Dipl.-Ing. Jennifer Fritz
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jennifer.fritz@donau-uni.ac.at
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+43 2732 893-5384
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Zum Kontaktformular
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Campus Krems, Trakt D, 2. Stock, 2.08
- Universität für Weiterbildung Krems
- Zentrum für Regenerative Medizin
- Dr.-Karl-Dorrek-Straße 30
- 3500 Krems
- Österreich
Projekte (Auszug Forschungsdatenbank)
Laufende Projekte
Projektzeitraum: 01.01.2022–31.12.2024
Projektverantwortung (Universität für Weiterbildung Krems): Alexander Otahal
Fördergeber: Bundesländer (inkl. deren Stiftungen und Einrichtungen)
Publikationen (Auszug Forschungsdatenbank)
Fritz, J.; Moser, A.-C.; Otahal, A.; Kramer, K.; Casurovic, S.; Teuschl-Woller, A. H.; Nehrer, S. (2025). Hydrostatic Pressure Enhances Chondrogenic Differentiation of Mesenchymal Stem Cells in Silk Fibroin-Based 3D Bioprinted Hydrogels. Biomacromolecules, -: https://doi.org/10.1021/acs.biomac.5c00048
Fritz, J.; Moser, A.-C.; Otahal, A.; Redl, H.; Teuschl-Woller, A. H.; Schneider, K. H., Nehrer, S. Andreas H. Teuschl-Woller, Karl H. Schneider, and Stefan Nehrer (2025). Silk Fibroin-Based Hydrogels Supplemented with Decellularized Extracellular Matrix and Gelatin Facilitate 3D Bioprinting for Meniscus Tissue Engineering. Macromolecular Bioscience, 2400515: https://doi.org/10.1002/mabi.202400515
Moser, Anna-Christina; Fritz, Jennifer; Kesselring, Andreas; Schüssler, Florian; Otahal, Alexander; Nehrer, Stefan (2025). Biomechanical testing of virtual meniscus implants made from a bi-phasic silk fibroin-based hydrogel and polyurethane via finite element analysis. Journal of the Mechanical Behavior of Biomedical Materials, 162: 106830
Vukonic, L.; Nothnagel, R.M.; Groß, F.; Bauer, C.; Fritz, J.; Thurner, P.; Gachot, C.; Ripoll, M.R. (2025). Cartilage-inspired biocompatible double network PVA based hydrogels: A critical comparison of the role of agarose, chitosan, and silk fibroin additives. Materials Today Communications, 45: 1-11
Moser, Anna-Christina; Fritz, Jennifer (2023). Meniskusregernation durch 3D-(Bio)Druck. Jatros Orthopädie & Traumatologie Rheumatologie, 2: https://doi.org/10.
Vorträge (Auszug Forschungsdatenbank)
Integration von additiver Fertigung und in-silico Simulation: Design und Finite-Element-Analyse von 3D-druckbaren Meniskusimplantaten
Digital Orthopedics Award by OPED, 12.12.2024
3D bioprinted silk fibroin-based hydrogels for meniscus tissue engineering
6th MuSkITYR symposium, 04.11.2024
Advancements in the Development of 3D-Printed Meniscal Implants: Virtual Prototyping and Biomechanical Assessment
7th ICRS Summit, 27.09.2024
Meniskus Bioprinting: Biomaterialeigenschaften & Finite Elemente Analyse
AGA Denkfabrik, 06.07.2024
Biomechanische in-silico Evaluierung eines 3D gedruckten Meniskus-Implantates mittels Finiter Element Analyse
GOTS, 39. Jahreskongress, 20.06.2024
Wie wird eine Biotinte zum 3D gedruckten Gewebe für die Regenerative Medizin
Lange Nacht der Forschung 2024, 24.05.2024
3D printed shock absorbers for the human knee joint
Pint of Science, 14.05.2024
Enhancing meniscus implant biomechanics: an in-silico analysis through 3D printing
OARSI World Congress on Osteoarthritis, 18.04.2024
Comparison of two silk fibroin-based bioinks for meniscus bioprinting
OARSI World Congress on Osteoarthritis, 18.04.2024
Formulation and biomechanical characterisation of a silk fibroin-based bioink for meniscus replacement via bioprinting
LBG Meeting for Health Sciences 2023, 02.11.2023
Formulation and biomechanical characterisation of a silk fibroin-based bioink for meniscus replacement via bioprinting
17th World Congress ICRS 2023, 10.09.2023
Menisc-3D-SilkPrint
M3d+it Conference, 02.12.2022
The potential of mulberry and non-mulberry silk fibroin bioinks for meniscus regeneration by 3D-bioprinting’
Joint KMM-VIN / ViCEM / ESB cross-disciplinary workshop, 22.09.2022
The potential of mulberry and non-mulberry silk fibroin blends as bioinks for meniscus regeneration by 3D-bioprinting
TERMIS EU 2022, 28.06.2022
Cartilage derived extracellular matrix incorporated silk fibroin hybrid scaffolds for endochondral ossification mediated bone tissue regeneration
TERMIS EU 2022, 28.06.2022
The potential of mulberry and non-mulberry silk fibroin blends as bioinks for meniscus regeneration by 3D-bioprinting
Summer school ‘Frontiers in Regenerative Medicine’, 23.05.2022
