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Query: UMLS:C0040822 (
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18,428
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Gas-liquid mass transfer properties of shaken 96-well microtiter plates were characterized using a recently described method. The maximum oxygen transfer capacity (
OTR
(max)), the specific mass transfer area (a), and the mass transfer coefficient (k(L)) in a single well were determined at different
shaking
intensities (different
shaking
frequencies and
shaking
diameters at constant filling volume) and different filling volumes by means of sulfite oxidation as a chemical model system. The shape (round and square cross-sections) and the size (up to 2 mL maximum filling volume) of a microtiter plate well were also considered as influencing parameters. To get an indication of the hydrodynamic behavior of the liquid phase in a well, images were taken during
shaking
and the liquid height derived as a characteristic parameter. The investigations revealed that the
OTR
(max) is predominantly dependent on the specific mass transfer area (a) for the considered conditions in round-shaped wells. The mass transfer coefficient (k(L)) in round-shaped wells remains at a nearly constant value of about 0.2 m/h for all
shaking
intensities, thus within the range reported in the literature for surface-aerated bioreactors. The
OTR
(max) in round-shaped wells is strongly influenced by the interfacial tension, determined by the surface tension of the medium used and the surface properties of the well material. Up to a specific
shaking
intensity the liquid surface in the wells remains horizontal and no liquid movement can be observed. This critical
shaking
intensity must be exceeded to overcome the surface tension and, thus, to increase the liquid height and enlarge the specific mass transfer area. This behavior is solely specific to microtiter plates and has not yet been observed for larger
shaking
bioreactors such as
shaking
flasks. In square-shaped microtiter plate wells the corners act as baffles and cause a significant increase of
OTR
(max), a, and k(L). An
OTR
(max) of up to 0.15 mol/L/h can be reached in square-shaped wells.
...
PMID:Characterization of gas-liquid mass transfer phenomena in microtiter plates. 1245 54
Oxygen supply is a key parameter in aerobic fermentation processes like the industrial production of amino acids. Although the oxygen transfer rate (
OTR
; or the volumetric oxygen transfer coefficient k(L)a) is routinely analyzed by engineers during stirred tank fermentations, it is often not taken into account by biologists conducting screening experiments in shake flasks. To show the importance of knowing how to avoid oxygen transfer limitations during primary screenings, Corynebacterium glutamicum ATCC 13032 (wild-type strain) and DSM 12866 (lysine-producing strain) were cultivated in shake flasks with different culture liquid volumes and under different
shaking
conditions. With the Respiration Activity Monitoring System, the
OTR
was determined quasi-continuously. Optical density as well as concentrations of lysine and byproducts (lactate, acetate, succinate) were determined off-line and correlated with the
OTR
signal. From the results, design criteria for improved screening in shaken bioreactors that help to avoid selection of suboptimal strains during early process development steps can be derived. Finally, the suitability of DSM 12866 as a strain for industrial processes with a high space-time yield is discussed.
...
PMID:Oxygen limitation is a pitfall during screening for industrial strains. 1657 61
Most experiments in screening and process development are performed in shaken bioreactors. Today, microtiter plates are the preferred vessels for small-scale microbial cultivations in high throughput, even though they have never been optimized for this purpose. To interpret the experimental results correctly and to obtain a base for a meaningful scale-up, sufficient oxygen supply to the culture liquid is crucial. For shaken bioreactors this problem can generally be addressed by the introduction of baffles. Therefore, the focus of this study is to investigate how baffling and the well geometry affect the maximum oxygen transfer capacity (
OTR
(max)) in microtiter plates. On a 48-well plate scale, 30 different cross-section geometries of a well were studied. It could be shown that the introduction of baffles into the common circular cylinder of a microtiter plate well doubles the maximum oxygen transfer capacity, resulting in values above 100 mmol/L/h (k(L)a > 600 1/h). To also guarantee a high volume for microbial cultivation, it is important to maximize the filling volume, applicable during orbital
shaking
. Additionally, the liquid height at the well bottom was examined, which is a decisive parameter for online-monitoring systems such as the BioLector. This technology performs fiber-optical measurements through the well bottom, therefore requires a constant liquid height at all
shaking
frequencies. Ultimately, a six-petal flower-shaped well geometry was shown to be the optimal solution taking into account all aforementioned criteria. With its favorable culture conditions and the possibility for unrestricted online monitoring, this novel microtiter plate is an efficient tool to gain meaningful results for interpreting and scaling-up experiments in clone screening and bioprocess development.
...
PMID:The baffled microtiter plate: increased oxygen transfer and improved online monitoring in small scale fermentations. 1944 92
