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Evaluation of parameters influencing oxygen transfer efficiency in a membrane bioreactorHu, Jing January 2006 (has links)
Thesis (M.S.)--University of Hawaii at Manoa, 2006. / Includes bibliographical references (leaves 96-99). / xiii, 99 leaves, bound ill. (some col.) 29 cm
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Perfusion bioreactor for tissue-engineered blood vesselsWilliams, Chrysanthi 12 1900 (has links)
No description available.
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Momentum transfer inside a single fibre capillary membrane bioreactorGodongwana, Buntu January 2007 (has links)
Thesis (MTech (Chemical Engineering))--Cape Peninsula University of Technology, 2007. / Innovation in biotechnology research has resulted in a number of fungi being identified for
diverse industrial applications. One such fungus, which is the subject of this study and has been
one of the most intensively studied, is Phanerochaete chrysosporium. Much research has been
done in developing optimized membrane bioreactor systems for the cultivation of these fungi
because of their potent industrial applications. This research, however, has been hampered by the
lack of a thorough understanding of the kinematics of flow, as well as the dynamics of the flow
through these devices. Previous analyses of momentum transfer in membrane bioreactors have
been entirely based on horizontally orientated bioreactor systems, and ignored the different
modes of operations of membrane bioreactors. These models also ignored the osmotic pressure
effects brought about by the retention of solutes on the membrane surface.
In this study, analytical and numerical solutions to the Navier-Stokes equations for the
description of pressure, velocity, and volumetric flow profiles in a single fibre capillary
membrane bioreactor (SFCMBR) were developed. These profiles were developed for the lumen
and shell sides of the SFCMBR, taking into account osmotic pressure effects, as well as gel
and/or cake formation on the lumen surface of the membrane. The analytical models developed
are applicable to horizontal and vertical systems, as well as dead-end, continuous open shell,
closed-shell, and shell side crossflow modes.
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Design of a packed-bed fungal bioreactor : the application of enzymes in the bioremediation of organo-pollutants present in soils and industrial effluentFillis, Vernon William January 2001 (has links)
Thesis (MTech (Chemical Engineering))--Peninsula Technikon, 2001 / Certain fungi have been shown to excrete extracellular enzymes, including peroxidases,
laccases, etc. These enzymes are useful for bioremediation of aromatic pollutants
present in industrial effluents (Leukes, 1999; Navotny et aI, 1999).
Leukes (1999) made recent significant development in the form of a capillary membrane
gradostat (fungal) bioreactor that offers optimal conditions for the production of these
enzymes in high concentrations. This system also offers the possibility for the polluted
effluent to be treated directly in the bioreactor. Some operating problems relating to
continuous production of the enzymes and scale-up of the capillary modules, were,
however, indentified.
In an attempt to solve the above-mentioned identified problems the research group at
Peninsula Technikon considered a number of alternative bioreactor configurations. A
pulsed packed bed bioreactor concept suggested by Moreira et at. (1997) was selected for
further study. Their reactor used polyurethane pellets as the support medium for the
fungal biofilm and relied upon pulsing of the oxygen supply and recycle of nutrient
solution in order to control biomass accumulation. These authors reported accumulation
due to the recycle of proteases that were believed to destroy the desired ligninases. We
experimented with a similar concept without recycle to avoid backrnixing and thereby
overcome protease accumulation. In our work, a maximum enzyme productivity of 456
Units.L1day·1 was attained. Since this was significantly greater than the maximum
reported by Moreira et aI, 1997 (202 Units.L-1day-I) it appeared that the elimination of
recycle had significant benefits.
In addition to eliminating recycle we also used a length / diameter (L / D) ratio of 14: 1
(compared with 2.5: 1 used by Moreira et aI, 1997) in order to further reduce backrnixing.
Residence time distributions were investigated to gain insight into mechanisms of
dispersion in the reactor.
It was found that the pulsed packed bed concept presented problems with regard to
blockage by excess biomass. This led us to consider the advantages of a fluidized bed
using resin beads. Accordingly, growth of fungi on resin beads in shake flasks was
investigated with favorable results. An experimental program is proposed to further
investigate the fluidized bed concept with a view to extending the operation time of the
bioreactor.
From our literature survey to date, packed bed fungal bioreactors are still the best reactor
configuration for continuous production ofligninolytic enzymes.
An interesting study of the application of laccases to the degradation of naphthalene and
MTBE is described in an addendum to this thesis.
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Design and operation of a laboratory scale photobioreactor for the cultivation of microalgaeBhola, Virthie January 2011 (has links)
Submitted in fulfilment of the requirements of the Degree of Master of Technology: Biotechnology, Durban University of Technology, 2011. / Due to greenhouse gas emissions from fossil fuel usage, the impending threat of global climate change has increased. The need for an alternative energy feedstock that is not in direct competition to food production has drawn the focus to microalgae. Research suggests that future advances in microalgal mass culture will require closed systems as most microalgal species of interest thrive in highly selective environments. A high lipid producing microalga, identified as Chlorella vulgaris was isolated from a freshwater pond. To appraise the biofuel potential of the isolated strain, the growth kinetics, pyroletic characteristics and photosynthetic efficiency of the Chlorella sp was evaluated in vitro. The optimised preliminary conditions for higher biomass yield of the selected strain were at 4% CO2, 0.5 g l-1 NaNO3 and 0.04 g l-1 PO4, respectively. Pulse amplitude modulation results indicated that C. vulgaris could withstand a light intensity ranging from 150-350 μmol photons m-2s-1. The pyrolitic studies under inert atmosphere at different heating rates of 15, 30, 40 and 50 ºC min-1 from ambient temperature to 800 oC showed that the overall final weight loss recorded for the four different heating rates was in the range of 78.9 to 81%. A tubular photobioreactor was then designed and utilised for biomass and lipid optimisation. The suspension of microalgae was circulated by a pump and propelled to give a sufficiently turbulent flow periodically through the illuminated part and the dark part of the photobioreactor. Microalgal density was determined daily using a Spectrophotometer. Spectrophotometric determinations of biomass were periodically verified by dry cell weight measurements. Results suggest that the optimal NaNO3 concentration for cell growth in the reactor was around 7.5 g l-1, yielding maximum biomass of 2.09 g l-1 on day 16. This was a significant 2.2 fold increase in biomass (p < 0.005) when compared to results achieved at the lowest NaNO3 cycle (of 3.8 g l-1), which yielded a biomass value of 0.95 g l-1 at an OD of 1.178. Lipid accumulation experiments revealed that the microalga did not accumulate significant amounts of lipids when NaNO3 concentrations in the reactor were beyond 1.5 g l-1 (p > 0.005). The largest lipid fraction occurred when the NaNO3 concentration in the medium was 0.5 g l-1. Results suggest that the optimal trade-off between maximising biomass and lipid content occurs at 0.9 g l-1 NaNO3 among the tested conditions within the photobioreactor. Gas chromatograms showed that even though a greater number of known lipids were produced in Run 8, the total lipid percentage was much lower when compared to Runs 9-13. For maximal biomass and lipid from C. vulgaris, it is therefore crucial to optimise nutritional parameters such as NaNO3.
However, suitable growth conditions for C. vulgaris in a tubular photobioreactor calls for innovative technological breakthroughs and therefore work is ongoing globally to address this.
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Multicapillary membrane bioreactor designNtwampe, Seteno Karabo Obed January 2005 (has links)
Thesis (MTech (Chemical Engineering))--Cape Peninsula University of Technology, 2005 / The white rot fungus, Phanerochaete chrysosporium, produces enzymes, which are capable of
degrading chemical pollutants. It was detennined that this fungus has multiple growth phases.
The study provided infonnation that can be used to classify growth kinetic parameters, substrate
mass transfer and liquid medium momentum transfer effects in continuous secondary metabolite
production studies. P. chrysosporium strain BKMF 1767 (ATCC 24725) was grown at 37 QC in
single fibre capillary membrane bioreactors (SFCMBR) made of glass. The SFCMBR systems
with working volumes of 20.4 ml and active membrane length of 160 mm were positioned
vertically.
Dry biofilm density was determined by using a helium pycnometer. Biofilm differentiation was
detennined by taking samples for image analysis, using a Scanning Electron Microscope at
various phases of the biofilm growth. Substrate consumption was detennined by using relevant
test kits to quantify the amount, which was consumed at different times, using a varying amount
of spore concentrations. Growth kinetic constants were detennined by using the substrate
consumption and the dry biofilm density model. Oxygen mass transfer parameters were
determined by using the Clark type oxygen microsensors. Pressure transducers were used to
measure the pressure, which was needed to model the liquid medium momentum transfer in the
lumen of the polysulphone membranes. An attempt was made to measure the glucose mass
transfer across the biofilm, which was made by using a hydrogen peroxide microsensor, but
without success.
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Flow Characterization and Modeling of Cartilage Development in a Spinner-Flask BioreactorSucosky, Philippe 30 March 2005 (has links)
Bioreactors are devices used for the growth of tissues in a laboratory environment. They exist in many different forms, each designed to enable the production of high-quality tissues. The dynamic environment within bioreactors is known to significantly affect the growth and development of the tissue. Chondrocytes, the building blocks of articular cartilage, for example, are stimulated by mechanical stresses such as shear, as compared with those in tissues grown under static incubation conditions. On the other hand, high shear can damage cells. Consequently the shear-stress level has to be controlled in order to optimize the design and the operating conditions of bioreactors.
Spinner flasks have been used for the production of articular cartilage in vitro. Assuming the existence of a relation between the cellular glycosaminoglycan (GAG) synthesis and the local shear stresses on the construct surfaces, this research focuses on the development of a model for cartilage growth in such devices. The flow produced in a model spinner flask is characterized experimentally using particle-image velocimetry (PIV). A computational fluid dynamic (CFD) model validated with respect to the laboratory measurements is constructed in order to predict the local shear stresses on the construct surfaces. Tissue growth experiments conducted in the prototype bioreactor permit construct histologies and GAG contents to be analyzed and then correlated with the shear-stress predictions. The integration of this relation into the CFD model enables the prediction of GAG synthesis through convective effects. Coupling this convective model to an existing diffusive model produces a complete cartilage-growth model for use in aiding the optimization of existing bioreactors, and in the design of new ones.
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