@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} } @phdthesis{Renner2018, author = {Renner, Tobias}, title = {In vitro Testverfahren zur Qualifizierung von Knochenklebstoffen}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-161546}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2018}, abstract = {Knochenklebstoffe, welche eine unkonventionelle M{\"o}glichkeit im Bereich der chirurgischen Frakturversorgung darstellen, m{\"u}ssen bereits in vitro eine Reihe an klinischen Anforderungen erf{\"u}llen. Hinsichtlich entsprechender Pr{\"u}fverfahren wurde noch keine Normierungsarbeit geleistet, weswegen Ergebnisse verschiedener Arbeiten schwierig vergleichbar sind. Ziel der Arbeit war es daher Pr{\"u}fverfahren vorzustellen, welche die Besonderheiten des „Werkstoffes Knochen" ber{\"u}cksichtigen. In diesem Rahmen werden zwei neuartigen Klebstoffsysteme, ein in situ h{\"a}rtender Knochenzement aus Trimagnesiumphosphat, Magnesiumoxid und organischer Phytins{\"a}ure und ein lichth{\"a}rtender Knochenklebstoff aus Polyethylenglycoldimethacrylat, NCO-sP(EO-stat-PO), Campherchinon und anorganischen Newberyit-F{\"u}llern, vorgestellt. Neben diesen sind drei kommerziell erh{\"a}ltliche Klebstoffe Gegenstand der Untersuchung. Dies sind zum einen Histoacryl® und TruGlue® Gewebekleber, zwei Klebstoffe auf Cyanoacrylat-Basis mit unterschiedlich langer Alkyl-Seitenkette, zum anderen Bioglue®, ein Gewebekleber aus Albumin und Glutaraldehyd. Bei den Klebstoffen wurde die Zug- und Scherfestigkeit unter Einfluss der physiologischen Klebstoffalterung, der Variation der Klebefugenbreite, der Variation von komplement{\"a}ren F{\"u}geteilen, sowie F{\"u}geteiloberfl{\"a}chen inspiziert. Makro- und mikroskopische, sowie elektronenmikroskopischen Untersuchung der Bruchfl{\"a}chen auf mikrostrukturelle Besonderheiten und Versagemechanismus wurden angestellt. Die neuartigen Klebstoffsysteme unterliegen zwar den konventionellen Cyanoacrylaten hinsichtlich mechanischer Parameter, weisen aber dennoch ad{\"a}quate Klebefestigkeiten auf bei zugleich zahlreichen Vorteilen gegen{\"u}ber konventionellen Systemen im Umgang mit Knochen. Gerade der Magnesiumphosphatzement scheint auf Grund mechanischer Parameter und Vorz{\"u}gen wie der guten Biokompatibilit{\"a}t und biologischen Abbaubarkeit, Osteoinduktivit{\"a}t, Osteokonduktivit{\"a}t, der einfachen Applizierbarkeit, einem hohen Kosten-Nutzen-Faktor oder dem g{\"u}nstigen Verhalten in w{\"a}ssrigen Milieu vielversprechend.}, subject = {bone}, language = {de} } @phdthesis{Stuckensen2016, author = {Stuckensen, Kai}, title = {Fabrication of hierarchical cell carrier matrices for tissue regeneration by directional solidification}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-145510}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {The key hypothesis of this work represented the question, if mimicking the zonal composition and structural porosity of musculoskeletal tissues influences invading cells positively and leads to advantageous results for tissue engineering. Conventional approaches in tissue engineering are limited in producing monolithic "scaffolds" that provide locally variating biological key signals and pore architectures, imitating the alignment of collagenous fibres in bone and cartilage tissues, respectively. In order to fill this gap in available tissue engineering strategies, a new fabrication technique was evolved for the production of scaffolds to validate the hypothesis. Therefore, a new solidification based platform procedure was developed. This process comprises the directional solidification of multiple flowable precursors that are "cryostructured" to prepare a controlled anisotropic pore structure. Porous scaffolds are attained through ice crystal removal by lyophilisation. Optionally, electrostatic spinning of polymers may be applied to provide an external mesh on top or around the scaffolds. A consolidation step generates monolithic matrices from multi zonal structures. To serve as matrix for tissue engineering approaches or direct implantation as medical device, the scaffold is sterilized. An Adjustable Cryostructuring Device (ACD) was successively developed; individual parts were conceptualized by computer aided design (CAD) and assembled. During optimisation, a significant performance improvement of the ACDs accessible external temperature gradient was achieved, from (1.3 ± 0.1) K/mm to (9.0 ± 0.1) K/mm. Additionally, four different configurations of the device were made available that enabled the directional solidification of collagenous precursors in a highly controlled manner with various sample sizes and shapes. By using alginate as a model substance the process was systematically evaluated. Cryostructuring diagraphs were analysed yielding solidification parameters, which were associated to pore sizes and alignments that were determined by image processing. Thereby, a precise control over pore size and alignment through electrical regulation of the ACD could be demonstrated. To obtain tissue mimetic scaffolds for the musculoskeletal system, collagens and calcium phosphates had to be prepared to serve as raw materials. Extraction and purification protocols were established to generate collagen I and collagen II, while the calcium phosphates brushite and hydroxyapatite were produced by precipitation reactions. Besides the successive augmentation of the ACD also an optimization of the processing steps was crucial. Firstly, the concentrations and the individual behaviour of respective precursor components had to be screened. Together with the insights gained by videographic examination of solidifying collagen solutions, essential knowledge was gained that facilitated the production of more complex scaffolds. Phenomena of ice crystal growth during cryostructuring were discussed. By evolutionary steps, a cryostructuring of multi-layered precursors with consecutive anisotropic pores could be achieved and successfully transferred from alginate to collagenous precursors. Finally, very smooth interfaces that were hardly detectable by scanning electron microscopy (SEM) could be attained. For the used collagenous systems, a dependency relation between adjustable processing parameters and different resulting solidification morphologies was created. Dehydrothermal-, diisocyanate-, and carbodiimide- based cross linking methods were evaluated, whereby the "zero length" cross linking by carbodiimide was found to be most suitable. Afterwards, a formulation for the cross linking solution was elaborated, which generated favourable outcomes by application inside a reduced pressure apparatus. As a consequence, a pore collapse during wet chemical cross linking could be avoided. Complex monolithic scaffolds featuring continuous pores were fabricated that mimicked structure and respective composition of different areas of native tissues by the presence of biochemical key stimulants. At first, three types of bone scaffolds were produced from collagen I and hydroxyapatite with appropriate sizes to fit critical sized defects in rat femurs. They either featured an isotropic or anisotropic porosity and partly also contained glycosaminoglycans (GAGs). Furthermore, meniscus scaffolds were prepared by processing two precursors with biomimetic contents of collagen I, collagen II and GAGs. Here, the pore structures were created under boundary conditions, which allowed an ice crystal growth that was nearly orthogonal to the external temperature gradient. Thereby, the preferential alignment of collagen fibres in the natural meniscus tissue could be mimicked. Those scaffolds owned appropriate sizes for cell culture in well plates or even an authentic meniscus shape and size. Finally, osteochondral scaffolds, sized to either fit well plates or perfusion reactors for cell culture, were fabricated to mimic the composition of subchondral bone and different cartilage zones. Collagen I and the resorbable calcium phosphate brushite were used for the subchondral zone, whereas the cartilage zones were composed out of collagen I, collagen II and tissue mimetic contents of GAGs. The pore structure corresponded to the one that is dominating the volume of natural osteochondral tissue. Energy dispersive X-ray spectroscopy (EDX) and SEM were used to analyse the composition and pore structure of the individual scaffold zones, respectively. The cross section pore diameters were determined to (65 ± 25) µm, (88 ± 35) µm and(93 ± 42) µm for the anisotropic, the isotropic and GAG containing isotropic bone scaffolds. Furthermore, the meniscus scaffolds showed pore diameters of (93 ± 21) µm in the inner meniscus zone and (248 ± 63) µm inside the outer meniscus zone. Pore sizes of (82 ± 25) µm, (83 ± 29) µm and (85 ± 39) µm were present inside the subchondral, the lower chondral and the upper chondral zone of osteochondral scaffolds. Depending on the fabrication parameters, the respective scaffold zones were also found to feature a specific micro- and nanostructure at their inner surfaces. Degradation studies were carried out under physiological conditions and resulted in a mean mass loss of (0.52 ± 0.13) \%, (1.56 ± 0.10) \% and (0.80 ± 0.10) \% per day for bone, meniscus and osteochondral scaffolds, respectively. Rheological measurements were used to determine the viscosity changes upon cooling of different precursors. Micro computer tomography (µ-CT) investigations were applied to characterize the 3D microstructure of osteochondral scaffolds. To obtain an osteochondral scaffold with four zones of tissue mimetic microstructure alignment, a poly (D, L-lactide-co-glycolide) mesh was deposited on the upper chondral zone by electrostatic spinning. In case of the bone scaffolds, the retention / release capacity of bone morphogenetic protein 2 (BMP-2) was evaluated by an enzyme linked immunosorbent assay (ELISA). Due to the high presence of attractive BMP binding sites, only less than 0.1 \% of the initially loaded cytokine was released. The suitability of combining the cryostructuring process with 3D powder printed calcium phosphate substrates was evaluated with osteochondral scaffolds, but did not appear to yield more preferable results than the non-combined approach. A new custom build confined compression setup was elaborated together with a suitable evaluation procedure for the mechanical characterisation under physiological conditions. For bone and cartilage scaffolds, apparent elastic moduli of (37.6 ± 6.9) kPa and (3.14 ± 0.85) kPa were measured. A similar behaviour of the scaffolds to natural cartilage and bone tissue was demonstrated in terms of elastic energy storage. Under physiological frequencies, less than 1.0 \% and 0.8 \% of the exerted energy was lost for bone and cartilage scaffolds, respectively. With average relaxation times of (0.613 ± 0.040) sec and (0.815 ± 0.077) sec, measured for the cartilage and bone scaffolds, they respond four orders of magnitude faster than the native tissues. Additionally, all kinds of produced scaffolds were able to withstand cyclic compression at un-physiological frequencies as high as 20 Hz without a loss in structural integrity. With the presented new method, scaffolds could be fabricated whose extent in mimicking of native tissues exceeded the one of scaffolds producible by state of the art methods. This allowed a testing of the key hypothesis: The biological evaluation of an anisotropic pore structure in vivo revealed a higher functionality of immigrated cells and led finally to advantageous healing outcomes. Moreover, the mimicking of local compositions in combination with a consecutive anisotropic porosity that approaches native tissue structures could be demonstrated to induce zone specific matrix remodelling in stem cells in vitro. Additionally, clues for a zone specific chondrogenic stem cell differentiation were attained without the supplementation of growth factors. Thereby, the hypothesis that an increased approximation of the hierarchically compositional and structurally anisotropic properties of musculoskeletal tissues would lead to an improved cellular response and a better healing quality, could be confirmed. With a special focus on cell free in situ tissue engineering approaches, the insights gained within this thesis may be directly transferred to clinical regenerative therapies.}, subject = {Tissue Engineering}, language = {en} } @article{RathBrandlHilleretal.2014, author = {Rath, Subha N. and Brandl, Andreas and Hiller, Daniel and Hoppe, Alexander and Gbureck, Uwe and Horch, Raymund E. and Boccaccini, Aldo R. and Kneser, Ulrich}, title = {Bioactive Copper-Doped Glass Scaffolds Can Stimulate Endothelial Cells in Co-Culture in Combination with Mesenchymal Stem Cells}, series = {PLOS ONE}, volume = {9}, journal = {PLOS ONE}, number = {12}, issn = {1932-6203}, doi = {10.1371/journal.pone.0113319}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-114339}, year = {2014}, abstract = {Bioactive glass (BG) scaffolds are being investigated for bone tissue engineering applications because of their osteoconductive and angiogenic nature. However, to increase the in vivo performance of the scaffold, including enhancing the angiogenetic growth into the scaffolds, some researchers use different modifications of the scaffold including addition of inorganic ionic components to the basic BG composition. In this study, we investigated the in vitro biocompatibility and bioactivity of Cu2+-doped BG derived scaffolds in either BMSC (bone-marrow derived mesenchymal stem cells)-only culture or co-culture of BMSC and human dermal microvascular endothelial cells (HDMEC). In BMSC-only culture, cells were seeded either directly on the scaffolds (3D or direct culture) or were exposed to ionic dissolution products of the BG scaffolds, kept in permeable cell culture inserts (2D or indirect culture). Though we did not observe any direct osteoinduction of BMSCs by alkaline phosphatase (ALP) assay or by PCR, there was increased vascular endothelial growth factor (VEGF) expression, observed by PCR and ELISA assays. Additionally, the scaffolds showed no toxicity to BMSCs and there were healthy live cells found throughout the scaffold. To analyze further the reasons behind the increased VEGF expression and to exploit the benefits of the finding, we used the indirect method with HDMECs in culture plastic and Cu2+-doped BG scaffolds with or without BMSCs in cell culture inserts. There was clear observation of increased endothelial markers by both FACS analysis and acetylated LDL (acLDL) uptake assay. Only in presence of Cu2+-doped BG scaffolds with BMSCs, a high VEGF secretion was demonstrated by ELISA; and typical tubular structures were observed in culture plastics. We conclude that Cu2+-doped BG scaffolds release Cu2+, which in turn act on BMSCs to secrete VEGF. This result is of significance for the application of BG scaffolds in bone tissue engineering approaches.}, language = {en} }