Physicochemical degradation of calcium magnesium phosphate (stanfieldite) based bone replacement materials and the effect on their cytocompatibility

Schaufler, Christian; Schmitt, Anna-Maria; Moseke, Claus; Stahlhut, Philipp; Geroneit, Isabel; Brückner, Manuel; Meyer-Lindenberg, Andrea; Vorndran, Elke

doi:10.1088/1748-605x/aca735

Cited by 3 publications

(1 citation statement)

References 56 publications

(99 reference statements)

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“…Due to excellent results, the production of the wedges is based on the studies by Kowalewicz et al [23,24]. The 3D powder printing and post-treatment process followed a procedure similar to that of the study by Schaufler et al [32]. By sintering (at 1100 • C for 5 h each) mixtures of calcium hydrogen phosphate (CaHPO 4 , J.T.…”

Section: Production and Characterization Of The Scaffolds 211 Product...mentioning

confidence: 99%

In Vivo Investigation of 3D-Printed Calcium Magnesium Phosphate Wedges in Partial Load Defects

Hemmerlein,

Vorndran,

Schmitt

et al. 2024

Materials

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Bone substitutes are ideally biocompatible, osteoconductive, degradable and defect-specific and provide mechanical stability. Magnesium phosphate cements (MPCs) offer high initial stability and faster degradation compared to the well-researched calcium phosphate cements (CPCs). Calcium magnesium phosphate cements (CMPCs) should combine the properties of both and have so far shown promising results. The present study aimed to investigate and compare the degradation and osseointegration behavior of 3D powder-printed wedges of CMPC and MPC in vivo. The wedges were post-treated with phosphoric acid (CMPC) and diammonium hydrogen phosphate (MPC) and implanted in a partially loaded defect model in the proximal rabbit tibia. The evaluation included clinical, in vivo µ-CT and X-ray examinations, histology, energy dispersive X-ray analysis (EDX) and scanning electron microscopy (SEM) for up to 30 weeks. SEM analysis revealed a zone of unreacted material in the MPC, indicating the need to optimize the manufacturing and post-treatment process. However, all materials showed excellent biocompatibility and mechanical stability. After 24 weeks, they were almost completely degraded. The slower degradation rate of the CMPC corresponded more favorably to the bone growth rate compared to the MPC. Due to the promising results of the CMPC in this study, it should be further investigated, for example in defect models with higher load.

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Section: Production and Characterization Of The Scaffolds 211 Product...mentioning

confidence: 99%

In Vivo Investigation of 3D-Printed Calcium Magnesium Phosphate Wedges in Partial Load Defects

Hemmerlein,

Vorndran,

Schmitt

et al. 2024

Materials

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An injectable porous bioactive magnesium phosphate bone cement foamed with calcium carbonate and citric acid for periodontal bone regeneration

Wang

Zhong-yu

Chen

et al. 2023

Journal of the Mechanical Behavior of Biomedical Materials

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Research progress on the application of magnesium phosphate bone cement in bone defect repair: A review

Tian,

Sun,

et al. 2024

BME

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BACKGROUND: Bone defects arising from diverse causes, such as traffic accidents, contemporary weapon usage, and bone-related disorders, present significant challenges in clinical treatment. Prolonged treatment cycles for bone defects can result in complications, impacting patients’ overall quality of life. Efficient and timely repair of bone defects is thus a critical concern in clinical practice. OBJECTIVE: This study aims to assess the scientific progress and achievements of magnesium phosphate bone cement (MPC) as an artificial bone substitute material. Additionally, the research seeks to explore the future development path and clinical potential of MPC bone cement in addressing challenges associated with bone defects. METHODS: The study comprehensively reviews MPC’s performance, encompassing e.g. mechanical properties, biocompatibility, porosity, adhesion and injectability. Various modifiers are also considered to broaden MPC’s applications in bone tissue engineering, emphasizing drug-loading performance and antibacterial capabilities, which meet clinical diversification requirements. RESULTS: In comparison to alternatives such as autogenous bone transplantation, allograft, polymethyl methacrylate (PMMA), and calcium phosphate cement (CPC), MPC emerges as a promising solution for bone defects. It addresses limitations associated with these alternatives, such as immunological rejection and long-term harm to patients. MPC can control heat release during the curing process, exhibits superior mechanical strength, and has the capacity to stimulate new bone growth. CONCLUSION: MPC stands out as an artificial bone substitute with appropriate mechanical strength, rapid degradation, non-toxicity, and good biocompatibility, facilitating bone repair and regeneration. Modification agents can enhance its clinical versatility. Future research should delve into its mechanical properties and formulations, expanding clinical applications to create higher-performing and more medically valuable alternatives in bone defect repair.

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Physicochemical degradation of calcium magnesium phosphate (stanfieldite) based bone replacement materials and the effect on their cytocompatibility

Cited by 3 publications

References 56 publications

In Vivo Investigation of 3D-Printed Calcium Magnesium Phosphate Wedges in Partial Load Defects

In Vivo Investigation of 3D-Printed Calcium Magnesium Phosphate Wedges in Partial Load Defects

An injectable porous bioactive magnesium phosphate bone cement foamed with calcium carbonate and citric acid for periodontal bone regeneration

Research progress on the application of magnesium phosphate bone cement in bone defect repair: A review

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