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28 results on '"Steingroewer, J."'

1. Membrane inlet-ion mobility spectrometry with automatic spectra evaluation as online monitoring tool for the process control of microalgae cultivation

Author

Cämmerer, Malcolm, Mayer, Thomas, Schott, C., Steingroewer, J., Petrich, R., Borsdorf, Helko, Cämmerer, Malcolm, Mayer, Thomas, Schott, C., Steingroewer, J., Petrich, R., and Borsdorf, Helko

Abstract

The cultivation of algae either in open raceway ponds or in closed bioreactors could allow the renewable production of biomass for food, pharmaceutical, cosmetic, or chemical industries. Optimal cultivation conditions are however required to ensure that the production of these compounds is both efficient and economical. Therefore, high-frequency analytical measurements are required to allow timely process control and to detect possible disturbances during algae growth. Such analytical methods are only available to a limited extent. Therefore, we introduced a method for monitoring algae release volatile organic compounds (VOCs) in the headspace above a bioreactor in real time. This method is based on ion mobility spectrometry (IMS) in combination with a membrane inlet (MI). The unique feature of IMS is that complete spectra are detected in real time instead of sum signals. These spectral patterns produced in the ion mobility spectrum were evaluated automatically via principal component analysis (PCA). The detected peak patterns are characteristic for the respective algae culture; allow the assignment of the individual growth phases and reflect the influence of experimental parameters. These results allow for the first time a continuous monitoring of the algae cultivation and thus an early detection of possible disturbances in the biotechnological process.

Published
2023

2. IMS meets HKA: ein neues Tool zur Überwachung von Mikroalgenkulturen

Author

Mayer, Thomas, Steingroewer, J., Petrich, R., Borsdorf, Helko, Mayer, Thomas, Steingroewer, J., Petrich, R., and Borsdorf, Helko

Abstract

A new method for real-time monitoring of algae cultures in bioreactors has been developed. It is based on ion mobility spectrometry and enables the detection of volatile organic compounds released by the algae. Spectral analysis and principal component analysis can be used to identify growth phases and to detect experimental infl uences. This continuous monitoring enables early detection of disturbances in the biotechnological process.

Published
2023

4. Bio-compatible flotation of Chlorella vulgaris: Study of zeta potential and flotation efficiency

Author

Matho, C., Schwarzenberger, K., Eckert, K., Keshavarzi, B., Walther, T., Steingroewer, J., and Krujatz, F.

Subjects
Chitosan, Flotation, Zeta potential, CTAB, Dispersed-air flotation, Chlorella vulgaris
Abstract

The energy-intensive dewatering of algae biomass, the first step of most downstream processes, remains one of the big challenges for economically relevant photoautotrophic bioprocesses. Due to its scalability and easy construction, froth flotation using the interactions between cells and bubbles shows considerable potential for this type of cost-efficient initial dewatering step. Comprehensive knowledge on both the physico-chemical conditions and the cellular surface properties are an important precondition to harvest cells by flotation. This study investigates the impact of changing the medium composition, specifically varying the pH and adding (bio-) collectors, on the zeta potential of Chlorella vulgaris SAG 211-1b. Decreasing the pH value from physiological to acidic conditions (pH 1–1.5) resulted in a strongly reduced cellular zeta potential. As validated by dispersed-air flotation, this yields a significantly enhanced cell recovery R > 95 %. The impact of the synthetic collector cetyltrimethylammonium bromide and the biopolymer chitosan on the cellular zeta potential and flotation performance was studied, resulting in a 3.3-fold decrease in the surfactant dose when chitosan was used . The basic mechanisms of cell-chitosan interaction were analysed in terms of particle size distribution and surface tension measurements, revealing interactions between flocculation and adsorption during the dispersed-air flotation of C.vulgarisSAG 211-1b.

Published
2019

14. A Rapid Method for the Pre‐Enrichment and Detection of SalmonellaTyphimurium by Immunomagnetic Separation and Subsequent Fluorescence Microscopical Techniques

Author

Steingroewer, J., Knaus, H., Bley, T., and Boschke, E.

Abstract

Detection of food‐borne pathogens is of great importance in order to minimize the risk of infection for customers. These analyses should be as fast as possible. Any detection method requires enrichment and quantitative analysis of the enriched microbes. Conventional enrichment methods, which take several days, need to be replaced by faster techniques such as immunomagnetic separation (IMS). This technique is based on the use of paramagnetic microspheres coated with antibodies as ligands that have specific affinity to the microbes that have to be detected. In the studies reported here, a rapid method for the detection of Salmonella entericaserovar Typhimurium (SalmonellaTyphimurium), combining IMS and Direct Epifluorescence Filter Technique (DEFT), was developed. It was focused on releasing the target cells from the magnetic beads after IMS, because this is a premise for combining IMS, as an alternative pre‐enrichment, with DEFT. Otherwise, the high number of beads form a layer on the filter membrane that makes the following microscopic analysis for the detection of the contaminants impossible. The CELLectionTMDynabeads®used in this study, are coated with recombinant streptavidin (rSA) viaa DNA linker. The rSA binds biotinylated antibodies that are able to capture target cells. The DNA linker provides the cleavable site, so that the beads can be removed from the captured cells after isolation. In this study a releasing procedure was developed. This procedure allows for an average 74 % ± 4 % of the bead‐bound SalmonellaTyphimurium cells to be released from the beads after IMS, so that the detection of the separated cells by DEFT will be possible.

Published
2005
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15. Membrane inlet-ion mobility spectrometry with automatic spectra evaluation as online monitoring tool for the process control of microalgae cultivation.

Author

Cämmerer M, Mayer T, Schott C, Steingroewer J, Petrich R, and Borsdorf H

Abstract

The cultivation of algae either in open raceway ponds or in closed bioreactors could allow the renewable production of biomass for food, pharmaceutical, cosmetic, or chemical industries. Optimal cultivation conditions are however required to ensure that the production of these compounds is both efficient and economical. Therefore, high-frequency analytical measurements are required to allow timely process control and to detect possible disturbances during algae growth. Such analytical methods are only available to a limited extent. Therefore, we introduced a method for monitoring algae release volatile organic compounds (VOCs) in the headspace above a bioreactor in real time. This method is based on ion mobility spectrometry (IMS) in combination with a membrane inlet (MI). The unique feature of IMS is that complete spectra are detected in real time instead of sum signals. These spectral patterns produced in the ion mobility spectrum were evaluated automatically via principal component analysis (PCA). The detected peak patterns are characteristic for the respective algae culture; allow the assignment of the individual growth phases and reflect the influence of experimental parameters. These results allow for the first time a continuous monitoring of the algae cultivation and thus an early detection of possible disturbances in the biotechnological process., Competing Interests: The authors declare no competing interests., (© 2023 The Authors. Engineering in Life Sciences published by Wiley‐VCH GmbH.)

Published
2023
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16. Monitoring the apical growth characteristics of hairy roots using non-invasive laser speckle contrast imaging.

Author

Schott C, Bley T, Walter T, Brusius J, and Steingroewer J

Abstract

Hairy roots are used to produce plant agents and additives. Due to their heterogeneous structure and growth characteristics, it is difficult to determine growth-related parameters continuously and in real time. Laser speckle contrast analysis is widely used as a non-destructive measurement technique in material testing or in medical technology. This type of analysis is based on the principle that moving objects or particles cause fluctuations in stochastic interference patterns known as speckle patterns. They are formed by the random backscattering of coherent laser light on an optically rough surface. A Laser Speckle Imager, which is well established for speckle studies of hemodynamics, was used for the first time for non-invasive speckle measurements on hairy roots to study dynamic behavior in plant tissue. Based on speckle contrast, a specific flux value was defined to map the dynamic changes in the investigated tissue. Using this method, we were able to predict the formation of lateral strands and to identify the growth zone in the apical root region, as well as dividing it into functional regions. This makes it possible to monitor physiological processes in the apical growth zone in vivo and in real time without labeling the target structures., Competing Interests: The authors have declared no conflict of interest., (© 2021 The Authors. Engineering in Life Sciences published by Wiley‐VCH GmbH.)

Published
2021
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18. Biospeckle-characterization of hairy root cultures using laser speckle photometry.

Author

Schott C, Steingroewer J, Bley T, Cikalova U, and Bendjus B

Abstract

Monitoring is indispensable for the optimization and simulation of biotechnological processes. Hairy roots (hr, plant tissue cultures) are producers of valuable relevant secondary metabolites. The genetically stable cultures are characterized by a rapid filamentous growth, making monitoring difficult with standard methods. This article focuses on the application of laser speckle photometry (LSP) as an innovative, non-invasive method to characterize Beta vulgaris (hr). LSP is based on the analysis of time-resolved interference patterns. Speckle interference patterns of a biological object, known as biospeckles, are characterized by a dynamic behavior that is induced by physical and biological phenomena related to the object. Speckle contrast, a means of measuring the dynamic behavior of biospeckles, was used to assess the biospeckle activity. The biospeckle activity corresponds to processes modifying the object and correlates with the biomass growth. Furthermore, the stage of the cultures' physiological development was assessed by speckle contrast due to the differentiation between active and low active behavior. This method is a new means of monitoring and evaluating the biomass growth of filamentous cultures in real time. As a potential tool to characterize hairy roots, LSP is non-invasive, time-saving, can be used online and stands out for its simple, low-cost setup., Competing Interests: The authors have declared no conflict of interest., (© 2020 The Authors. Engineering in Life Sciences published by WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2020
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19. Engineering considerations on extrusion-based bioprinting: interactions of material behavior, mechanical forces and cells in the printing needle.

Author

Emmermacher J, Spura D, Cziommer J, Kilian D, Wollborn T, Fritsching U, Steingroewer J, Walther T, Gelinsky M, and Lode A

Subjects
Alginates chemistry, Cell Culture Techniques instrumentation, Cell Culture Techniques methods, Cell Survival, Humans, Mesenchymal Stem Cells cytology, Mesenchymal Stem Cells physiology, Methylcellulose chemistry, Ocimum basilicum cytology, Plant Cells physiology, Rheology, Sepharose chemistry, Shear Strength, Bioprinting methods, Ink, Printing, Three-Dimensional
Abstract

Systematic analysis of the extrusion process in 3D bioprinting is mandatory for process optimization concerning production speed, shape fidelity of the 3D construct and cell viability. In this study, we applied numerical and analytical modeling to describe the fluid flow inside the printing head based on a Herschel-Bulkley model. The presented analytical calculation method nicely reproduces the results of Computational Fluid Dynamics simulation concerning pressure drop over the printing head and maximal shear parameters at the outlet. An approach with dimensionless flow parameter enables the user to adapt rheological characteristics of a bioink, the printing pressure and needle diameter with regard to processing time, shear sensitivity of the integrated cells, shape fidelity and strand dimension. Bioinks consist of a blend of polymers and cells, which lead to a complex fluid behavior. In the present study, a bioink containing alginate, methylcellulose and agarose (AMA) was used as experimental model to compare the calculated with the experimental pressure gradient. With cultures of an immortalized human mesenchymal stem cell line and plant cells (basil) it was tested how cells influence the flow and how mechanical forces inside the printing needle affect cell viability. Influences on both sides increased with cell (aggregation) size as well as a less spherical shape. This study contributes to a systematic description of the extrusion-based bioprinting process and introduces a general strategy for process design, transferable to other bioinks.

Published
2020
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20. Microalgae wastewater treatment: Biological and technological approaches.

Author

Wollmann F, Dietze S, Ackermann JU, Bley T, Walther T, Steingroewer J, and Krujatz F

Abstract

Current global environmental issues raise unavoidable challenges for our use of natural resources. Supplying the human population with clean water is becoming a global problem. Numerous organic and inorganic impurities in municipal, industrial, and agricultural waters, ranging from microplastics to high nutrient loads and heavy metals, endanger our nutrition and health. The development of efficient wastewater treatment technologies and circular economic approaches is thus becoming increasingly important. The biomass production of microalgae using industrial wastewater offers the possibility of recycling industrial residues to create new sources of raw materials for energy and material use. This review discusses algae-based wastewater treatment technologies with a special focus on industrial wastewater sources, the potential of non-conventional extremophilic (thermophilic, acidophilic, and psychrophilic) microalgae, and industrial algae-wastewater treatment concepts that have already been put into practice., Competing Interests: The authors have declared no conflict of interest, (© 2019 The Authors. Engineering in Life Sciences published by WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2019
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21. Green bioprinting: extrusion-based fabrication of plant cell-laden biopolymer hydrogel scaffolds.

Author

Seidel J, Ahlfeld T, Adolph M, Kümmritz S, Steingroewer J, Krujatz F, Bley T, Gelinsky M, and Lode A

Subjects
Alginates chemistry, Cell Culture Techniques, Cell Survival, Compressive Strength, Computer-Aided Design, Glucuronic Acid chemistry, Green Chemistry Technology, Hexuronic Acids chemistry, Methylcellulose chemistry, Microscopy, Electron, Scanning, Ocimum basilicum cytology, Ocimum basilicum metabolism, Rheology, Sepharose chemistry, Viscosity, Biopolymers chemistry, Bioprinting methods, Hydrogels chemistry, Plant Cells chemistry, Tissue Scaffolds chemistry
Abstract

Plant cell cultures produce active agents for pharmaceuticals, food and cosmetics. However, up to now process control for plant cell suspension cultures is challenging. A positive impact of cell immobilization, such as encapsulation in hydrogel beads, on secondary metabolites production has been reported for several plant species. The aim of this work was to develop a method for bioprinting of plant cells in order to allow fabrication of free-formed three-dimensional matrices with defined internal pore architecture for in depth characterization of immobilization conditions, cell agglomeration and interactions. By using extrusion-based 3D plotting of a basil cell-laden hydrogel blend consisting of alginate, agarose and methylcellulose (alg/aga/mc), we could demonstrate that bioprinting is applicable to plant cells. The majority of the cells survived plotting and crosslinking and the embedded cells showed high viability and metabolic activity during the investigated cultivation period of 20 d. Beside its compatibility with the plant cells, the novel alg/aga/mc blend allowed fabrication of defined 3D constructs with open macropores both in vertical and horizontal direction which were stable under culture conditions for several weeks. Thus, Green Bioprinting, an additive manufacturing technology processing live cells from the plant kingdom, is a promising new immobilization tool for plant cells that enables the development of new bioprocesses for secondary metabolites production as well as monitoring methods.

Published
2017
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22. Additive Biotech-Chances, challenges, and recent applications of additive manufacturing technologies in biotechnology.

Author

Krujatz F, Lode A, Seidel J, Bley T, Gelinsky M, and Steingroewer J

Subjects
Imaging, Three-Dimensional, Microfluidics, Biotechnology methods, Manufacturing Industry
Abstract

The diversity and complexity of biotechnological applications are constantly increasing, with ever expanding ranges of production hosts, cultivation conditions and measurement tasks. Consequently, many analytical and cultivation systems for biotechnology and bioprocess engineering, such as microfluidic devices or bioreactors, are tailor-made to precisely satisfy the requirements of specific measurements or cultivation tasks. Additive manufacturing (AM) technologies offer the possibility of fabricating tailor-made 3D laboratory equipment directly from CAD designs with previously inaccessible levels of freedom in terms of structural complexity. This review discusses the historical background of these technologies, their most promising current implementations and the associated workflows, fabrication processes and material specifications, together with some of the major challenges associated with using AM in biotechnology/bioprocess engineering. To illustrate the great potential of AM, selected examples in microfluidic devices, 3D-bioprinting/biofabrication and bioprocess engineering are highlighted., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published
2017
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23. "Fungal elicitors combined with a sucrose feed significantly enhance triterpene production of a Salvia fruticosa cell suspension".

Author

Kümmritz S, Louis M, Haas C, Oehmichen F, Gantz S, Delenk H, Steudler S, Bley T, and Steingroewer J

Subjects
Aspergillus niger metabolism, Cell Culture Techniques methods, Culture Media, Conditioned pharmacology, Cyclopentanes pharmacology, Oxylipins pharmacology, Plant Cells metabolism, Trichoderma metabolism, Ursolic Acid, Bioreactors, Oleanolic Acid biosynthesis, Salvia metabolism, Sucrose metabolism, Triterpenes metabolism
Abstract

Oleanolic (OA) and ursolic acid (UA) are plant secondary metabolites with diverse pharmacological properties. To reach reasonable productivities with plant cell suspension cultures, elicitation is a widely used strategy. Within the presented work, the effects of different elicitors on growth and production of OA and UA in a Salvia fruticosa cell suspension culture were examined. Beside commonly used elicitors like jasmonic acid (JA) and yeast extract, the influence of medium filtrates of the endophytic fungi Aspergillus niger and Trichoderma virens was investigated. The best eliciting effects were achieved with JA and fungal medium filtrates. Both increased the triterpene content by approximately 70 %. Since JA showed significant growth inhibition, the volumetric triterpene yield did not increase. But, adding fungal filtrates increased the volumetric triterpene yield by approximately 70 % to 32.6 mgOA l(-1) and 65.9 mgUA l(-1) for T. virens compared to the control with 19.4 mgOA l(-1) and 33.3 mgUA l(-1). An elicitation strategy combining fungal medium filtrate of T. virens with sucrose feeding significantly enhanced cell dry weight concentration to 22.2 g l(-1) as well as triterpene content by approximately 140 %. In total, this led to an approximately 500 % increase of volumetric triterpene yield referring to the control with final values of 112.9 mgOA l(-1) and 210.4 mgUA l(-1). Despite the doubled cultivation duration, productivities of 6.7 mgOA l(-1) day(-1) and 12.4 mgUA l(-1) day(-1) were reached. These results demonstrate methods by which increased productivities of triterpenes can be achieved to attain yields competing with intact plants.

Published
2016
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24. Modeling hairy root tissue growth in in vitro environments using an agent-based, structured growth model.

Author

Lenk F, Sürmann A, Oberthür P, Schneider M, Steingroewer J, and Bley T

Subjects
Beta vulgaris cytology, Plant Roots cytology, Beta vulgaris growth & development, Models, Biological, Plant Roots growth & development
Abstract

An agent-based model for simulating the in vitro growth of Beta vulgaris hairy root cultures is described. The model fitting is based on experimental results and can be used as a virtual experimentator for root networks. It is implemented in the JAVA language and is designed to be easily modified to describe the growth of diverse biological root networks. The basic principles of the model are outlined, with descriptions of all of the relevant algorithms using the ODD protocol, and a case study is presented in which it is used to simulate the development of hairy root cultures of beetroot (Beta vulgaris) in a Petri dish. The model can predict various properties of the developing network, including the total root length, branching point distribution, segment distribution and secondary metabolite accumulation. It thus provides valuable information that can be used when optimizing cultivation parameters (e.g., medium composition) and the cultivation environment (e.g., the cultivation temperature) as well as how constructional parameters change the morphology of the root network. An image recognition solution was used to acquire experimental data that were used when fitting the model and to evaluate the agreement between the simulated results and practical experiments. Overall, the case study simulation closely reproduced experimental results for the cultures grown under equivalent conditions to those assumed in the simulation. A 3D-visualization solution was created to display the simulated results relating to the state of the root network and its environment (e.g., oxygen and nutrient levels).

Published
2014
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25. Induction of a photomixotrophic plant cell culture of Helianthus annuus and optimization of culture conditions for improved α-tocopherol production.

Author

Geipel K, Song X, Socher ML, Kümmritz S, Püschel J, Bley T, Ludwig-Müller J, and Steingroewer J

Subjects
Cell Culture Techniques methods, Culture Media chemistry, Glucose metabolism, Light, Biotechnology methods, Helianthus growth & development, Helianthus metabolism, alpha-Tocopherol metabolism
Abstract

Tocopherols, collectively known as vitamin E, are lipophilic antioxidants, which are synthesized only by photosynthetic organisms. Due to their enormous potential to protect cells from oxidative damage, tocopherols are used, e.g., as nutraceuticals and additives in pharmaceuticals. The most biologically active form of vitamin E is α-tocopherol. Most tocopherols are currently produced via chemical synthesis. Nevertheless, this always results in a racemic mixture of different and less effective stereoisomers because the natural isomer has the highest biological activity. Therefore, tocopherols synthesized in natural sources are preferred for medical purposes. The annual sunflower (Helianthus annuus L.) is a well-known source for α-tocopherol. Within the presented work, sunflower callus and suspension cultures were established growing under photomixotrophic conditions to enhance α-tocopherol yield. The most efficient callus induction was achieved with sunflower stems cultivated on solid Murashige and Skoog medium supplemented with 30 g l(-1) sucrose, 0.5 mg l(-1) of the auxin 1-naphthalene acetic acid, and 0.5 mg l(-1) of the cytokinin 6-benzylaminopurine. Photomixotrophic sunflower suspension cultures were induced by transferring previously established callus into liquid medium. The effects of light intensity, sugar concentration, and culture age on growth rate and α-tocopherol synthesis rate were characterized. A considerable increase (max. 230%) of α-tocopherol production in the cells was obtained within the photomixotrophic cell culture compared to a heterotrophic cell culture. These results will be useful for improving α-tocopherol yields of plant in vitro cultures.

Published
2014
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26. Sage in vitro cultures: a promising tool for the production of bioactive terpenes and phenolic substances.

Author

Marchev A, Haas C, Schulz S, Georgiev V, Steingroewer J, Bley T, and Pavlov A

Subjects
Biological Products isolation & purification, Cell Culture Techniques methods, Phenols isolation & purification, Terpenes isolation & purification, Biological Products metabolism, Biotechnology methods, Phenols metabolism, Salvia metabolism, Terpenes metabolism
Abstract

Extracts of Salvia species are used in traditional medicine to treat various diseases. The economic importance of this genus has increased in recent years due to evidence that some of its secondary metabolites have valuable pharmaceutical and nutraceutical properties.The bioactivity of sage extracts is mainly due to their content of terpenes and polyphenols. The increasing demand for sage products combined with environmental, ecological and climatic limitations on the production of sage metabolites from field-grown plants have led to extensive investigations into biotechnological approaches for the production of Salvia phytochemicals. The purpose of this review is to evaluate recent progress in investigations of sage in vitro systems as tools for producing important terpenoids and polyphenols and in development of methods for manipulating regulatory processes to enhance secondary metabolite production in such systems.

Published
2014
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27. Determination of triterpenic acids and screening for valuable secondary metabolites in Salvia sp. suspension cultures.

Author

Kümmritz S, Haas C, Pavlov AI, Geib D, Ulber R, Bley T, and Steingroewer J

Subjects
Cells, Cultured, Oleanolic Acid analysis, Salvia chemistry, Triterpenes analysis, Ursolic Acid, Oleanolic Acid metabolism, Salvia metabolism, Triterpenes metabolism
Abstract

Plant in vitro cultures are a prospective alternative for biochemicals production, for example the triterpenes oleanolic and ursolic acid present in plants and cell cultures of Salvia sp. Our objective was to develop a suitable analysis protocol for evaluation of triterpenic acid yield in plant raw material and in vitro cultures supporting selection processes. Moreover, valuable bioactive compounds had to be revealed. Thus, different strategies enhancing the separation for a sensitive and effective HPLC-UV method were investigated and the developed method was validated for linearity, precision, accuracy, limits of detection and quantification. A baseline separation of these isomers enabled detection limits of below 0.4 microg/mL and quantification limits of about 1.2 microg/mL. Over the tested concentration range a good linearity was observed (R2 > 0.9999). The variations in the method were below 6% for intra- and inter-day assays of concentration. Recoveries were between 85-98% for both compounds using ethanol as extraction solvent. Additionally, metabolite profiling of cell suspension culture extracts by GC-MS has shown the production variability of different plant metabolites and especially the presence of plant phenols and sterols. These studies provide a method suitable for screening plant and cell culture productivity of triterpenic acids and highlighted interesting co-products of plant cell cultures.

Published
2014

28. Effects of caffeine on stereoselectivities of high cell density biotransformations of cyclic beta-keto esters with Saccharomyces cerevisiae.

Author

Bohn M, Leppchen K, Katzberg M, Lang A, Steingroewer J, Weber J, Bley T, and Bertau M

Subjects
Apoptosis drug effects, Biotransformation drug effects, Calcium chemistry, Cell Count, Cyclization, Esters metabolism, Ketones metabolism, Magnesium chemistry, Molecular Structure, Oxidation-Reduction, Stereoisomerism, Caffeine pharmacology, Esters chemistry, Ketones chemistry, Saccharomyces cerevisiae drug effects, Saccharomyces cerevisiae metabolism
Abstract

Caffeine affects the stereoselectivity of microbial high cell density reductions with commercial grade Saccharomyces cerevisiae (Baker's yeast). Cyclic beta-keto esters ethyl 2-oxocyclopentanoate (1) and ethyl 2-oxocyclohexanoate (3) were shown to be reduced with increased diastereoselectivity (1: 90.1 --> 92.1% de, 3: 75.0 --> 90.0% de) after addition of caffeine. Effects on enantioselectivity were less pronounced (1: 97.3 --> 98.5% ee, 3: 90.1 --> 92.1% ee). The observations are ascribed to the action of caffeine on cellular calcium homeostasis. These effects are accompanied by caffeine-induced cell-death, which preferably takes effect on pre-stressed cells which were found to decrease diastereoselectivity.

Published
2007
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