Enzymatická hydrolýza odpadní papíroviny - zdroj suroviny pro výrobu kapalných biopaliv / Enzymatic hydrolysis of waste paper pulp - source of raw material for production of liquid biofuels

Brummer, Vladimír

January 2010

This master’s thesis is aimed at process of enzymatic hydrolysis of lignocellulosic material – waste paper as a source of raw material for production of liquid biofuels. In the theoretical part of this work are summarized previously used methods of hydrolysis and lignocellulosic materials used for the process of hydrolysis as a source of fermentable sugars for fermentation technology. The different types of waste paper are evaluated from the composition and usability with consideration to the papermaking process in order to select the appropriate type of waste paper for the enzymatic hydrolysis process. In the next part of this work are suggested technological premises and procedures for the preparation of raw materials and the subsequent enzymatic hydrolysis of these pre–treated materials. In the experimental part were optimized parameters of enzymatic hydrolysis using the Novozymes company enzyme package. Enzymatic degradation of cellulose to reducing sugars was observed using Somogyi – Nelson method. For the verification of hydrolysis conditions were used model materials with high cellulose content – pulp and filter paper. Conditions, which seems to be the best after testing on the model materials, were verified on specific waste paper materials – offset cardboard, recycled paper, matte MYsol paper and for comparison again on model materials – pulp and filter paper. The highest yields was achieved with the use of cardboard, which was further tested using various combinations of pretreatment to material for purpose of increase the yields of hydrolysis.

Enzymatická hydrolýza odpadní lepenky s využitím metody SSF - zdroj suroviny pro výrobu kapalných biopaliv. / Enzymatic hydrolysis of waste cardboard using the SSF method - a source of raw materials for the production of liquid biofuels.

Hlaváček, Viliam

January 2013

This master’s thesis discusses the useof enzymatic hydrolysis process of waste cardboard using simultaneous saccharification and fermentation (SSF) as a source of raw materials for production of liquid biofuels. This thesis is based on theses written by Ing. Brummer and Ing.Lepař.Thus, results gained in these works have been used and also further developed. The theoretical part summarizes the reasons for further development of SSF method and discusses, as well, the achievements reached in the processing of lignocellulosic waste materials by the SSF method so far.This section also discusses the general characteristics of lignocellulosic materials and also of the cellulolytic enzymes. It focusses also on individual pretreatment methods of lignocellulosic material and options of increasing the yield of the whole process. The experimental part verifies the particular results reached in previous theses and at the same time a further optimization of the method has been carried out because of the transfer of the whole process into a fermenter. Cardboard was set as the substrate for the experiments as it was evaluated by Ing. Brummer as the best one for enzymatic hydrolysis which was carried out by enzymes from Novozymes®. Parameters such as temperature, pH and kind of used buffer, the loading concentration of substrate and enzymes, were set according to the thesis of Ing. Lepař, which was aimed to their optimization. The SSF process done in fermenter of 2.0 l volume confirmed the previous results and furthermore it has been more effective through optimization of the added inoculum volume. It has been confirmed that the best substrate is cardboard finely grinded by vibrating mill. Also experiments with added nutrients had been done as an effort to increase the ethanol concentration, but these haven’t resulted insatisfying results. The maximal concentration of ethanol was 23,49 g/l, which was achieved after further optimization of various conditions. This result equals to experimental yield of 84,79 %.

Elaboration contrôlée de membranes à base de chitosane pour le traitement de l'eau / Elaboration of chitosane membrane for water treatment

Wlodarczyk, Damien

16 December 2015

Le travail de thèse présenté dans ce manuscrit a pour objectif de mettre en place un nouveau procédé d’élaboration de membranes à base de chitosane pour le traitement d’effluents acides contenants des ions métallique. Soluble en milieu aqueux acide, le chitosane présente la propriété de gélifier lorsque le pH devient basique, ce qui permet d’envisager l’élaboration de membrane sans solvant organique contrairement aux polymères synthétiques classiques. Par ailleurs, ce travail de thèse s’est intéressé à un procédé original de gélification par voie enzymatique, dans lequel la gélification in-situ de la solution de chitosane permet une structuration contrôlée de la membrane contrairement aux procédés classiques qui donnent lieu à un front de gélification. Une étude des cinétiques de gélification en fonction des paramètres d’élaboration (température et concentration en urée) a mis en évidence que seule la température est significativement influente sur le temps de gélification dès lors que la concentration en urée n’est pas limitante. Un modèle a été mis en place pour décrire la gélification enzymatique du chitosane afin de comprendre les mécanismes des cinétiques réactionnelles et de transferts lors de la formation du gel. Des membranes de chitosane ont ainsi été élaborées par le procédé par voie enzymatique, la porosité de ces membranes ayant été générée avec un agent porogène (PEG 6000) et une réaction d’acétylation du chitosane ayant permis d’obtenir des membranes insolubles en milieu acide. Les membranes obtenues ont été caractérisées en termes de morphologie et de propriétés fonctionnelles (filtration, sorption du Cu(II) comme élément métallique modèle). / The Ph-D work presented in this manuscript aims to develop a new process for elaborate chitosan membranes for treatment of acidic media containing metal ions. Soluble In acidic aqueous media, gelation occurs when the pH becomes basic, allowing elaboration of membrane without the use of organic solvents unlike classical synthetic polymers. Moreover, this Ph-D work has focused on an original process enzymatic gelation which the in-situ gelation of chitosan solution allows a controlled structuration of the membrane unlike conventional processes which leads to a front gelling.A study of gelation time as a function of the elaboration parameters (temperature and urea concentration) highlighted that only the temperature is a main parameter on gelation time since the urea concentration is not limiting. A model was developed to describe the chitosan enzymatic gelation in order to understand mechanisms of reaction kinetics and transfers during the gel formation.Chitosan membranes have been prepared by enzymatic process, the porosity of such membranes have been generated with a blowing agent (PEG 6000) and an acetylation of chitosan having yielded insoluble membranes in acid medium. The resulting membranes were characterized by their morphology and functional properties (filtration, sorption of Cu (II) as model metal element).

GélificatIon enzymatique

Ultrafiltration

Sorption

Enzymatic gelation

Ultrafiltration

Sorption

The human Klotho VS variant: focus on the processing and function of the V, S and VS isoforms

Tucker Zhou, Tracey Beth

24 September 2015

Klotho (KL), an anti-aging protein, attracted interest in the aging field because of the dramatic phenotype of KL deficient mice and its connection to signaling pathways implicated in aging. The KLVS variant consists of the F352V (KLV) and C370S (KLS) substitutions. It was detected in genome wide association studies (GWAS) that linked it to alterations in longevity and disease risk. The molecular mechanism(s) underlying these associations are unknown. To understand how KL increases the risk of age-related diseases, the studies in this dissertation investigated whether expression of the KLVS variant, when compared to wildtype (KLWT), displays differences in processing, protein-protein interactions and enzymatic activity. Differences in processing were evaluated by studying changes in shedding, half-life and plasma membrane localization of KL variants. The decrease in KLV shedding, as measured by the intracellular: extracellular ratio, were explained by a decreased half-life. This decreased half-life is potentially due to decreased KLV plasma membrane localization, which is attenuated by co-expression of dominant negative dynamin, suggesting a role of endocytosis in these differences. To assess whether there are changes in KLVS protein-protein interactions, differences in dimerization were measured by Blue Native gel electrophoresis and cross-linking. KLV dimerization was increased while KLS and KLVS variants decreased dimerization. Co-immunoprecipitation of tagged KL assessed whether these changes were due to alterations in homodimerization. The presence of KLVS in dimers decreased the levels of immunoprecipitated KL suggesting KLVS decreases homodimerization. Changes in heterodimerization of KLVS with fibroblast growth factor receptor (FGFR) 1c were also investigated through co-immunoprecipitation. KLVS increased heterodimerization with FGFR1c. Addition of FGF23, for which KL is a co-receptor, showed that KLVS increases FGF signaling downstream of FGFR1c. To determine differences in enzymatic activity of KLVS, 4-metylumbelliferyl-beta-D-glucuronide was used to measure alterations in glucuronidase activity. Results showed that KLVS had decreased enzymatic activity compared to KLWT. These findings are the first to show that KLVS leads to differences in function as demonstrated by decreased homodimerization and enzymatic activity and increased heterodimerization with FGFR1c. Given the association of KLVS with disease and longevity, these results suggest that these functions are integral in KL's anti-aging role in humans.

Molecular biology

Aging

Dimerization

Enzymatic activity

FGFR signaling

Genetic polymorphisms

Studies on enzymatic synthesis of optically active amides for pharmaceutical intermediates / 医薬品として有用な光学活性アミド類の酵素合成に関する研究

Nojiri, Masutoshi

26 March 2018

京都大学 / 0048 / 新制・論文博士 / 博士(農学) / 乙第13178号 / 論農博第2857号 / 新制||農||1061(附属図書館) / 学位論文||H30||N5100(農学部図書室) / (主査)教授 小川 順, 教授 栗原 達夫, 教授 三上 文三 / 学位規則第4条第2項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

enzymatic synthesis

amide hydrolysis

amidase

imidase

desymmetrization

610

Inhibition of enzymatic browning in food products using bio-ingredients

Crumière, Fabienne.

January 2000

No description available.

Polyphenol oxidase -- Inhibitors.

Esterases.

Aspergillus niger.

Metallothionein.

Enzymatic browning.

Digestive proteases from the stomachless cunner fish (Tautogolabrus adspersus) : preparation and use as food processing aid

Kyei, Mary Abena.

January 1997

No description available.

Polyphenol oxidase -- Inhibitors.

Trypsin.

Cunner.

Pectin.

Enzymatic browning.

Characterization of a polyphenol esterase from Aspergillus niger and its role in the inhibition of tyrosinase

Madani, Wigdan.

January 2000

No description available.

Esterases.

Polyphenol oxidase -- Inhibitors.

Enzymatic browning.

Aspergillus niger.

Inhibition of tyrosinase activity by metallothionein from Aspergillus niger

Hossain, Abzal

January 1999

No description available.

Polyphenol oxidase -- Inhibitors.

Metallothionein.

Enzymatic browning.

Aspergillus niger.

Design and Synthesis of Multifuntional Poly(Ethylene Glycol)S Using Enzymatic Catalysis for Multivalent Cancer Drug Delivery

Seo, Kwang Su

01 May 2012

No description available.

Polymers

Poly(ethylene glycol)

enzymatic catalysis

multifunctional macromolecules