@article{SeifertGruberGburecketal.2021,
  author    = {Seifert, Annika and Gruber, Julia and Gbureck, Uwe and Groll, J{\"u}rgen},
  title     = {Morphological control of freeze-structured scaffolds by selective temperature and material control in the ice-templating process},
  series = {Advanced Engineering Materials},
  volume    = {24},
  journal   = {Advanced Engineering Materials},
  number    = {3},
  doi       = {10.1002/adem.202100860},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-256330},
  year      = {2021},
  abstract  = {Herein, it is aimed to highlight the importance of the process parameter choice during directional solidification of polymer solutions, as they have a significant influence on the pore structure and orientation. Biopolymer solutions (alginate and chitosan) are directionally frozen, while systematically varying parameters such as the external temperature gradient, the temperature of the overall system, and the temperatures of the cooling surfaces. In addition, the effect of material properties such as molecular weight, solution concentration, or viscosity on the sample morphology is investigated. By selecting appropriate temperature gradients and cooling surface temperatures, aligned pores ranging in size between (50 ± 22) μm and (144 ± 56) μm are observed in the alginate samples, whereas the pore orientation is influenced by altering the external temperature gradient. As this gradient increases, the pores are increasingly oriented perpendicular to the sample surface. This is also observed in the chitosan samples. However, if the overall system is too cold, that is, using temperatures of the lower cooling surface down to -60 °C combined with low temperatures of the upper cooling surface, control over pore orientation is lost. This is also found when viscosity of chitosan solutions is above ≈5 Pas near the freezing point.},
  language  = {en}
}
@article{StuckensenLamoEspinosaMuinosLopezetal.2019,
  author    = {Stuckensen, Kai and Lamo-Espinosa, Jos{\´e} M. and Mui{\~n}os-L{\´o}pez, Emma and Ripalda-Cembor{\´a}in, Purificaci{\´o}n and L{\´o}pez-Mart{\´i}nez, Tania and Iglesias, Elena and Abizanda, Gloria and Andreu, Ion and Flandes-Iparraguirre, Mar{\´i}a and Pons-Villanueva, Juan and Elizalde, Reyes and Nickel, Joachim and Ewald, Andrea and Gbureck, Uwe and Pr{\´o}sper, Felipe and Groll, J{\"u}rgen and Granero-Molt{\´o}, Froil{\´a}n},
  title     = {Anisotropic cryostructured collagen scaffolds for efficient delivery of RhBMP-2 and enhanced bone regeneration},
  series = {Materials},
  volume    = {12},
  journal   = {Materials},
  number    = {19},
  issn      = {1996-1944},
  doi       = {10.3390/ma12193105},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-195966},
  year      = {2019},
  abstract  = {In the treatment of bone non-unions, an alternative to bone autografts is the use of bone morphogenetic proteins (BMPs), e.g., BMP-2, BMP-7, with powerful osteoinductive and osteogenic properties. In clinical settings, these osteogenic factors are applied using absorbable collagen sponges for local controlled delivery. Major side effects of this strategy are derived from the supraphysiological doses of BMPs needed, which may induce ectopic bone formation, chronic inflammation, and excessive bone resorption. In order to increase the efficiency of the delivered BMPs, we designed cryostructured collagen scaffolds functionalized with hydroxyapatite, mimicking the structure of cortical bone (aligned porosity, anisotropic) or trabecular bone (random distributed porosity, isotropic). We hypothesize that an anisotropic structure would enhance the osteoconductive properties of the scaffolds by increasing the regenerative performance of the provided rhBMP-2. In vitro, both scaffolds presented similar mechanical properties, rhBMP-2 retention and delivery capacity, as well as scaffold degradation time. In vivo, anisotropic scaffolds demonstrated better bone regeneration capabilities in a rat femoral critical-size defect model by increasing the defect bridging. In conclusion, anisotropic cryostructured collagen scaffolds improve bone regeneration by increasing the efficiency of rhBMP-2 mediated bone healing.},
  language  = {en}
}
@article{HeiligSandnerJordanetal.2021,
  author    = {Heilig, Philipp and Sandner, Phoebe and Jordan, Martin Cornelius and Jakubietz, Rafael Gregor and Meffert, Rainer Heribert and Gbureck, Uwe and Hoelscher-Doht, Stefanie},
  title     = {Experimental drillable magnesium phosphate cement is a promising alternative to conventional bone cements},
  series = {Materials},
  volume    = {14},
  journal   = {Materials},
  number    = {8},
  issn      = {1996-1944},
  doi       = {10.3390/ma14081925},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-236633},
  year      = {2021},
  abstract  = {Clinically used mineral bone cements lack high strength values, absorbability and drillability. Therefore, magnesium phosphate cements have recently received increasing attention as they unify a high mechanical performance with presumed degradation in vivo. To obtain a drillable cement formulation, farringtonite (Mg\(_3\)(PO\(_4\))\(_2\)) and magnesium oxide (MgO) were modified with the setting retardant phytic acid (C\(_6\)H\(_{18}\)O\(_{24}\)P\(_6\)). In a pre-testing series, 13 different compositions of magnesium phosphate cements were analyzed concentrating on the clinical demands for application. Of these 13 composites, two cement formulations with different phytic acid content (22.5 wt\% and 25 wt\%) were identified to meet clinical demands. Both formulations were evaluated in terms of setting time, injectability, compressive strength, screw pullout tests and biomechanical tests in a clinically relevant fracture model. The cements were used as bone filler of a metaphyseal bone defect alone, and in combination with screws drilled through the cement. Both formulations achieved a setting time of 5 min 30 s and an injectability of 100\%. Compressive strength was shown to be ~12-13 MPa and the overall displacement of the reduced fracture was <2 mm with and without screws. Maximum load until reduced fracture failure was ~2600 N for the cements only and ~3800 N for the combination with screws. Two new compositions of magnesium phosphate cements revealed high strength in clinically relevant biomechanical test set-ups and add clinically desired characteristics to its strength such as injectability and drillability.},
  language  = {en}
}
@article{FuchsHeiligMcDonoghetal.2020,
  author    = {Fuchs, Konrad F. and Heilig, Philipp and McDonogh, Miriam and Boelch, Sebastian and Gbureck, Uwe and Meffert, Rainer H. and Hoelscher-Doht, Stefanie and Jordan, Martin C.},
  title     = {Cement-augmented screw fixation for calcaneal fracture treatment: a biomechanical study comparing two injectable bone substitutes},
  series = {Journal of Orthopaedic Surgery and Research},
  volume    = {15},
  journal   = {Journal of Orthopaedic Surgery and Research},
  doi       = {10.1186/s13018-020-02009-6},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-230336},
  year      = {2020},
  abstract  = {Background The role of cement-augmented screw fixation for calcaneal fracture treatment remains unclear. Therefore, this study was performed to biomechanically analyze screw osteosynthesis by reinforcement with either a calcium phosphate (CP)-based or polymethylmethacrylate (PMMA)-based injectable bone cement. Methods A calcaneal fracture (Sanders type IIA) including a central cancellous bone defect was generated in 27 synthetic bones, and the specimens were assigned to 3 groups. The first group was fixed with four screws (3.5 mm and 6.5 mm), the second group with screws and CP-based cement (Graftys (R) QuickSet; Graftys, Aix-en-Provence, France), and the third group with screws and PMMA-based cement (Traumacem (TM) V+; DePuy Synthes, Warsaw, IN, USA). Biomechanical testing was conducted to analyze peak-to-peak displacement, total displacement, and stiffness in following a standardized protocol. Results The peak-to-peak displacement under a 200-N load was not significantly different among the groups; however, peak-to-peak displacement under a 600- and 1000-N load as well as total displacement exhibited better stability in PMMA-augmented screw osteosynthesis compared to screw fixation without augmentation. The stiffness of the construct was increased by both CP- and PMMA-based cements. Conclusion Addition of an injectable bone cement to screw osteosynthesis is able to increase fixation strength in a biomechanical calcaneal fracture model with synthetic bones. In such cases, PMMA-based cements are more effective than CP-based cements because of their inherently higher compressive strength. However, whether this high strength is required in the clinical setting for early weight-bearing remains controversial, and the non-degradable properties of PMMA might cause difficulties during subsequent interventions in younger patients.},
  language  = {en}
}
@article{DiloksumpandeRuijterCastilhoetal.2020,
  author    = {Diloksumpan, Paweena and de Ruijter, Myl{\`e}ne and Castilho, Miguel and Gbureck, Uwe and Vermonden, Tina and van Weeren, P Ren{\´e} and Malda, Jos and Levato, Riccardo},
  title     = {Combining multi-scale 3D printing technologies to engineer reinforced hydrogel-ceramic interfaces},
  series = {Biofabrication},
  volume    = {12},
  journal   = {Biofabrication},
  number    = {2},
  doi       = {10.1088/1758-5090/ab69d9},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-254005},
  year      = {2020},
  abstract  = {Multi-material 3D printing technologies that resolve features at different lengths down to the microscale open new avenues for regenerative medicine, particularly in the engineering of tissue interfaces. Herein, extrusion printing of a bone-biomimetic ceramic ink and melt electrowriting (MEW) of spatially organized polymeric microfibres are integrated for the biofabrication of an osteochondral plug, with a mechanically reinforced bone-to-cartilage interface. A printable physiological temperature-setting bioceramic, based on α-tricalcium phosphate, nanohydroxyapatite and a custom-synthesized biodegradable and crosslinkable poloxamer, was developed as bone support. The mild setting reaction of the bone ink enabled us to print directly within melt electrowritten polycaprolactone meshes, preserving their micro-architecture. Ceramic-integrated MEW meshes protruded into the cartilage region of the composite plug, and were embedded with mechanically soft gelatin-based hydrogels, laden with articular cartilage chondroprogenitor cells. Such interlocking design enhanced the hydrogel-to-ceramic adhesion strength >6.5-fold, compared with non-interlocking fibre architectures, enabling structural stability during handling and surgical implantation in osteochondral defects ex vivo. Furthermore, the MEW meshes endowed the chondral compartment with compressive properties approaching those of native cartilage (20-fold reinforcement versus pristine hydrogel). The osteal and chondral compartment supported osteogenesis and cartilage matrix deposition in vitro, and the neo-synthesized cartilage matrix further contributed to the mechanical reinforcement at the ceramic-hydrogel interface. This multi-material, multi-scale 3D printing approach provides a promising strategy for engineering advanced composite constructs for the regeneration of musculoskeletal and connective tissue interfaces.},
  language  = {en}
}