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Processing optimalization of biodegradable starch based packaging and its characterization for adaptation on production technology
Krahulová, Veronika ; Ondreáš, František (referee) ; Lepcio, Petr (advisor)
This diploma thesis focuses on the problematics of preparation of biodegradable starch based packaging. The aim of the thesis is to optimize the preparation and verify the characteristics for further adaptation and production technologies. The films consisted of starch, PVA and glycerol. Four types of starches, three types of PVA and different ratios of glycerol were tested. Films were prepared by casting with glycerol as a plasticizer, instead of distilled water, to reduce the energy cost of the preparation. The mechanical properties of the films were tested as well. The experimentally determined values of elongation at break and tensile strength of the wheat starch films were compared with a semiempirical model. Results revealed that the preparation of thermoplasticization of starch with glycerol leads to a considerable increase in elongation at break but at the same time to a marked decrease in tensile strength compared to the preparation from solution. The rheological properties of the prepared films were also investigated. Infrared spectroscopy (FTIR), thermogravimetric analysis (TGA) and differential scanning calorimetry (DSC) were used to study the structure of the films.
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Application of thermophilic Culture for Organic Compounds Biodegradation
Piechová, Jana ; Burdychová, Radka (referee) ; Babák, Libor (advisor)
The aim of this work is focused on biodegradability study of modified polyurethane materials (foams and foils) in glukose medium and biodegradation of whey. The biodegradability was tested with using mixed thermophilic aerobic bacterial culture of the Bacillus and Thermus genera. The cultivations were practised in the fermentor and in Erlenmayer flasks in a heated shaker. Maximal reduction of COD and culture growth has been achieved by biodegradation of polyuretane in the fermentor. Main effect of degradation was abiotic destruction of PUR materials and consequent utilization of degradation products by bacterial culture. These tests indicated that the best modification agent for biodegradation was 10% carboxymethyl cellulose. The polyurethane foam was more decomposed then the polyurethane foil. Biodegradation of whey without proteins in the fermentor was detected decrease of CHSK and lactose concentration about 50 % in 20th hour. Optimal conditions for whey biodegradation with the thermophilic bacterial culture were pH 6,5 and temperature 60 °C.
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Study on biotechnological potential of thermophilic gram-positive bacterium Brevibacillus sp. Bz
Filimonova, Anastasiia ; Obruča, Stanislav (referee) ; Pernicová, Iva (advisor)
Předmětem předložené diplomové práce je studium biotechnologického potenciálu termofilní grampozitivní bakterie Brevibacillus borstelensis BZ. Teoretická část obsahuje obecnou charakterizaci termofilních organismů a jejich termozymů. Popisuje také adaptivní molekulární mechanismy, které zajišťují termostabilitu těchto proteinů. Závěr teoretické části je věnován biodegradaci odpadních substrátů a polymerů na bázi přírodních a fosilních zdrojů. První část experimentální práce se zabývá produkcí hydrolytických enzymů na různých původních zdrojích a odpadních substrátech. Díky intenzivní enzymatické produkci na původních zdrojích je Brevibacillus borstelensis BZ považován za velmi slibného producenta termostabilních enzymů, konkrétně xylanáz a celuláz. Testovaný bakteriální kmen BZ byl schopen produkce termostabilních enzymů i na odpadních substrátech. Na vybraných substrátech kmen BZ přednostně produkoval xylanázy. Díky tomu byla xylanázám věnována zvláštní pozornost, kdy bylo testováno teplotní a pH optimum. Závěrem experimentální práce byla testována schopnost bakterie Brevibacillus borstelensis BZ degradovat vybrané polymery na bázi přírodních a fosilních zdrojů. Kmen BZ poskytl nový pohled na biologický rozklad polyethylentereftalátu (PET), amorfní frakce kyseliny polymléčné (PLA), semikrystalické PLA a polyhydroxyalkanoátů (PHA). Pozorováním povrchu PET fólie skenovacím elektronovým mikroskopem (SEM) se potvrdilo zdrsnění materiálu, přítomnost rýh a naprosté pronikání bakterie skrz fólii. Pokud jde o polymery na bázi přírodních zdrojů, PHA granule byly zcela degradovány. Studiem morfologie povrchu obou zmíněných PLA bylo prokázáno jasné zhoršení jejich struktury přítomností jam a trhlin na povrchu polymerů.
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Influence of biodegradation of polyhydroxyalkanoates on soil properties and composition
Denková, Pavla ; Doležalová Weissmannová, Helena (referee) ; Kučerík, Jiří (advisor)
Biodegradable plastics are presented as a promising replacement for synthetic polymers. In soil, they are expected to be fully degraded by micro-organisms within a short time and to be inherently harmless to the environment. However, this assumption needs to be verified, and it is important to pay attention to the impact on soil´s biota as well as the effect of the biodegradation process could have on soil properties, composition and structure. In this work was studied the effect of biodegradation of poly(R-3-hydroxybutyrate), (P3HB), belonging to the group of polyhydroxyalkanoates, on the structure and physicochemical properties of soil. P3HB particles were mixed in different concentrations with soil in which biodegradation experiments were carried out under different conditions - i.e. with and without growing plant, with and without nitrogen fertilization. After 90 days, were soil analyzed. Thermogravimetry was used to determine the amount of residual non-degraded micro-bioplastics and to determine the effect of biodegradation on the properties of soil organic matter. Differential scanning calorimetry provided information on the effect of biodegradation on the evaporation enthalpy of adsorbed water from the soil, while the amount of water in the soil was also determined. Furthermore, the effect on field water holding capacity was determined and sieve analysis of individual samples was performed to characterize the effect of biodegradation on soil particle size distribution. Biodegradation conditions were shown to affect not only the rate of biodegradation but also some soil parameters. As expected, biodegradation of P3HB was proved to be faster in a nutrient-rich environment. In contrast, lack of nitrogen in soil with growing plant caused a decrease in the evaporation enthalpy of water and a reduction in the amount of water in soil, which can lead to easier soil drying and cause stress conditions for plant growth. Increased soil particle aggregation was observed in all sample series with P3HB compared to soils without P3HB addition.
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Biodegradabilní materiály a jejich vliv na životní prostředí
Mrkvičková, Klára
Bachelors thesis is focused on biodegradable materials and their impact on the environment. In the literature section, biopolymers are first divided into groups according to biodegradability and sources. Finally, some industries in which biopolymers are used and the possibilities for removal are presented. At the end of the literature search, the work focused on the possible positive and negative impacts of biopolymers on the environment and life cycle assessment of these materials. Standards, certifications, and other environmental labels are also mentioned. In the practical part, an experiment was carried out with the decomposition of wet wipes under the conditions of a home compost. Wet wipes with a certificate of compostability in home compost and wet wipes without a certificate that were labelled as 100 % biodegradable by the manufacturer were examined. The goal was to verify the biodegradability of both products and compare their decomposition success rates.
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Kompostování bioplastů
Kořínková, Aneta
The final work deals with research on the behaviour of various bioplastic materials placed in composting base under laboratory conditions and subsequent assessment of the phytotoxic effects of individual composts. Composting was carried out on the basis of modified standard ČSN EN 14045 and knowledge from standard ČSN EN 14046. The determination of chronic phytotoxic effects followed the modified standard ČSN EN 13432 and acute phytotoxicity was assessed using the Phytotoxkit test. Following completion of the composting process, decomposition was observed for the certified vegetable starch-based sample, two other samples without certification, but marked as 100% degradable, showed no evidence of decomposition. Various indicator organism growth inhibition values were observed, with chronic toxicity testing in the range of 3.4-20.9%, and phytotoxkit testing two of the samples showed a stimulating effect. Different bioplastic materials have achieved different results and represent a different level of potential environmental burden.
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Biodegradace azobarviv působením hub bílé hniloby
Bírošíková, Paulína
White rot fungi, belonging to wood decay fungi have the ability to degra-de complex aromatic structures such as lignin or pollutants with an aromatic structure (tetracyclines, endocrine disruptors) via extracellular ligninolytic enzymes. Azo dyes are synthetic dyes containing aromatic rings with bonded substituents lin-ked by an azo group. Fungi are able to degrade these structures, whereas decrease of dye is observed, called decolorization. The aim of this bachelor's thesis is to de-termine the degradation ability of three types of azo dyes (methylene red, tartrazine and azorubin) using ten types of white rot fungi. Cultivation of individual fungi with the dyes was carried out for twenty-four days, during which the absorbance was monitored using a UV/VIS spectrophotometer at intervals of every other working day. The colour loss was calculated from the measured values and the decoloriza-tion values were expressed graphically as a percentages. The selected fungi showed the greatest decolorization of tartrazine on the second day of the experiment, an average of 89%, except for the fungus Fomes fomentarius, for which dye decoloriza-tion was not observed. In contrast, the least degraded dye was azorubin, an average of 37% at the end of the experiment for most fungi species. Methylene red showed the most stable decolorization trend, with an average of 77% at the end of the me-asurement. The effect of decolorization was influenced by the structure of the azo dyes and the efficiency of specific fungal species.
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Diversity, ecology, and biotechnological potential of yeasts associated with bark beetles
Havlíček, Václav ; Kolařík, Miroslav (advisor) ; Novotný, David (referee)
Bark beetles (Coleoptera; Scolytinae) attack woody plants, which is why they are considered pests from a human perspective. They owe their evolutionary success, among other factors, to numerous symbioses with microorganisms, with fungi playing a significant role. The mycobiome of bark beetles is dominated by yeasts, which, nevertheless, are widely overlooked. Intestinal yeasts not only from Ips typographus but also from other species of bark beetles have potential for future biotechnological applications. The aim of this study was to examine their diversity and physiological activities, which will help clarify their ecological role and biotechnological potential. Collections were conducted in the Czech Republic from larvae of the spruce bark beetle Ips typographus and from various species of subcortical insects in Kenya. Yeasts were identified and taxonomically classified based on rDNA sequencing. A total of 133 yeast strains belonging to 37 species were identified, including 9 species that could not be identified and belong to previously undescribed species and in two cases also genera. A total of 133 yeast strains belonging to 37 species were identified, including 9 species that could not be identified and belong to previously undescribed species and in two cases also genera. The most frequently...
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Employment of thermophilic bacteria for biodegradation of synthetic and natural polymers
Csölle, Eduard ; Sedlář, Karel (referee) ; Obruča, Stanislav (advisor)
This bachelor’s thesis deals with the employment of thermophilic bacterium Schlegelella thermodepolymerans for biodegradation of selected polymers, namely poly(3-hydroxybutyrate) (PHB), polylactic acid (PLA), and poly(butylene adipate-co-terephthalate) (PBAT). The theoretical part focuses on the properties and origin of these bioplastics, the characteristics of the studied bacteria, and the general course of the biodegradation process. The experimental part discusses the twenty-day cultivation of three tested strains in the presence of the mentioned polymers and the subsequent evaluation of the degradation rate of these materials. The greatest increase in biomass content was observed by spectrophotometry for strain DSM 15344 when cultured on PHB. With blank samples (without polymers), it was shown that for significant growth, the bacteria had to truly utilize the polymers present. Gravimetric analysis of biomass content confirmed that PHB was the most suitable substrate for cultivation. The highest mass losses were recorded for PHB and were around 30 % across all three strains. For strain LMG 21645, the mass has decreased by almost 33 %. The weight losses of PLA and PBAT were considerably lower. Nevertheless, the most significant molecular weight loss was observed by SEC-MALS for PLA, reaching approximately 80 % for strain DSM 15264. SEM analysis of the polymer surface confirmed that the biodegradation of PHB occurs by enzymatic surface erosion. In contrast, the PLA and PBAT samples did not show any signs of biodegradation.
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Biodegradation of 3D printed composites based on poly(3-hydroxybutyrate)
Gazdová, Nikol ; Menčík, Přemysl (referee) ; Melčová, Veronika (advisor)
This bachelor thesis deals with the biodegradation of 3D printed bodies composed of poly(3- hyroxybutyrate), polylactic acid, bioceramics and plasticizer. These components were selected for their biocompatibility and properties that could be used in tissue engineering as a temporary, absorbable bone tissue replacement. The main objective was to investigate the effect of the individual constituent bodies on the biodegradation itself. Biodegradation was carried out at 37 °C in a solution simulating the ionic concentration of blood plasma. Samples were sequentially withdrawn at monthly intervals for five months. To evaluate the results, 2 methods were used, weight change and compression test, where the strength of each body was evaluated. From the evaluation of the data it was not possible to reach a uniform result on which substance influences biodegradation the most, because it always depended on the ratio of the other substances. To investigate the effect of poly(3-hydroxybutyrate) and polylactic acid on the rate of biodegradation, mixtures of RP9, RP10 and RP15 were compared. It showed that a higher polylactic acid and lower poly(3-hydroxybutyrate) content had a significant positive effect on the biodegradation rate, as the difference between the weight loss for the RP9 blend with the highest poly(3-hydroxybutyrate) content and the RP10 blend with the highest polylactic acid content was 8.37% for solid bodies and 4.13% for porous bodies. For strength, the difference was 73.32% and 73.65% for the solid and porous bodies, respectively. Observing the effect of bioceramic content on the RP11, RP12 and RP15 mixtures, we concluded that this effect was almost negligible on the biodegradation rate The difference in weight loss between the RP11 mixture with the lowest bioceramic content and the RP12 mixture with the highest bioceramic content was only 1, 68 % for solid bodies and 0.99 % for porous bodies, while mixture RP15 showed the highest biodegradation rate despite having a medium value of bioceramics in the mixture. For the mechanical properties, this then amounts to a difference of 10.4% for the solids and 7.57% for the porous bodies. When comparing the effect of plasticizer for mixes RP13, RP14 and RP15, the effect was more on the strength drop, where the difference in strength drop for mix RP13 with the lowest plasticizer content and RP14 with the highest plasticizer content was different by 20.3% and 18.16% for the solid and porous body, respectively. The decrease in weight was then different by 4.1 % and 0.83 % for the solid and porous body, respectively. Finally, bioceramics from different companies emerged as an important element for the biodegradation rate. Hydroxyapatite from Applichem was the best biodegraded and hydroxyapatite from CN Lab was the worst. The difference for weight loss was 17.35% for the solid and 5.93% for the porous body. The strength loss was then different by 55.6% for the solid body and 33.38% for the porous body.
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