Biomechanical Evaluation of Promising Different Bone Substitutes in a Clinically Relevant Test Set-Up

Brueckner, Theresa; Heilig, Philipp; Jordan, Martin; Paul, Mila M.; Blunk, Torsten; Meffert, Rainer H.; Gbureck, Uwe; Hoelscher-Doht, Stefanie

doi:10.3390/ma12091364

Cited by 19 publications

(29 citation statements)

References 46 publications

(88 reference statements)

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“…Twenty-seven synthetic bone specimens of the right calcaneus (LD 9118; Synbone, Zizers, Switzerland) were used in this study. Previous studies have proven that the biomechanical properties are similar between synthetic bone and human specimens, and our pre-tests confirmed these findings [10]. A four-part fracture (Sanders type IIA) was generated using an oscillating saw by a technique that has been proven reproducible in other studies [11].…”

Section: Specimens and Fracture Generationsupporting

confidence: 79%

“…Self-setting CP cements form an osteoconductive, degradable bone cement by a dissolution-reprecipitation process [15]. The Graftys® used in this study sets under a pH of > 4.2 and produces a slowly degrading hydroxyapatite, mimicking the composition and crystallinity of the inorganic phase of the bone matrix [10]. The mean compressive strength of Graftys® was 19.0 ± 2.5 MPa in our previous tests (manufacturer information: 24 MPa after 24 h) [10].…”

Section: Discussionmentioning

confidence: 88%

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Cement-augmented screw fixation for calcaneal fracture treatment: a biomechanical study comparing two injectable bone substitutes

et al. 2020

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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® QuickSet; Graftys, Aix-en-Provence, France), and the third group with screws and PMMA-based cement (Traumacem™ 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.

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Section: Specimens and Fracture Generationsupporting

confidence: 79%

Section: Discussionmentioning

confidence: 88%

Cement-augmented screw fixation for calcaneal fracture treatment: a biomechanical study comparing two injectable bone substitutes

et al. 2020

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“…Magnesium substitution in CaP cements as well as pure MPC has captured increasing attention in bone graft research during the last few years [8]. This material group exhibits several features which are relevant for the application in clinical situations.…”

Section: Discussionmentioning

confidence: 99%

“…The amount of the latter was equal to the amount in a powder-liquid-approach using 3.5 M (NH 4 ) 2 HPO 4 solution and a powder to liquid ratio of 3 to 1. Prefabricated cement pastes were then obtained by mixing the powder components with an oil-surfactant mixture in the ratio of 5.25:1 as described elsewhere [8]. During the individual experiments the CaMgP cement pastes were applied using a 4:1 double chamber cartridge system (Medmix, Risch-Rotkreuz, Switzerland) with a connected static mixer.…”

Section: Methodsmentioning

confidence: 99%

“…This behavior was proofed in a number of animal studies with models ranging from small defects in rabbits [5,6] up to partial load-bearing tibial defects in sheep [7]. Additionally, magnesium phosphate cements (MPC) turned out to show very good biomechanical features, which are even better than clinically well-established calcium phosphate bone fillers [8]. Since most of the implanted magnesium phosphate minerals are hydrated species, their processing and in vivo application usually follows a cementitious route, in which the starting minerals are mixed with an aqueous solution to form a paste.…”

Section: Introductionmentioning

confidence: 97%

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Development and Bone Regeneration Capacity of Premixed Magnesium Phosphate Cement Pastes

et al. 2019

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Magnesium phosphate cements (MPC) have been demonstrated to have a superior bone regeneration capacity due to their good solubility under in vivo conditions. While in the past only aqueous MPC pastes have been applied, the current study describes the fabrication and in vitro/in vivo testing of an oil-based calcium doped magnesium phosphate (CaMgP) cement paste. Premixed oil-based pastes with CaMgP chemistry combine the advantages of conventional MPC such as high mechanical strength and good resorbability with a prolonged shelf-life and an easier clinical handling. The pastes set in an aqueous environment and predominantly form struvite and achieve a compressive strength of ~8–10 MPa after setting. The implantation into a drill-hole defect at the distal femoral condyle of New Zealand white rabbits over a course of 6 and 12 weeks demonstrated good biocompatibility of the materials without the formation of soft connective tissue or any signs of inflammation. In contrast to a hydroxyapatite forming reference paste, the premixed CaMgP pastes showed subsequent degradation and bony regeneration. The CaMgP cement pastes presented herein are promising bone replacement materials with excellent material properties for an improved and facilitated clinical application.

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Combining 3D Printing and Cryostructuring to Tackle Infection and Spine Fusion

Fischetti,

Graziani,

Ghezzi

et al. 2024

Adv Materials Technologies

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Low back pain is among the main issues in vertebral orthopaedics. Intervertebral disk degeneration can be severe, up to requiring the replacement of the damaged disk by substitutes to achieve spine fusion. Disk removal results in critical size defects, so fusion does not occur naturally, but synthetic bone grafts are needed. Since the surgical procedure is time‐consuming, high infection rates occur. Hence, in spine fusion, bone regeneration enhancement and infection prevention are needed. Here, a new dual‐component system is proposed, to tackle both issues at one time. To enable spine fusion, 3D extrusion‐based printing is employed to develop coherent custom magnesium phosphate (CaMgP)‐based cages. The 3D‐printed scaffolds are hardened, and the structural properties are evaluated to be within the ranges of physiological bone. To prevent infection, an in‐house ice‐templating device is employed in combination with a 3D‐printed ceramic scaffold, to develop tailored porous alginate structures loaded with vancomycin. Results show that CaMgP can be printed into complex geometries and that the geometry influences the pore orientation during ice‐templating. These structures loaded with vancomycin have antibacterial properties against Escherichia coli (E. coli) and Staphylococcus aureus (S. aureus) strains.

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Biomechanical Evaluation of Promising Different Bone Substitutes in a Clinically Relevant Test Set-Up

Cited by 19 publications

References 46 publications

Cement-augmented screw fixation for calcaneal fracture treatment: a biomechanical study comparing two injectable bone substitutes

Cement-augmented screw fixation for calcaneal fracture treatment: a biomechanical study comparing two injectable bone substitutes

Development and Bone Regeneration Capacity of Premixed Magnesium Phosphate Cement Pastes

Combining 3D Printing and Cryostructuring to Tackle Infection and Spine Fusion

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