethylene glycol + 6% BSA in PBSm) and then transferred to the vitrification solution (50% ethylene glycol + 6% BSA in PBSm) in teflon wire with 0.4 mm diameter, 2 cm length and 0.05 mm thickness containing the drop of 1μL volume, and placed into stainless steel box for the storage in LN2; treatment 4:144 embryos were exposed to a dehydration solution (10% ethylene glycol + 6% BSA in PBSm) and after 2 minutes were transferred to the teflon wire, that was previousily loaded with 1μL of the vitrification solution (50% ethylene glycol + 6% BSA in PBSm). Finally, the teflon wires were placed into plastic globets attached to aluminum canes and maintained in LN2. After thawing, the embryos were serially washed in PBSm, and then cultured in PBSm supplemented with 0.4% BSA. The hatched blastocyst rates observed in the treatments were: T1=76.29% (245/307); T2=41.05% (117/292); T3=37.98% (54/138) and T4=26.78% (37/144). In the second experiment, 747 embryos were arranged as follows: treatment 1(control): consisted of 80 fresh embryos cultured in vitro in KSOM medium + 0.4% BSA without being exposed to either dehydration or cryoprotectants agents; treatment 2: 334 embryos were loaded into 0.25 mL french straws containing 10% glycerol + 0.4% BSA in PBSm and after 10 minutes the straws were submitted to the rapid-freezing procedure (Biocool®, controlled freezer); treatment 3: 333 embryos were exposed during 2 minutes to a dehydration solution (10% ethylene glycol + 0.4% BSA in PBSm) and then transferred to the eppendorf tubes loaded with the vitrification solution (50% ethylene glycol + 0.4% BSA in PBSm). After in vitro culture, the hatched blastocysts rates observed were: T1=88.75% (71/80); T2=40.44% (141/334) and T3=19.70% (66/333). Based on these results it is concluded that the embryos of Mus domesticus domesticus submitted to vitrification procedure after being exposed to 9.0 M of ethylene glycol – based solution and loaded in teflon wires were efficient to promote satisfactory embryo survival rates. The survival rate of Mus domesticus domesticus embryos was independent of the LN2 storage procedure. The vitrification procedure after being exposed to 9.0 M of ethylene glycol – based solution and loaded in eppendorf tubes were not efficient to promote high embryo survival rate, but to warrant the embryo’s biologically security during storage in liquid nitrogen.

Reproducao animal : Camundongos

Etileno Glicol

Vitrification

Mouse

Embryos

Load

Ethylene glycol

Ethylene Supply in a Fluid Context: Implications of Shale Gas and Climate Change

Foster, Gillian Joanne

01 November 2018

The recent advent of shale gas in the U.S. has redefined the economics of ethylene manufacturing globally, causing a shift towards low-cost U.S. production due to natural gas feedstock, while reinforcing the industry's reliance on fossil fuels. At the same time, the global climate change crisis compels a transition to a low-carbon economy. These two influencing factors are complex, contested, and uncertain. This paper projects the United States' (U.S.) future ethylene supply in the context of two megatrends: the natural gas surge and global climate change. The analysis models the future U.S. supply of ethylene in 2050 based on plausible socio-economic scenarios in response to climate change mitigation and adaptation pathways as well as a range of natural gas feedstock prices. This Vector Error Correction Model explores the relationships between these variables. The results show that ethylene supply increased in nearly all modeled scenarios. A combination of lower population growth, lower consumption, and higher natural gas prices reduced ethylene supply by 2050. In most cases, forecasted CO2 emissions from ethylene production rose. This is the first study to project future ethylene supply to go beyond the price of feedstocks and include socio-economic variables relevant to climate change mitigation and adaptation.

JEL Q41, Q54

Sensors and Portable Instruments for Postharvest Agriculture

Lerud, Ryan M.

10 June 2019

The sensing needs for the fresh produce industry can be split into two primary stages: during maturation in the field, also referred to as Precision Farming, and during storage and transport of the produce, or Postharvest Storage. This work seeks to improve the accuracy and reliability of commercially available electrochemical and spectroscopic sensors tailored to the sensing needs of the fresh produce industry. For electrochemical sensing, this study proposes the use of an inline filter to remove polar organic compounds, which can interfere with the readings of a platinum-based electrochemical sensor. A 50% improvement in measurement accuracy was achieved when monitoring the storage headspace of a container of apples. For portable spectroscopy instruments, this study suggests improvements for the alignment of the optical bench and the spectral collect protocol. Methods to reduce the influence of environmental noise, such as variability of background light (sunlight in the field) and thermal effects on hardware performance, are presented. This study also presents the first report of the calibration transfer of spectral regressions developed with Karl Norris's Derivative Quotient Method. The motivation for this aspect of research was to develop methods to collect stable and accurate data in the field, which can be used to improve the quality of fresh produce reaching the customer and reduce premature food spoilage.

Electrochemical sensors

Fruit -- Postharvest technology

Ethylene

Food spoilage -- Prevention

Food Science

Physics

Effect of Pt and Ag metals to the degradation of trichloroethylene, ethylene, ethane, and toluene by gas phase photocatalysis

Djongkah, Cissillia Young, Chemical Sciences & Engineering, Faculty of Engineering, UNSW

January 2006

The photocatalytic oxidation of trichloroethylene (TCE), ethylene. ethane and toluene on TiO2, Pt/TiO2 and Ag/TiO2 were investigated in a dedicated reactor set-up operated at room temperature and ambient pressure condition. The gas phase experiments were carried out for both single and binary mixtures of these chemicals to identify the role of Pt and Ag metallisation in the photocatalytic oxidation of different contaminants. In a single contaminant system, the presence of Pt enhanced the oxidation of ethylene, ethane and toluene but detrimental to the oxidation of TCE. In the oxidation of ethylene, Pt enhanced the oxidation by acting as catalyst and as electron sink. However, in ethane oxidation, the enhancement was solely associated to the ability of Pt to act as electron sink. The detrimental effect observed in TCE oxidation was attributed to Pt and Cl interaction, which formed a persistent inorganic chlorine species decreasing the overall Pt/TiO2 photocatalyst performance. Interestingly, Ag did not show any significant effect to the oxidation of any single system degradation. In binary system degradation, where TCE and another organic compound either ethylene, ethane or toluene were degraded simultaneously, Pt always caused a detrimental effect due to its strong interaction with Cl. However, the presence of Ag and Cl gives a more synergetic effect. Ag was found to provide sites to temporarily trap chlorine radicals as AgCl. Under illumination, electrons transferred from Cl to Ag forming chlorine radicals that could react with the surface contaminant enhancing its breakdown and mineralization.

Photocatalysis

metal doping

Ag

Pt

Toluene

TCE

Ethylene

Ethane

UV

Deactivation

Binary mixture

catalysis

Chlorine.

The molecular basis for the initiation of fruit development and parthenocarpy

Vivian-Smith, Adam

January 2001

Parthenocarpy, or seedless fruit development, has an agronomic importance in many horticultural crops. In most fruit, fertilization or seed set usually determines whether fruit growth is sustained. Naturally occurring parthenocarpy results from a genetic lesion that permits fruit to develop in the absence of fertilization and seed development. Parthenocarpy can also be induced artificially with cytokinin, gibberellin or auxin plant growth regulators applied to anthesis pistils. This thesis describes genetic research using Arabidopsis as a model plant to identify integral mechanisms that control parthenocarpy and the initiation of fruit development. The growth and structure of the Arabidopsis pistil was determined post-fertilization. Experiments were designed to understand how plant growth regulators induce Arabidopsis silique (fruit) development in emasculated anthesis stage pistils. Exogenous gibberellin (GA3) induced growth and cellular differentiation most comparable to pollinated pistils. Dependencies on gibberellins during silique development were examined in mutants defective for gibberellin biosynthesis (ga1, ga4-1, ga5-1) or perception (spy-4, gai-1). Although exogenous GAs are effective at inducing parthenocarpy, mutant studies concluded that GAs are not the sole cue for fruit development in Arabidopsis. Mutants blocked in GA perception could develop siliques in response to pollination, auxin, cytokinin but not to exogenously applied gibberellins. Silique structure in pollinated gai-1 and ga5-1 provided strong evidence for a model supporting evidence of an auxin-like signal regulating structural development and that GAs limit anticlinal cellular division. A specialized function for GAI and related GRAS family members in controlling cellular division during fruit development was uncovered. A mutant that forms parthenocarpic siliques without fertilization (fwf), was also characterized. The presence of surrounding floral whorls reduced the extent of parthenocarpic silique formation in fwf. Silique growth in the fwf background was examined when hormone perception, ovule and carpel identity functions were removed genetically. This established that FWF functions independent of GAI-mediated GA perception. Carpel identity conferred by FUL was critical for parthenocarpic silique elongation and ovule development beyond integument initiation, nucellar specification and subsequent morphogenesis, was essential for parthenocarpic silique development in fwf. Silique elongation occurs over a four-day period post-pollination or post-anthesis. This coincides with a similar time period in which fwf ovules remained receptive to fertilization. These observations are congruent with the hypothesis that FWF potentially represses a signal transduction process initiated within the ovule that mediates subsequent transition from carpel to silique development. Further analysis revealed that aberrant testa shape (ats) a mutant defective in integument formation enhanced parthenocarpic development in fwf, indicating that an ovule located repressor other than fwf can function to affect silique formation. Other studies have shown that ethylene can modulate auxin-dependent growth in both aerial and root tissues by altering both polar and lateral auxin transport. The contribution of ethylene perception to signal transduction between ovule and carpel was also genetically assessed. Constitutive ethylene responses, conferred by ctr1-1, enhanced cellular expansion in fwf and also the autonomous silique development in fis-2, which develops autonomous endosperm. ats ctr1-1 and ino ctr1-1 double mutants were also found to be parthenocarpic. This indicates that ethylene perception and integumentary structure play an important role in autonomous silique development, conceivably by changing the polar and lateral movement of an auxin-like signal within the integumentary tissues of the ovule. fwf and ats were fine mapped on chromosome 5 of Arabidopsis. Candidate genes were identified corresponding to both mutations but only the identity of FWF was established. Auxin Response Factor 8 (ARF8) was cloned and sequenced from the fwf mutant background. The gene encodes a protein with a amino-terminal DNA binding domain and a carboxy-terminal protein binding domain which homo- and hetero- dimerizes with other ARF or Aux / IAA class proteins. ARF8 sequence from fwf mutants encoded a mutation in the translation start site. Complementation of fwf plants by the transformation of wild type copies of ARF8 into fwf plants was hampered by reduced transformation efficiency. However wild type L.er and No.O plants transformed with mutant copies of ARF8 were obtained in higher frequency, and these formed parthenocarpic siliques when primary transformants were emasculated. This indicated that an interfering protein is produced from the mutated ARF8 gene that has altered regulatory activity. Sequence analysis indicated this and found that interference resulted from functional activity of the Q-rich and carboxy-terminal domains of the ARF8 protein. This inference is consistent with other published molecular data, which has demonstrated that the carboxy-terminal domain, together with the Q-rich region of selected ARF members, can activate auxin-responses. Thus the FWF / ARF8 protein may have a dual role, repressing carpel growth development through the DNA binding domain and then ensuring activation of silique development through the carboxy-terminal domain. The combined molecular and genetic data has been used to construct models concerning the genetic control of silique development. The first model considers the role of plant hormones and how signals from floral whorls surrounding the carpel and from within the ovule control silique growth. A model is also presented for the control of adaxial growth and development of the outer integument by the INNER NO OUTER gene. Finally the role of FWF and SPY in controlling floral tissue identity and boundary tissue specification is considered in a third model. Modification of the FWF / ARF8 gene could be used as a tool to improve fruit set and retention in horticultural crops, in addition to creating seedless parthenocarpic fruit. / Thesis (Ph.D.)--Agriculture and Wine, 2001.

New nanocomposites based on poly(ethylene-co-vinyl acetate) and multiwall carbon nanotubes : preparation and characterization.

Peeterbroeck, Sophie

15 December 2006

Carbon nanotubes (CNTs) have been a major interest of study since 1991. A panel of properties and phenomena associated with carbon nanotubes due to their special combination of dimension, structure and topology have been investigated in the last years. Recently, it appears interesting to use carbon nanotubes at low loading content to obtain materials with enhanced mechanical and thermal properties. One of the major challenges is actually to disperse easily and individually these nanotubes in polymer matrices to obtain materials with increased properties for different application uses. Ethylene-vinyl acetate (EVA) copolymer is commonly used in cable industry. It is required to introduce high contents of alumina trihydrate (ATH) or magnesium dihydroxide (MDH) as fire retardant, to avoid fire hazards and reduce flammability. But this high mineral loading results in a decrease of the mechanical performances of the materials. This work aims at studying the influence of the incorporation of multiwall carbon nanotubes (MWNTs) on the tensile properties and the fire behavior of EVA nanocomposites. This work demonstrates, on one side, the significant effect of the previous nanotube coating by a thin layer of high density polyethylene (HDPE-coating) on the mechanical behavior of the so-obtained nanocomposites and explain, on the other side, the flame retardant efficiency of MWNTs in EVA nanocomposites. An original mechanism related to the action of the MWNTs during the combustion process is proposed and the effect of the HDE-coating on the cohesion of the residues is discussed.

nanocomposites

Ethylene-vinyl acetate copolymer

carbon nanotubes

tensile testing

fire behavior

Probing Protein Adsorption Modes onto Poly(Ethylene Glycol) Brushes by Neutron Reflection

Schollier, Audrey

18 March 2011

Adsorption of proteins at interfaces has an important role in biotechnological and pharmaceutical applications. Indeed, several undesirable processes are related to protein adsorption, as for example: fouling of contact lenses, clotting on blood contacting devices, triggering inammation around articial organs, diminished circulation time of therapeutic proteins and drug bearing liposomes. Neutral water soluble polymers, such as poly(ethylene glycol) (PEG), are used to repress protein adsorption: by coating the surface with a polymer brush, a "cushion" is created between the protein and the surface, that can reduce, or even completely repress the adsorption. Understanding the mechanism that inhibits the adsorption at interfaces is an active field of research, and could lead to relevant improvements in biomaterials performances and design. A clear understanding of the mechanism of protein adsorption onto polymer brushes is still missing. The first models describing the interactions of a polymer brush with adsorbing particles predicted two adsorption modes: primary adsorption at the grafting surface, and secondary adsorption at the outer edge of the brush (occurring for large cylindrical proteins). Primary adsorption can be repressed by increasing the grafting density of the brush, and secondary adsorption by increasing its thickness, in agreement with the experiments reported in the literature. But experimental evidences (a maximum in the adsorbed amount observed for long brushes) suggested then the existence of a third mode: ternary adsorption within the brush itself, due to attractive interactions between the protein and the brush. Standard techniques can in general only probe the total adsorbed amount. The aim of this work was to separate primary and ternary adsorption isotherms, by using neutron reectivity and deuterated proteins. As neutrons interact differently with hydrogen and deuterium atoms, the contrast between the hydrogenated brush and the deuterated protein is high enough to separate the two contributions. We studied the adsorption of deuterated myoglobin on PEG brushes with different degrees of polymerisation (N = 56, 146 and 770), and as a function of the area per grafted chain. The contribution of primary and ternary adsorption was separated for the different systems, and the adsorbed amount was extracted and the adsorption isotherms compared to the theoretical predictions. The ability to distinguish between the different adsorption modes, and the quantification of their relative contribution to the overall amount of adsorbed proteins, represents a major advance in optimising surface properties. In particular, the occurrence of ternary adsorption onto PEG brushes affects their status as tool for repressing protein adsorption. L’adsorption de protéines aux interfaces a un rôle important pour certaines applications pharmaceutiques ou biotechnologiques. En effet, plusieurs processus indésirables sont liés à l’adsorption de protéines, par exemple l’encrassement de lentilles de contact, la coagulation dans des appareils contenant du sang, l’inflammation d’organes artificiels ou encore la diminution du temps de circulation dans le corps de protéines ou liposomes thérapeutiques. Certains polymères, tels que le polyéthylène glycol (PEG), sont utilisés pour réprimer l’adsorption de protéines : en greffant une brosse de PEG sur la surface, une couche est créée entre la protéine et celle-ci qui diminue, voire même réprime complètement l’adsorption. Comprendre le mécanisme qui entrave l’adsorption aux interfaces est un sujet de recherche actif, qui pourrait mener à des améliorations significatives dans la conception de biomatériaux. À ce jour, la compréhension du mécanisme d’adsorption de protéines sur des brosses de polymère n’est pas claire. Les premiers modèles décrivant les interactions entre brosses de polymères et particules adsorbantes prédisaient deux modes d’adsorption : l’adsorption primaire sur la surface de greffage, et l’adsorption secondaire à l’extérieur de la brosse (pour les grandes protéines cylindriques uniquement). L’adsorption primaire peut-être réprimée en augmentant la densité de greffage de la brosse, et l’adsorption secondaire en augmentant son épaisseur, en accord avec les expériences reportées dans la littérature. Mais d’autres évidences expérimentales (un maximum dans la quantité adsorbée observé pour les brosses longues) ont ensuite suggéré l’existence d’un troisième mode : l’adsorption ternaire à l’intérieur même de la brosse, due aux interactions attractives entre la protéine et la brosse. Les techniques standards peuvent en général mesurer la quantité adsorbée totale. Le but de ce travail était de séparer les isothermes d’adsorption primaire et ternaire, en utilisant la réflectivité de neutrons et des protéines deutérées. Comme les neutrons interagissent différemment avec les atomes d’hydrogène ou de deutérium, le contraste entre la brosse hydrogénée et la protéine deutérée est ainsi suffisant pour séparer les deux contributions. Nous avons étudié l’adsorption de myoglobine deutérée sur des brosses de PEG avec différents degrés de polymérisation (N = 56, 146 and 770), en fonction de l’aire par chaîne Σ. La contribution des adsorptions primaire et ternaire put être séparée pour les différents systèmes, et les quantités adsorbées extraites pour finalement comparer les isothermes d’adsorption aux prédictions théoriques. La possibilité de distinguer les différents modes d’adsorption, et la quantification de leur contribution relative à la quantité totale de protéines adsorbées représente une avancée majeure dans l’optimisation des propriétés des surfaces. L’adsorption ternaire dans les brosses de PEG en particulier remet en question leur utilisation pour réprimer l’adsorption de protéines.

poly(ethylene glycol)

polymer

brush

protein

PEG

adsorption

neutron reflection

polymère

réflection de neutrons

protéine

brosse

Crystallization in Constrained Polymer Structures : Approaching the Unsolved Problems in Polymer Crystallization

Núñez, Eugenia

January 2006

The knowledge regarding certain issues in polymer crystallization e.g. the possible existence of short–lived mesophases remains inconclusive due to experimental limitations. Polymers undergo chain folding upon crystallization, which introduces some complications that are not found in crystallization of low molar mass materials. Chain–folded crystals are far from their equilibrium shape and they rearrange rapidly at the crystallization temperature. This, together with the slow experimental techniques traditionally used, impedes the observation of the originally formed structures. To approach this problem, molecularly constrained polymer structures (in which the crystallizing chains are fixed at one end whereas the other end is free to move) have been studied by X–ray diffraction, differential scanning calorimetry, polarized optical microscopy, transmission electron microscopy and atomic force microscopy. The crystallization studies performed in star–branched polyesters showed that the dendritic cores have a pronounced effect on the crystallization of the linear poly(ε–caprolactone) (PCL) arms attached to them. The star–branched polymers showed slower crystal rearrangement, higher equilibrium melting point, higher fold surface free energy, moderately lower crystallinity, and a greater tendency to form spherulites in comparison with linear PCL. The crystal unit cell was the same in both linear and star–branched PCL. Single crystals of the star–branched polymers were more irregular and showed smoother fold surfaces than linear PCL crystals. No sectorial preference was observed in the crystals of the star–branched polymers upon melting while the single crystals of linear PCL showed earlier melting in the {100} sectors than in the {110} sectors. Some of the differences observed can be attributed to the dendritic cores, which must be placed in the vicinity of the fold surface and thus influence the fold surface structure, the possibility of major crystal rearrangement and the presence of a significant cilia phase during crystal growth causing diverging crystal lamellae and consequent spherulite formation. The attachment of the many crystallizable chains to a single core reduces the melt entropy, which explains the higher equilibrium melting point of star–branched PCL. The crystallization behavior of a series of poly(ethylene oxybenzoate)s was also studied. The polymers showed a profound tendency for crystal rearrangement during melting even at high heating rates. The Hoffman–Weeks extrapolation method was found to be unsuitable to calculate the equilibrium melting point of the samples studied because the melting point vs. crystallization temperature data were sensitive to the variations in crystallisation time, which led to significant variations in the equilibrium melting points obtained. / QC 20100914

Crystallization

Constrained structures

poly(ε–caprolactone)

poly(ethylene oxybenzoate).

Polymer chemistry

Polymerkemi

Biomimetic PEG Hydrogels for ex vivo Hematopoietic Stem Cell Expansion

January 2012

Hematopoietic stem cells (HSCs) are commonly used in the treatment of blood cancers, like leukemia, and other cancers where radiation or chemotherapy damages the native HSC population. The development of a novel system to study and maintain HSCs ex vivo would give researchers and clinicians the ability to investigate the basic biological processes of HSCs, improve current treatment regimens, and explore their use in new therapies. The work in this thesis focuses on the development of a synthetic PEG hydrogel scaffold that accurately mimics aspects of the HSC microenvironment and can expand clinically relevant HSC populations. PEG hydrogel well surfaces were covalently functionalized with bioactive factors known to be critical in controlling HSC fate in vivo. In initial studies, 32D cells, a myeloid progenitor, were cultured in the wells for 6 days. On surfaces with the adhesive RGDS peptide sequence, 32D cell adhesion increased concurrently with RGDS surface concentrations. With the immobilization of two niche cytokines, SCF and SDF1α, onto hydrogel surfaces, 32D cells demonstrated significant increases in adhesion and spreading. These results confirmed that hematopoietic cell behavior could be controlled through the design of the bioactive PEG scaffold. In studies with a primary hematopoietic cell population (c-kit + , lin - ), the effects of bioactive molecules on cell expansion and differentiation were investigated after 2 weeks in culture. The adhesive peptides sequences, RGDS and CS1, and four niche proteins, SCF, SDF1α, JAG1, and IFNγ, were covalently tethered to hydrogel well surfaces. Primary cells proliferated significantly on gels containing SCF and IFNγ though only SCF was capable of preventing HSC differentiation. Cells cultured on surfaces functionalized with JAG1 and SDF1α did not proliferate extensively, but they were able to maintain primitive HSC populations. Primary c-kit + cells were also encapsulated within biodegradable PEG hydrogels and cultured for 2-5 weeks. Cells remained viable for 5 weeks in culture, and preliminary results indicated minimal cell differentiation. In this work, biomimetic PEG hydrogels were successfully employed to expand HSC populations in both two and three dimensions. The ability to generate large populations of primitive HSCs ex vivo has broad clinical and research implications.

Applied sciences

Poly(ethylene glycol)

Biomimetics

Hydrogels

Stem cells

Encapsulation

Biomedical engineering

Electrochemical Promotion of Gold Nanoparticles Supported on Yttria-Stabilized Zirconia

Kim, Jong Min

23 November 2011

The feasibility of highly dispersed gold nanocatalyst supported on yttria-stabilized zirconia (YSZ) for the model reactions of C2H4 and CO oxidation is demonstrated for the first time. Gold nanoparticles are synthesized on YSZ powder by chemical reduction of the precursor salt in the mixture of ethanol, water and polyvinylpyrrolidone (PVP). Resulting metal loading of the catalysts are 1 wt.% with average particle sizes ranging from 6 to 9 nm. Results of CO and C2H4 oxidation display catalytic activity at 65 0C and 25 0C for CO and C2H4 oxidation, respectively. The catalytic properties of the catalysts are different due to their average particle size. Electrochemical Promotion of Catalysis (EPOC) of C2H4 oxidation is demonstrated. Application of constant potential difference between two electrodes in the bipolar electrochemical cell led to increase in C2H4 conversion. A proposed mechanism explains the bipolar EPOC phenomenon through formation of O2- flux across the electrochemical cell, resulting in the change of Work Function of gold nanoparticles placed in between the electrodes and is electronically isolated.

c2h4 oxidation

electrochemical promotion

epoc

ethylene oxidation

wireless

nemca

nanocatalyst

gold nanoparticle

ysz

yttria stabilized zirconia