@article{GeffersGrollGbureck2015,
  author    = {Geffers, Martha and Groll, J{\"u}rgen and Gbureck, Uwe},
  title     = {Reinforcement strategies for load-bearing calcium phosphate biocements},
  series = {Materials},
  volume    = {8},
  journal   = {Materials},
  doi       = {10.3390/ma8052700},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-148636},
  pages     = {2700-2717},
  year      = {2015},
  abstract  = {Calcium phosphate biocements based on calcium phosphate chemistry are well-established biomaterials for the repair of non-load bearing bone defects due to the brittle nature and low flexural strength of such cements. This article features reinforcement strategies of biocements based on various intrinsic or extrinsic material modifications to improve their strength and toughness. Altering particle size distribution in conjunction with using liquefiers reduces the amount of cement liquid necessary for cement paste preparation. This in turn decreases cement porosity and increases the mechanical performance, but does not change the brittle nature of the cements. The use of fibers may lead to a reinforcement of the matrix with a toughness increase of up to two orders of magnitude, but restricts at the same time cement injection for minimal invasive application techniques. A novel promising approach is the concept of dual-setting cements, in which a second hydrogel phase is simultaneously formed during setting, leading to more ductile cement-hydrogel composites with largely unaffected application properties.},
  language  = {en}
}
@phdthesis{SchamelgebGeffers2017,
  author    = {Schamel [geb. Geffers], Martha},
  title     = {Novel dual setting approaches for mechanically reinforced mineral biocements},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-154946},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2017},
  abstract  = {Calcium phosphate biocements are inherently brittle materials due to their ceramic nature. Hence, currently applied cement formulations are only indicated for non-load bearing application sites. An approach to reduce cement brittleness is based on the use of cement - polymer composites, which combine the flexibility of a polymeric phase with the hardness and compression strength of a cement matrix. Here, a relatively new strategy is the use of "dual-setting" cements, in which the polymeric phase is simultaneously build up from monomers or prepolymers during cement setting. This approach largely maintains basic properties of the fresh paste such as rheology or setting time. Previous works on such dual setting cements were dealing with a radical polymerization reaction to create the polymeric network. This type of reaction requires the addition of a suitable initiator system (e.g. a tertiary amine in conjunction with ammonium peroxosulfate), which are often cytotoxic and may interfere with the cement setting conditions. The current thesis dealt with alternative strategies, in which the cross-linking and gelation of the second (polymeric or inorganic) cement phase is initiated by the chemical conditions of the setting reaction such that no additional initiator has to be added to the cement paste. In a first approach a six armed star molecule functionalized with isocyanate groups as reactive termini (NCO-sP(EO-stat-PO)) was used to build up a hydrogel matrix, which was then subsequently mineralized with hydroxyapatite nanocrystals following the hydrolysis of incorporated -tricalcium phosphate particles. The stimulus to initiate hydrogel cross-linking are water molecules, which subsequently hydrolyzed isocyanate groups to amines, which then cross-linked with unreacted isocyanate to form urea-bonds. Here, it was possible to show the advantages features of a dual setting system in comparison to the simple combination of hydrogels with unreactive filler particles. By the formation of the cement matrix within the hydrogel a strength improvement by the factor of 30 could be observed. Furthermore, by applying a dual setting system higher mineral concentrations are realizable. The mechanical properties such as elasticity, compression strength and E-modulus of a composite with 30 wt\% NCO-sP(EO-stat-PO) were found to be similar to the properties of cancellous bone. With the motivation to develop a dual setting and resorbable cement, a brushite (CaHPO4·2H2O) forming cement was modified with a second inorganic silica based precursor. The latter was obtained by pre-hydrolysing tetraethyl orthosilicate (TEOS) under acidic conditions. This silica precursor was mixed with a cement powder composed of ß-tricalcium phosphate and monocalcium phosphate, whereas cement setting occurred by a dissolution-precipitation process to form a matrix of brushite. Simultaneously, the increase of the pH during setting from initially 1-2 to values > 4 initiated the condensation reaction of the hydrolysed TEOS. This resulted in an interpenetrating phase composite material in which the micropores of the cement were filled with the nanoporous silica gel. This resulted in a higher density and a compressive strength of 24 MPa, which is approximately 5-10 times higher than the CPC reference at the same powder to liquid ratio. The microporous character of the composites also altered the release of vancomycin as a model drug, whereby in contrast to the quantitative release from the CPC reference, approx. 25 \% of the immobilised drug remained in the composite matrix. It was also observed, that a variation of the TEOS content in the composite enabled a control over cement phase composition to form either brushite, anhydrous monetite or a biphasic mixture of both. Cytocompatibility tests revealed that composites with the highest silicate content showed an increased cell proliferation compared to the silica-free brushite reference. Proliferation was found to be similar to a hydroxyapatite reference with a significant higher activity per cell. Mechanistically, the improved biological response could not be attributed to the released silicate ions, but to a decreased release of phosphate and adsorption of magnesium ions from the cell culture medium. Finally, an investigated dual setting cement system was based on the combination of a brushite forming cement powder with an aqueous silk fibroin solution. Here, changes of both ion concentration and pH during cement setting were shown to build up an interpenetrating fibroin - brushite composite with combined properties of the elastic polymer and the rigid cement. Mechanistically, the low pH of the cement paste (2) as well as the free Ca2+ ions during setting resulted in a conformation change of the dissolved fibroin from random coil to ß-sheet structure. This leads to a rapid gelation and contraction of the fibroin phase with a self-densifying effect on the cement paste. The set composites showed typical ductile fracture behavior under dry testing conditions and a high elasticity under wet conditions with a mechanical strength nearly an order of magnitude higher than the fibroin free cement reference. Cell number and activity against MG63 cells were strongly increased on silk fibroin cement composite surfaces at later time points, which could be again attributed to a decreased ion release and adsorption compared to the fibroin free cements. This in turn slowed down the in vitro degradation of the CPC phase in such composites.},
  subject      = {Calciumphosphate},
  language  = {en}
}