Your search keyword '"Christoph Buken"' showing total 5 results

1. Beneficial Effects of Low Frequency Vibration on Human Chondrocytes in Vitro

Author

Ronald Lützenberg, Markus Wehland, Kendrick Solano, Mohamed Z. Nassef, Christoph Buken, Daniela Melnik, Johann Bauer, Sascha Kopp, Marcus Krüger, Stefan Riwaldt, Ruth Hemmersbach, Herbert Schulz, Manfred Infanger, and Daniela Grimm

Subjects

Physiology, QP1-981, Biochemistry, QD415-436

Published

2019

2. Morphological and Molecular Changes in Juvenile Normal Human Fibroblasts Exposed to Simulated Microgravity

Author

Christoph Buken, Jayashree Sahana, Thomas J. Corydon, Daniela Melnik, Johann Bauer, Markus Wehland, Marcus Krüger, Silke Balk, Nauras Abuagela, Manfred Infanger, and Daniela Grimm

Subjects

Medicine, Science

Abstract

Abstract The literature suggests morphological alterations and molecular biological changes within the cellular milieu of human cells, exposed to microgravity (µg), as many cell types assemble to multicellular spheroids (MCS). In this study we investigated juvenile normal human dermal fibroblasts (NHDF) grown in simulated µg (s-µg) on a random positioning machine (RPM), aiming to study changes in cell morphology, cytoskeleton, extracellular matrix (ECM), focal adhesion and growth factors. On the RPM, NHDF formed an adherent monolayer and compact MCS. For the two cell populations we found a differential regulation of fibronectin, laminin, collagen-IV, aggrecan, osteopontin, TIMP-1, integrin-β1, caveolin-1, E-cadherin, talin-1, vimentin, α-SM actin, TGF-β1, IL-8, MCP-1, MMP-1, and MMP-14 both on the transcriptional and/or translational level. Immunofluorescence staining revealed only slight structural changes in cytoskeletal components. Flow cytometry showed various membrane-bound proteins with considerable variations. In silico analyses of the regulated proteins revealed an interaction network, contributing to MCS growth via signals mediated by integrin-β1, E-cadherin, caveolin-1 and talin-1. In conclusion, s-µg-conditions induced changes in the cytoskeleton, ECM, focal adhesion and growth behavior of NHDF and we identified for the first time factors involved in fibroblast 3D-assembly. This new knowledge might be of importance in tissue engineering, wound healing and cancer metastasis.

Published

2019

3. Pathway Analysis Hints Towards Beneficial Effects of Long-Term Vibration on Human Chondrocytes

Author

Ronald Lützenberg, Kendrick Solano, Christoph Buken, Jayashree Sahana, Stefan Riwaldt, Sascha Kopp, Marcus Krüger, Herbert Schulz, Kathrin Saar, Norbert Huebner, Ruth Hemmersbach, Johann Bauer, Manfred Infanger, Daniela Grimm, and Markus Wehland

Subjects

Chondrocytes, Vibration, Cytoskeleton, Extracellular matrix proteins, Gene expression, Pathway analysis, Physiology, QP1-981, Biochemistry, QD415-436

Abstract

Background/Aims: Spaceflight negatively influences the function of cartilage tissue in vivo. In vitro human chondrocytes exhibit an altered gene expression of inflammation markers after a two-hour exposure to vibration. Little is known about the impact of long-term vibration on chondrocytes. Methods: Human cartilage cells were exposed for up to 24 h (VIB) on a specialised vibration platform (Vibraplex) simulating the vibration profile which occurs during parabolic flights and compared to static control conditions (CON). Afterwards, they were investigated by phase-contrast microscopy, rhodamine phalloidin staining, microarray analysis, qPCR and western blot analysis. Results: Morphological investigations revealed no changes between CON and VIB chondrocytes. F-Actin staining showed no alterations of the cytoskeleton in VIB compared with CON cells. DAPI and TUNEL staining did not identify apoptotic cells. ICAM-1 was elevated and vimentin, beta-tubulin and osteopontin proteins were significantly reduced in VIB compared to CON cells. qPCR of cytoskeletal genes, ITGB1, SOX3, SOX5, SOX9 did not reveal differential regulations. Microarray analysis detected 13 differentially expressed genes, mostly indicating unspecific stimulations. Pathway analyses demonstrated interactions of PSMD4 and CNOT7 with ICAM. Conclusions: Long-term vibration did not damage human chondrocytes in vitro. The reduction of osteopontin protein and the down-regulation of PSMD4 and TBX15 gene expression suggest that in vitro long-term vibration might even positively influence cultured chondrocytes.

Published

2018

4. Augmented-Reality-Assisted K-Wire Placement for Glenoid Component Positioning in Reversed Shoulder Arthroplasty: A Proof-of-Concept Study

Author

Fabio Tatti, Johann Henckel, Thorsten Pofahl, Faidon Katinakis, Jörg Opt-Eynde, Christoph Buken, Klaus Schlueter-Brust, and Ferdinando Rodriguez y Baena

Subjects

3D planning, intraoperative imaging, image-guided surgery, Computer science, medicine.medical_treatment, Medicine (miscellaneous), Article, medicine, Component placement, mixed reality, Orthodontics, medicine.diagnostic_test, business.industry, Arthroscopy, Implant failure, Robotics, 3D printing, simulation, Arthroplasty, Mixed reality, augmented reality, Image-guided surgery, Medicine, Augmented reality, Artificial intelligence, business, reversed shoulder arthroplasty

Abstract

The accuracy of the implant’s post-operative position and orientation in reverse shoulder arthroplasty is known to play a significant role in both clinical and functional outcomes. Whilst technologies such as navigation and robotics have demonstrated superior radiological outcomes in many fields of surgery, the impact of augmented reality (AR) assistance in the operating room is still unknown. Malposition of the glenoid component in shoulder arthroplasty is known to result in implant failure and early revision surgery. The use of AR has many promising advantages, including allowing the detailed study of patient-specific anatomy without the need for invasive procedures such as arthroscopy to interrogate the joint’s articular surface. In addition, this technology has the potential to assist surgeons intraoperatively in aiding the guidance of surgical tools. It offers the prospect of increased component placement accuracy, reduced surgical procedure time, and improved radiological and functional outcomes, without recourse to the use of large navigation or robotic instruments, with their associated high overhead costs. This feasibility study describes the surgical workflow from a standardised CT protocol, via 3D reconstruction, 3D planning, and use of a commercial AR headset, to AR-assisted k-wire placement. Post-operative outcome was measured using a high-resolution laser scanner on the patient-specific 3D printed bone. In this proof-of-concept study, the discrepancy between the planned and the achieved glenoid entry point and guide-wire orientation was approximately 3 mm with a mean angulation error of 5°.

Published

2021

5. Fighting Thyroid Cancer with Microgravity Research

Author

Jayashree Sahana, Ruth Hemmersbach, Johann Bauer, Thomas J. Corydon, Christoph Buken, Daniela Grimm, Sascha Kopp, Manfred Infanger, Marcus Krüger, Markus Wehland, and Daniela Melnik

Subjects

Target, Cell, spheroids, Review, Three-dimensional growth, Signal transduction, Catalysis, Metastasis, target, Inorganic Chemistry, Extracellular matrix, lcsh:Chemistry, Aggressiveness, medicine, Animals, Humans, three-dimensional growth, metastasis, Thyroid Neoplasms, Physical and Theoretical Chemistry, Follicular thyroid cancer, Molecular Biology, Thyroid cancer, lcsh:QH301-705.5, Spectroscopy, Weightlessness Simulation, Cell Proliferation, Cell growth, Organic Chemistry, Cancer, General Medicine, aggressiveness, medicine.disease, cytokines, Computer Science Applications, Cell biology, medicine.anatomical_structure, lcsh:Biology (General), lcsh:QD1-999, Thyroid Epithelial Cells, Cancer cell, Gravitationsbiologie, Cytokines, Microgravity, Spheroids, signal transduction

Abstract

Microgravity in space or simulated by special ground-based devices provides an unusual but unique environment to study and influence tumour cell processes. By investigating thyroid cancer cells in microgravity for nearly 20 years, researchers got insights into tumour biology that had not been possible under normal laboratory conditions: adherently growing cancer cells detach from their surface and form three-dimensional structures. The cells included in these multicellular spheroids (MCS) were not only altered but behave also differently to those grown in flat sheets in normal gravity, more closely mimicking the conditions in the human body. Therefore, MCS became an invaluable model for studying metastasis and developing new cancer treatment strategies via drug targeting. Microgravity intervenes deeply in processes such as apoptosis and in structural changes involving the cytoskeleton and the extracellular matrix, which influence cell growth. Most interestingly, follicular thyroid cancer cells grown under microgravity conditions were shifted towards a less-malignant phenotype. Results from microgravity research can be used to rethink conventional cancer research and may help to pinpoint the cellular changes that cause cancer. This in turn could lead to novel therapies that will enhance the quality of life for patients or potentially develop new preventive countermeasures.

Published

2019