Biological and mechanical performance of calcium phosphate cements modified with phytic acid.
Valentin C SteinackerJan WeichholdTobias RennerSebastian GubikAndreas VollmerNiko BreitenbücherAndreas FuchsAnton StraubStefan HartmannAlexander C KüblerUwe GbureckPublished in: Journal of materials science. Materials in medicine (2024)
Calcium phosphate cements, primarily brushite cements, require the addition of setting retarders to ensure adequate processing time and processability. So far, citric acid has been the primary setting retarder used in this context. Due to the poor biocompatibility, it is crucial to explore alternative options for better processing. In recent years, the setting retarder phytic acid (IP6) has been increasingly investigated. This study investigates the biological behaviour of calcium phosphate cements with varying concentrations of IP6, in addition to their physical properties. Therefore cytocompatibility in vitro testing was performed using osteoblastic (MG-63) and osteoclastic (RAW 264.7 differentiated with RANKL) cells. We could demonstrate that the physical properties like the compressive strength of specimens formed with IP6 (brushite_IP6_5 = 11.2 MPa) were improved compared to the reference (brushite = 9.8 MPa). In osteoblast and osteoclast assays, IP6 exhibited significantly better cytocompatibility in terms of cell activity and cell number for brushite cements up to 11 times compared to the brushite reference. In contrast, the calcium-deficient hydroxyapatite (CDHA) cements produced similar results for IP6 (CDHA_IP6_0.25 = 27.0 MPa) when compared to their reference (CDHA = 21.2 MPa). Interestingly, lower doses of IP6 were found to be more effective than higher doses with up to 3 times higher. Additionally, IP6 significantly increased degradation in both passive and active resorption. For these reasons, IP6 is emerging as a strong new competitor to established setting retarders such as citric acid. These cements have potential applications in bone augmentation, the stabilisation of non-load bearing fractures (craniofacial), or the cementation of metal implants.
Keyphrases
- physical activity
- single cell
- induced apoptosis
- stem cells
- oxidative stress
- cell therapy
- bone loss
- bone marrow
- high throughput
- risk assessment
- magnetic resonance imaging
- cell proliferation
- body composition
- high resolution
- signaling pathway
- inflammatory response
- postmenopausal women
- bone regeneration
- ultrasound guided
- vascular smooth muscle cells
- contrast enhanced