Your search keyword '"Tobias Butelmann"' showing total 8 results

1. Towards a 3D-Printed Millifluidic Device for Investigating Cellular Processes

Author

Jared A. Engelken, Tobias Butelmann, Fabian Tribukait-Riemenschneider, and V. Prasad Shastri

Subjects

3D printing, stereolithography, millifluidics, cancer research, metastasis, organ-on-a-chip, Mechanical engineering and machinery, TJ1-1570

Abstract

Microfluidic devices (µFDs) have been explored extensively in drug screening and studying cellular processes such as migration and metastasis. However, the fabrication and implementation of microfluidic devices pose cost and logistical challenges that limit wider-spread adoption. Despite these challenges, light-based 3D printing offers a potential alternative to device fabrication. This study reports on the development of millifluidic devices (MiFDs) for disease modeling and elucidates the methods and implications of the design, production, and testing of 3D-printed MiFDs. It further details how such millifluidic devices can be cost-efficiently and effortlessly produced. The MiFD was developed through an iterative process with analytical tests (flow tests, leak tests, cytotoxicity assays, and microscopic analyses), driving design evolution and determination of the suitability of the devices for disease modeling and cancer research. The design evolution also considered flow within tissues and replicates interstitial flow between the main flow path and the modules designed to house and support organ-mimicking cancer cell spheroids. Although the primary stereolithographic (SLA) resin used in this study showed cytotoxic potential despite its biocompatibility certifications, the MiFDs possessed essential attributes for cell culturing. In summary, SLA 3D printing enables the production of MiFDs as a cost-effective, rapid prototyping alternative to standard µFD fabrication for investigating disease-related processes.

Published

2024

2. Elucidating the mechanism of action of domatinostat (4SC-202) in cutaneous T cell lymphoma cells

Author

Marion Wobser, Alexandra Weber, Amelie Glunz, Saskia Tauch, Kristina Seitz, Tobias Butelmann, Sonja Hesbacher, Matthias Goebeler, René Bartz, Hella Kohlhof, David Schrama, and Roland Houben

Subjects

Cutaneous lymphoma, Epigenetic regulation, Histone deacetylase, HDAC, Lysine-specific methylase, LSD1, Diseases of the blood and blood-forming organs, RC633-647.5, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Background Targeting epigenetic modifiers is effective in cutaneous T cell lymphoma (CTCL). However, there is a need for further improvement of this therapeutic approach. Here, we compared the mode of action of romidepsin (FK228), an established class I histone deacetylase inhibitor, and domatinostat (4SC-202), a novel inhibitor of class I HDACs, which has been reported to also target the lysine-specific histone demethylase 1A (LSD1). Methods We performed MTS assays and flow cytometric analyses of propidium iodide or annexin V-stained cells to assess drug impact on cellular proliferation, cell cycle distribution, and survival. Histone acetylation and methylation as well as caspase activation was analyzed by immunoblot. Gene expression analysis was performed using NanosString technology. Knockdown and knockout of LSD1 was achieved with shRNA and CRISPR/Cas9, respectively, while the CRISPR/Cas9 synergistic activation mediator system was used to induce expression of endogenous HDACs and LSD1. Furthermore, time-lapse fluorescence microscopy and an in vitro tubulin polymerization assay were applied. Results While FK228 as well as 4SC-202 potently induced cell death in six different CTCL cell lines, only in the case of 4SC-202 death was preceded by an accumulation of cells in the G2/M phase of the cell cycle. Surprisingly, apoptosis and accumulation of cells with double DNA content occurred already at 4SC-202 concentrations hardly affecting histone acetylation and methylation, and provoking significantly less changes in gene expression compared to biologically equivalent doses of FK228. Indeed, we provide evidence that the 4SC-202-induced G2/M arrest in CTCL cells is independent of de novo transcription. Furthermore, neither enforced expression of HDAC1 nor knockdown or knockout of LSD1 affected the 4SC-202-induced effects. Since time-lapse microscopy revealed that 4SC-202 could affect mitotic spindle formation, we performed an in vitro tubulin polymerization assay revealing that 4SC-202 can directly inhibit microtubule formation. Conclusions We demonstrate that 4SC-202, a drug currently tested in clinical trials, effectively inhibits growth of CTCL cells. The anti-cancer cell activity of 4SC-202 is however not limited to LSD1-inhibition, modulation of histone modifications, and consecutive alteration of gene expression. Indeed, the compound is also a potent microtubule-destabilizing agent.

Published

2019

3. Metabolism Control in 3D-Printed Living Materials Improves Fermentation

Author

Rahul Kumar, Petri-Jaan Lahtvee, Tarmo Tamm, Zoel Parent, Alshakim Nelson, Tobias Butelmann, Trevor G. Johnston, and Hans Priks

Subjects

0303 health sciences, 3d printed, Ethanol, Polymers, Chemistry, Biochemistry (medical), Biomedical Engineering, Hydrogels, 02 engineering and technology, General Chemistry, Metabolism, 021001 nanoscience & nanotechnology, Oxygen, Biomaterials, 03 medical and health sciences, Fermentation, Printing, Three-Dimensional, Methacrylates, Food science, 0210 nano-technology, 030304 developmental biology

Abstract

The three-dimensional (3D) printing of cell-containing polymeric hydrogels creates living materials (LMs), offering a platform for developing innovative technologies in areas like biosensors and biomanufacturing. The polymer material properties of cross-linkable F127-bis-urethane methacrylate (F127-BUM) allow reproducible 3D printing and stability in physiological conditions, making it suitable for fabricating LMs. Though F127-BUM-based LMs permit diffusion of solute molecules like glucose and ethanol, it remains unknown whether these are permissible for oxygen, essential for respiration. To determine oxygen permissibility, we quantified dissolved oxygen consumption by the budding yeast-laden F127-BUM-based LMs. Moreover, we obtained data on cell-retaining LMs, which allowed a direct comparison between LMs and suspension cultures. We further developed a highly reliable method to isolate cells from LMs for flow cytometry analysis, cell viability evaluation, and the purification of macromolecules. We found oxygen consumption heavily impaired inside LMs, indicating that yeast metabolism relies primarily on fermentation instead of respiration. Applying this finding to brewing, we observed a higher (3.7%) ethanol production using LMs than the traditional brewing process, indicating improved fermentation. Our study concludes that the present F127-BUM-based LMs are useful for microaerobic processes but developing aerobic bioprocesses will require further research.

Published

2021

4. 3D Printed Solutions for Spheroid Engineering and Cancer Research

Author

Tobias Butelmann, Yawei Gu, Aijun Li, Fabian Tribukait-Riemenschneider, Julius Hoffmann, Amin Molazem, Ellen Jaeger, Diana Pellegrini, Aurelien Forget, and V. Prasad Shastri

Subjects

Organic Chemistry, tumor spheroids, hanging drop device, 3D printing, bioprinting, automation, General Medicine, Catalysis, Computer Science Applications, Inorganic Chemistry, Neoplasms, Spheroids, Cellular, Printing, Three-Dimensional, Tumor Microenvironment, Humans, Physical and Theoretical Chemistry, Molecular Biology, Spectroscopy

Abstract

In multicellular organisms, cells are organized in a 3-dimensional framework and this is essential for organogenesis and tissue morphogenesis. Systems to recapitulate 3D cell growth are therefore vital for understanding development and cancer biology. Cells organized in 3D environments can evolve certain phenotypic traits valuable to physiologically relevant models that cannot be accessed in 2D culture. Cellular spheroids constitute an important aspect of in vitro tumor biology and they are usually prepared using the hanging drop method. Here a 3D printed approach is demonstrated to fabricate bespoke hanging drop devices for the culture of tumor cells. The design attributes of the hanging drop device take into account the need for high-throughput, high efficacy in spheroid formation, and automation. Specifically, in this study, custom-fit, modularized hanging drop devices comprising of inserts (Q-serts) were designed and fabricated using fused filament deposition (FFD). The utility of the Q-serts in the engineering of unicellular and multicellular spheroids-synthetic tumor microenvironment mimics (STEMs)—was established using human (cancer) cells. The culture of spheroids was automated using a pipetting robot and bioprinted using a custom bioink based on carboxylated agarose to simulate a tumor microenvironment (TME). The spheroids were characterized using light microscopy and histology. They showed good morphological and structural integrity and had high viability throughout the entire workflow. The systems and workflow presented here represent a user-focused 3D printing-driven spheroid culture platform which can be reliably reproduced in any research environment and scaled to- and on-demand. The standardization of spheroid preparation, handling, and culture should eliminate user-dependent variables, and have a positive impact on translational research to enable direct comparison of scientific findings.

Published

2022

5. Metabolism Control in 3D Printed Living Materials

Author

Petri-Jaan Lahtvee, Tobias Butelmann, Alshakim Nelson, Tarmo Tamm, Zoel Parent, Trevor G. Johnston, Hans Priks, and Rahul Kumar

Subjects

0303 health sciences, 3d printed, Chemistry, Systems biology, Respiratory chain, Nanotechnology, 02 engineering and technology, Metabolism, 021001 nanoscience & nanotechnology, Budding yeast, 03 medical and health sciences, Bioreactor, Fermentation, 0210 nano-technology, Biosensor, 030304 developmental biology

Abstract

The three-dimensional printing of cells offers an attractive opportunity to design and develop innovative biotechnological applications, such as the fabrication of biosensors or modular bioreactors. Living materials (LMs) are cross-linked polymeric hydrogel matrices containing cells, and recently, one of the most deployed LMs consists of F127-bis-urethane methacrylate (F127-BUM). The material properties of F127-BUM allow reproducible 3D printing and stability of LMs in physiological environments. These materials are permissible for small molecules like glucose and ethanol. However, no information is available for oxygen, which is essential— for example, towards the development of aerobic bioprocesses using microbial cell factories. To address this challenge, we investigated the role of oxygen as a terminal electron acceptor in the budding yeast’s respiratory chain and determined its permissibility in LMs. We quantified the ability of cell-retaining LMs to utilize oxygen and compared it with cells in suspension culture. We found that the cells’ ability to consume oxygen was heavily impaired inside LMs, indicating that the metabolism mostly relied on fermentation instead of respiration. To demonstrate an application of these 3D printed LMs, we evaluated a comparative brewing process. The analysis showed a significantly higher (3.7%) ethanol production using 3D printed LMs than traditional brewing, indicating an efficient control of the metabolism. Towards molecular and systems biology studies using LMs, we developed a highly reliable method to isolate cells from LMs for flow cytometry and further purified macromolecules (proteins, RNA, and DNA). Our results show the application of F127-BUM-based LMs for microaerobic processes and envision the development of diverse bioprocesses using versatile LMs in the future.

Published

2021

6. Scanning electron microscopy (SEM) protocol for imaging living materials v1

Author

Hans Priks and Tobias Butelmann

Subjects

Materials science, Scanning electron microscope, Biomedical engineering

Abstract

Scanning electron microscopy (SEM) can be used to image cells and colonies immobilized inside hydrogels after supercritical carbon dioxide (CO2) extraction. Supercritical CO2 extraction can also be used on suspension cells after filtering the sample onto a 0.2 μM filter attached into the extractors carriers. This protocol gives an overview on how different techniques can be used to characterize triblock copolymer hydrogels.

Published

2020

7. Physical confinement impacts cellular phenotype within living materials

Author

Aleksandr Illarionov, Trevor G. Johnston, Hans Priks, Rahul Kumar, Tarmo Tamm, Petri-Jaan Lahtvee, Christopher R. Fellin, Alshakim Nelson, and Tobias Butelmann

Subjects

chemistry.chemical_classification, 0303 health sciences, biology, Saccharomyces cerevisiae, 02 engineering and technology, Polymer, 021001 nanoscience & nanotechnology, biology.organism_classification, Methacrylate, Cellular phenotype, Yeast, Glycidyl ether, 03 medical and health sciences, Polymer degradation, chemistry, Self-healing hydrogels, Biophysics, 0210 nano-technology, 030304 developmental biology

Abstract

Additive manufacturing allows three-dimensional printing of polymeric materials together with cells, creating living materials for applications in biomedical research and biotechnology. However, understanding the cellular phenotype within living materials is lacking and a key limitation for their wider application. Herein, we present an approach to characterize the cellular phenotype within living materials. We immobilized the budding yeast Saccharomyces cerevisiae in three different photocross-linkable triblock polymeric hydrogels containing F127-bis-urethane methacrylate, F127-dimethacrylate, or poly(alkyl glycidyl ether)-dimethacrylate. Using optical and scanning electron microscopy, we showed that hydrogels based on these polymers were stable under physiological conditions, but yeast colonies showed differences in the interaction within the living materials. We found that the physical confinement, imparted by compositional and structural properties of the hydrogels, impacted the cellular phenotype by reducing the size of cells in living materials compared with suspension cells. These properties also contributed to the differences in immobilization patterns, growth of colonies, and colony coatings. We observed that a composition-dependent degradation of polymers was likely possible by cells residing in the living materials. In conclusion, our investigation highlights the need for a holistic understanding of the cellular response within hydrogels to facilitate the synthesis of application-specific polymers and the design of advanced living materials in the future.

Published

2020

8. Physical Confinement Impacts Cellular Phenotypes within Living Materials

Author

Alshakim Nelson, Aleksandr Illarionov, Petri-Jaan Lahtvee, Tarmo Tamm, Christopher R. Fellin, Rahul Kumar, Tobias Butelmann, Hans Priks, and Trevor G. Johnston

Subjects

Materials science, polymer degradation, Biomedical Engineering, 3D printing, Nanotechnology, living materials, 02 engineering and technology, yeast, 010402 general chemistry, 01 natural sciences, Article, Cell size, Biomaterials, Polymer degradation, triblock copolymers, Bioprocess, hydrogels, business.industry, bioprocessing, Biochemistry (medical), General Chemistry, 021001 nanoscience & nanotechnology, Yeast, 0104 chemical sciences, cell size, Self-healing hydrogels, 0210 nano-technology, business, additive manufacturing, scanning electron microscopy, biotechnology

Abstract

Additive manufacturing allows three-dimensional printing of polymeric materials together with cells, creating living materials for applications in biomedical research and biotechnology. However, an understanding of the cellular phenotype within living materials is lacking, which is a key limitation for their wider application. Herein, we present an approach to characterize the cellular phenotype within living materials. We immobilized the budding yeast Saccharomyces cerevisiae in three different photo-cross-linkable triblock polymeric hydrogels containing F127-bis-urethane methacrylate, F127-dimethacrylate, or poly(alkyl glycidyl ether)-dimethacrylate. Using optical and scanning electron microscopy, we showed that hydrogels based on these polymers were stable under physiological conditions, but yeast colonies showed differences in the interaction within the living materials. We found that the physical confinement, imparted by compositional and structural properties of the hydrogels, impacted the cellular phenotype by reducing the size of cells in living materials compared with suspension cells. These properties also contributed to the differences in immobilization patterns, growth of colonies, and colony coatings. We observed that a composition-dependent degradation of polymers was likely possible by cells residing in the living materials. In conclusion, our investigation highlights the need for a holistic understanding of the cellular response within hydrogels to facilitate the synthesis of application-specific polymers and the design of advanced living materials in the future.

Published

2020