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List of publications Kevin Tröndle
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Journal Articles Years: 2023 |
2022 |
2021 |
2020 |
2019 |
2017 | show all back to the top of all publications J. Weygant, F. Koch, K. Adam, K. Tröndle, R. Zengerle, G. Finkenzeller, S. Kartmann, P. Koltay, S. ZimmermannA Drop-on-Demand Bioprinting Approach to Spatial Arrangement of Multiple Cell Types and Monitoring Their Cell–Cell Interactions towards Vascularization Based on Endothelial Cells and Mesenchymal Stem Cells 2023 Cells , volume : 12, issue : 4, page : 646 K. Tröndle, G. Miotto, L. Rizzo, R. Pichler, F. Koch, P. Koltay, R. Zengerle, S. S. Lienkamp, S. Kartmann, S. ZimmermannDeep Learning-Assisted Nephrotoxicity Testing with Bioprinted Renal Spheroids 2022 Int. J. Bioprint , volume : 8, issue : 2, page : 528 F. Koch, O. Thaden, S. Conrad, K. Tröndle, G. Finkenzeller, R. Zengerle, S. Kartmann, S. Zimmermann, P. KoltayMechanical properties of polycaprolactone (PCL) scaffolds for hybrid 3D-bioprinting with alginate-gelatin hydrogel 2022 J. Mech. Behav. Biomed. Mat. , volume : 130, page : 105219 F. Koch, O. Thaden, K. Tröndle, R. Zengerle, S. Zimmermann, P. KoltayOpen-source hybrid 3D-bioprinter for simultaneous printing of thermoplastics and hydrogels 2021 HardwareX , volume : 10, page : e00230 F. Koch, K. Tröndle, G. Finkenzeller, R. Zengerle, S. Zimmermann, P. KoltayGeneric method of printing window adjustment for extrusion-based 3D-bioprinting to maintain high viability of mesenchymal stem cells in an alginate-gelatin hydrogel 2020 Bioprinting , page : e00094» show abstract « hide abstract Abstract Over the last decade, bioprinting of artificial tissues has been developed into a significant field of research. With an increasing number of printing technologies and bioinks used in bioprinting, its complexity increases as both the printing technology and the properties of the bioink influence the cell biological functionality and printing accuracy of the printed tissue. Therefore, optimization of bioprinting processes often remains a challenge, which could be solved by a smart fine-tuning of the process parameters. We present a novel method to adjust the printing window for extrusion-based bioprinting on the basis of a two-step assessment to determine process parameters such as nozzle size, extrusion flow rate, and printing temperature. First, a suitable printing temperature is deduced from the bioink properties and second nozzle size and extrusion flow rate is selected in a way that the immediate cell damage after printing is reduced. For both steps only basic rheological properties of the bioinks need to be known as well as detailed knowledge of the cell survival in the bioink for different shear stresses.
This method is applied to an exemplary alginate-gelatin hydrogel to show how the printing temperature affects the achievable printing accuracy. For this bioink, viability of immortalized mesenchymal stem cells (iMSC) decreases with about 4% per thousand Pascal increase in maximum shear stress. For different combinations of flow rate, nozzle size and nozzle shape it is shown, that only the maximum shear stress experienced by the iMSCs influences average cell viability. Factors like flow rate, nozzle size and shape only play an indirect role by influencing the maximum shear stress and individually have no significant influence on cell viability.
The experimental results allow a direct adjustment of printing parameters for the presented combination of hydrogel and cell type but are not limited to it. For other bioinks, the described generic method can be easily used to systematically adjust the printing parameters. For this purpose, only the basic rheological properties and the influence of shear stress on cell survival need to be known and process parameters can be set concerning the respective application. P. Rukavina, F. Koch, M. Wehrle, K. Tröndle, G. B. Stark, P. Koltay, S. Zimmermann, R. Zengerle, F. Lampert, S. Strassburg, G. Finkenzeller, F. SimunovicIn vivo evaluation of bioprinted prevascularized bone tissue 2020 Biotechnol Bioeng , pages : 1 - 10» show abstract « hide abstract Abstract Bioprinting can be considered as a progression of the classical tissue engineering approach, in which cells are randomly seeded into scaffolds. Bioprinting offers the advantage that cells can be placed with high spatial fidelity within three‐dimensional tissue constructs. A decisive factor to be addressed for bioprinting approaches of artificial tissues is that almost all tissues of the human body depend on a functioning vascular system for the supply of oxygen and nutrients. In this study, we have generated cuboid prevascularized bone tissue constructs by bioprinting human adipose‐derived mesenchymal stem cells (ASCs) and human umbilical vein endothelial cells (HUVECs) by extrusion‐based bioprinting and drop‐on‐demand (DoD) bioprinting, respectively. The computer‐generated print design could be verified in vitro after printing. After subcutaneous implantation of bioprinted constructs in immunodeficient mice, blood vessel formation with human microvessels of different calibers could be detected arising from bioprinted HUVECs and stabilization of human blood vessels by mouse pericytes was observed. In addition, bioprinted ASCs were able to synthesize a calcified bone matrix as an indicator of ectopic bone formation. These results indicate that the combined bioprinting of ASCs and HUVECs represents a promising strategy to produce prevascularized artificial bone tissue for prospective applications in the treatment of critical‐sized bone defects. K. Tröndle, F. Koch, G. Finkenzeller, G. B. Stark, R. Zengerle, P. Koltay, S. ZimmermannBioprinting of high cell density constructs leads to controlled lumen formation with self‐assembly of endothelial cells 2019 Journal of Tissue Engineering and Regenerative Medicine , volume : 13, issue : 10, pages : 1883 - 1895» show abstract « hide abstract Abstract Active nutrient supply and waste product removal are key requirements for the fabrication of long term viable and functional tissue constructs of considerable size. This work aims to contribute to the fabrication of artificial perfusable networks with a bioprinting process, based on drop‐on‐demand (DoD) printing of primary endothelial cell (EC) suspension bioink (25 · 106 ± 3 · 106 cells/ml). The process results in prescribed lumen between two hydrogel layers, allowing its integration in common layering based bioprinting processes. Low volume bioink droplets (appr. 10 nl) as building blocks, were deposited between two fibrin or collagen I layers to realize shapeable, cell‐rich aggregates. Unattainable with manual positioning, DoD printing allowed precise fabrication of various designs, such as spheroidal‐, line‐shaped and Y‐branch cellular structures, with a mean lateral extension of 285 ± 81 μm. For basic characterization, the cell suspension building blocks were systematically compared to preformed spheroids of the same cell type, passage and number. Post printing investigations of initially loose cell arrangements showed self‐assembly and formation of central lumen with a mean cross‐sectional area of Ølumen = 6400 μm2 at day 3, lined by a single layer of CD31 positive ECs, as evaluated by confocal microscopy. Originating from this main lumen smaller, undirected side‐branches (Øbranches = 740 μm2) were formed by sprouting cells, inducing a first step towards a simplistic hierarchically organized network. These lumen could prospectively help for tissue construct perfusion in vitro or, potentially, as niche for angiogenesis of host vascularization in implants. L. Benning, L. Gutzweiler, K. Tröndle, J. Riba, R. Zengerle, P. Koltay, S. Zimmermann, G. B. Stark, G. FinkenzellerAssessment of hydrogels for bioprinting of endothelial cells 2017 J Biomed Mater Res A , pages : 935 - 947» show abstract « hide abstract Abstract In tissue engineering applications, vascularization can be accomplished by co-implantation of
tissue forming cells and endothelial cells (ECs), whereby the latter are able to form functional
blood vessels. The use of three-dimensional (3D) bioprinting technologies has the potential to
improve the classical tissue engineering approach because these will allow the generation of
scaffolds with high spatial control of endothelial cell allocation. This study focuses on a side
by side comparisons of popular commercially available bioprinting hydrogels (matrigel,
fibrin, collagen, gelatin, agarose, Pluronic F-127, alginate and alginate/gelatin) in the context
of their physicochemical parameters, their swelling/degradation characteristics, their
biological effects on vasculogenesis-related EC parameters and their printability. The aim of
this study was to identify the most suitable hydrogel or hydrogel combination for inkjet
printing of ECs to build pre-vascularized tissue constructs. Most tested hydrogels displayed
physicochemical characteristics suitable for inkjet printing. However, Pluronic F-127 and the
alginate/gelatin blend were rapidly degraded when incubated in cell culture medium. Agarose,
Pluronic F-127, alginate and alginate/gelatin hydrogels turned out to be unsuitable for
bioprinting of ECs because of their non-adherent properties and/or their incapability to
support EC proliferation. Gelatin was able to support EC proliferation and viability but was
unable to support endothelial cell sprouting. Our experiments revealed fibrin and collagen to
be most suitable for bioprinting of ECs, because these hydrogels showed acceptable
swelling/degradation characteristics, supported vasculogenesis-related EC parameters and
showed good printability. Moreover, ECs in constructs of preformed spheroids survived the
printing process and formed capillary-like cords. L. Benning, L. Gutzweiler, K. Tröndle, J. Riba, R. Zengerle, P. Koltay, S. Zimmermann, G.B. Stark, G. FinkenzellerCytocompatibility testing of hydrogels toward bioprinting of mesenchymal stem cells 2017 J Biomed Mater Res A , volume : 105, pages : 3231 - 3241» show abstract « hide abstract Abstract Mesenchymal stem cells (MSCs) represent a very attractive cell source for tissue engineering applications aiming at the generation of artificial bone substitutes. The use of three-dimensional bioprinting technologies has the potential to improve the classical tissue engineering approach because bioprinting will allow the generation of hydrogel scaffolds with high spatial control of MSC allocation within the bioprinted construct. In this study, we have performed direct comparisons between commercially available hydrogels in the context of their cytocompatibility toward MSCs and their physicochemical parameters with the aim to identify the most suitable hydrogel for drop-on-demand (DoD) printing of MSCs. In this context, we examined matrigel, fibrin, collagen, gelatin, and gelatin/alginate at various hydrogel concentrations. Matrigel, fibrin, collagen, and gelatin were able to support cell viability, but the latter showed a limited potential to promote MSC proliferation. We concentrated our study on fibrin and collagen hydrogels and investigated the effect of hydroxyapatite (HA) inclusion. The inclusion of HA enhanced proliferation and osteogenic differentiation of MSCs and prevented degradation of fibrin in vitro. According to viscosity and storage moduli measurements, HA-blends displayed physicochemical characteristics suitable for DoD printing. In bioprinting experiments, we confirmed that fibrin and collagen and their respective HA-blends represent excellent hydrogels for DoD-based printing as evidenced by high survival rates of printed MSCs. L. Gutzweiler, S. Kartmann, K. Troendle, L. Benning, G. Finkenzeller, R. Zengerle, P. Koltay, B. Stark, S. ZimmermannLarge scale production and controlled deposition of single HUVEC spheroids for bioprinting applications 2017 Biofabrication , volume : 9 (2), page : 02502» show abstract « hide abstract Abstract We present 1.) a fast and automated method for large scale production of HUVEC spheroids based on the hanging drop method and 2.) a novel method for well-controlled lateral deposition of single spheroids by drop-on-demand printing. Large scale spheroid production is achieved via printing 1536 droplets of HUVEC cell suspension having a volume of 1 µl each within 3 minutes at a pitch of 2.3 mm within an array of 48 x 32 droplets onto a flat substrate. Printing efficiencies between 97.9% and 100% and plating efficiencies between 87.3% and 100% were achieved. Harvested spheroids (consisting of approx. 250 HUVECs each) appear uniform in size and shape. After incubation and harvesting, the spheroids are deposited individually in user-defined patterns onto hydrogels using an automated drop-on-demand dispenser setup. Controlled by an image detection algorithm focusing the dispenser nozzle, droplets containing exactly one spheroid are printed onto a substrate, while all other droplets are discarded. Using this approach an array of 6 x 3 HUVEC spheroids with intermediate distances of 500 µm embedded in fibrin was generated. Successful progress of spheroid sprouting and merging of neighboring sprouts was observed during the first 72 hours of incubation indicating a good viability of the deposited spheroids.
Conference papers Years: 2021 |
2020 |
2019 |
2018 | show all back to the top of all publications J. Weygant, F. Koch, K. Troendle, G. Finkenzeller, R. Zengerle, S. Kartmann, S. Zimmermann, P. KoltayDrop-on-Demand Bioprinting Approach For Precise
Alignment and Interaction Studies of Different Cell Types 2021 International Conference on Biofabrication, Australia, 27. – 29.09.2021 (online) K. Tröndle, A. Itani, F. Koch, R. Zengerle, P. Koltay, S. ZimmermannDrop-on-demand bioprinting solutions for the fabrication of 3D cell culture systems 2021 DECHEMA 3D Cell Culture Freiburg (online), 05.-07.05.2021 F. Koch, K. Tröndle, G. Finkenzeller, P. Rukavina, R. Zengerle, P. Koltay, S. ZimmermannHybrider 3D-Biodruck zur künstlichen Herstellung von Knochen / Using hybrid processes for 3D-bioprinting of artificial bone tissue 2021 MST-Kongress, Ludwigsburg, 08.-10.11.2021 K. Tröndle, A. Itani, F. Koch, R. Zengerle, S. Zimmermann, P. KoltayFabrication and fluidic integration of self-assembled cellular microtubules for nephron-on-chip applications 2020 MicroTAS 2020, 04.-09.10.2020, virtual F. Koch, M. Wehrle, K. Tröndle, P. Koltay, G. Finkenzeller, R. Zengerle, S. ZimmermannRapid assessment of combined drop on demand and extrusion-based bioprinting with controlled shear stress and high shape fidelity 2019 Transducers 2019 - EUROSENSORS XXXIII 23. -27. Juni 2019 - Berlin, Germany » show abstract « hide abstract Abstract We present a novel combination of drop on demand
(DoD) and extrusion-based bioprinting to generate highprecision
patterns of cells inside large hydrogel volumes.
Extrusion-based bioprinting has the great advantage
of enabling a fast deposition of high viscous cell-loaded
hydrogel with reasonable precision. Compromises
between high shape fidelity and cell viability, as well as
short process times often require many iterations of
optimizing process parameters and varying compositions
of the hydrogel. To limit the multitude of parameters
during extrusion-based bioprinting, a method for rapid
process assessment was developed. This enables to define
limits for printing temperature, flow rate and nozzle size
from basic rheological measurements with regard to the
biological and mechanical requirements.
The combination of extrusion-based bioprinting with
DoD bioprinting allows for precise deposition of low
viscous cell suspension and adjustable concentrations of
crosslinking agent. Together, the technologies were used
to print a bone replacement model by using the predefined
process parameters. Adiposed-derived stem cells
(ASC) prone to osteogenic differentiation were
homogenously extruded in a cuboid structure of
10x10x5 mm. Human umbilical vein endothelial cells
(HUVEC) were printed as highly dense cell suspension
lines inside the extruded hydrogel to allow a potential
vascularization of the structure in vivo. F. Koch, M. Wehrle, K. Tröndle, P. Koltay, G. Finkenzeller, R. Zengerle, S. ZimmermannRapid assessment of extrusion based bioprinting by controlling shear stresses on cells 2019 Transducers 2019, Berlin, 23.06. - 27.06.2019 K. Tröndle, S. Kartmann, L. Gutzweiler, R. Zengerle, P. Koltay, S. ZimmermannBioprinting with spheroids: Automated large-scale production and deposition 2018 3D Cell Culture 2018, 5. - 7. Juni 2018, Freiburg K. TröndleDrop-on-Demand Bioprinting Process for Single-Spheroid Deposition and Immobilization 2018 International Conference on Biofabrication, Würzburg, 28. – 31.10.2018 Credits: SILK Icons by http://www.famfamfam.com/lab/icons/silk/