Bio-inspired structured composites for load-bearing bone graft substitution

Galea, Laetitia

21 May 2015

Natural composites, in particular nacre, often combine high strength and toughness thanks to highly ordered architectures and controlled geometries of the reinforcement components. However, combining strength, toughness and resorbability in synthetic materials remains a challenge in particular in the field of bone graft substitutes. In the present study, calcium phosphate-(CaP-)based materials with designed architectures inspired from natural composite materials were achieved. CaP platelets obtained by precipitation in organic medium were first aligned in chitosan matrices by solvent casting in ambient conditions. Efficient strengthening was obtained with 15 vol-% ceramic, reaching cortical bone strength (150 MPa) and preserving good ductility (5 % deformation). In a weak magnetic field, high spatial arrangement without percolation was maintained up to 20 vol-%. With directional freezing, good alignment of the platelets could be pushed up to 50 vol-%. In parallel, in situ recrystallization of CaP blocks in hydrothermal conditions led to hierarchical structures. The strength and the work-of-fracture were enhanced (300%) thanks to a change of failure mode.

bio-inspirierte Komposite

Kalziumphosphat

Knochenersatzmaterialien

lasttragende

bio-inspired composites

calcium phosphate

bone graft substitutes

load-bearing

ddc:620

Verbundwerkstoff

Calciumphosphate

Biomaterial

Knochenzement

Traglast

Bio-inspired structured composites for load-bearing bone graft substitution

Galea, Laetitia

03 March 2015

Natural composites, in particular nacre, often combine high strength and toughness thanks to highly ordered architectures and controlled geometries of the reinforcement components. However, combining strength, toughness and resorbability in synthetic materials remains a challenge in particular in the field of bone graft substitutes. In the present study, calcium phosphate-(CaP-)based materials with designed architectures inspired from natural composite materials were achieved. CaP platelets obtained by precipitation in organic medium were first aligned in chitosan matrices by solvent casting in ambient conditions. Efficient strengthening was obtained with 15 vol-% ceramic, reaching cortical bone strength (150 MPa) and preserving good ductility (5 % deformation). In a weak magnetic field, high spatial arrangement without percolation was maintained up to 20 vol-%. With directional freezing, good alignment of the platelets could be pushed up to 50 vol-%. In parallel, in situ recrystallization of CaP blocks in hydrothermal conditions led to hierarchical structures. The strength and the work-of-fracture were enhanced (300%) thanks to a change of failure mode.:Acknowledgements v Summary vii Background vii Thesis outline viii Part I: “Brick-and-mortar” structures with discrete reinforcement components ix Part II: “Textured” structures with continuous reinforcement components x Zusammenfassung xi Hintergrund xi Doktorarbeit Gliederung xii Teil I: “Ziegelmauer-Architektur” mit diskreten Verstärkungskomponenten xiii Teil II: “ Texturierte” Strukturen mit kontinuierlichen Verstärkungskomponenten xiv Chapter 1: General introduction 1 Bone grafting 1 CaP ceramics 1 How to improve toughness of CaP ceramics? 2 Importance of structure design: bio-inspiration 2 What mechanical properties should be reached? 5 Specific aims 5 Two general approaches to reach the goal 6 Nacre-inspired “brick-and mortar” structures (Part I) 6 Textured ceramic monoliths (Part II) 6 References 7 Chapter 2: Theoretical calculations 11 Introduction 12 Theoretical tensile strength of β-TCP platelets and critical size for flaw tolerance 13 Optimal aspect ratio 15 Composite strength and stiffness 17 Limitations 19 References 19 PART I: NACRE-INSPIRED “BRICK-AND-MORTAR” STRUCTURES Chapter 3: Synthesis of sub-micrometer calcium phosphate platelets 23 Introduction 24 ii Materials and Methods 25 Precipitation method 25 Reaction parameters 25 Characterization 26 Statistical analysis of results 28 Results 28 Reproducibility of standard experiments 28 Increase of the reagent volume to increase the productivity 30 Increase of the precursors concentration to increase the productivity and modify the particles 30 Increase of titration rate to simplify the process 32 Influence of temperature on the particles 35 Effect of the pH value on the particles 37 Effect of a longer reaction time on the particle stability 40 Study of the influence of variations of the Ca/P molar ratio 42 Discussion 43 Reproducibility 43 Productivity 44 CaP crystal shape 45 Crystal purity 47 Aspect ratio 48 Critical thickness 49 Uniformity of primary particles 50 Non agglomerated 51 General points 52 Conclusions 52 References 53 Chapter 4: Kinetics study of the calcium phosphate platelets growth 57 Introduction 58 Theory 58 Materials and methods 60 Materials and sample preparation 60 Characterization methods 61 Results 62 Visual observations during manipulations 62 SEM observations 62 XRD results 66 Size measurements 68 Kinetics calculations 70 Discussion 74 Nucleation and assembly mechanism 74 Reaction kinetics 76 Control of size and aspect ratio 76 Conclusions 77 References 78 Chapter 5: Structural design of bio-inspired composites by solvent casting 81 Foreword 82 Introduction 82 Experimental section 84 iii Synthesis of resorbable ceramic platelets 84 Solvent casting to prove the reinforcement efficiency of DCP platelets 84 Magnetization of the platelets 85 Maintaining the orientation during drying of an hydrogel matrix 86 Results 87 Synthesis of resorbable ceramic platelets 87 Solvent casting to prove the reinforcement efficiency of CaP platelets 87 Magnetization of the platelets 91 Maintaining the orientation during drying of an hydrogel matrix 93 Discussion 95 Detrimental effect of β-TCP platelets in chitosan 95 Efficient reinforcement with DCP platelets up to a given volume fraction 96 Threshold value for strength improvement 97 Fitting the experimental results with theoretical equations 98 Conclusions 101 References 101 Chapter 6: Biodegradable, strong and tough nacre-inspired structures obtained by freezecasting 105 Introduction 106 Experimental section 108 Synthesis of resorbable ceramic platelets 108 Preliminary freeze-casting tests with β-TCP-based slurries 108 Determination of adequate freeze-casting parameters for hydrogels-CaP slurries 108 Integration of CaP platelets and local planar alignment 109 Attempts to globally align porosity in two directions 109 Densification and consolidation 110 Tensile testing 110 Results 111 Preliminary freeze-casting tests with β-TCP-based slurries 111 Determination of adequate freeze-casting parameters for hydrogels-CaP slurries 112 Integration of CaP platelets and local planar alignment 113 Attempts to globally align porosity in two directions 119 Densification and consolidation 121 Tensile testing 121 Discussion 122 Conclusions 124 References 125 PART II: TEXTURED CERAMIC MONOLITHS Chapter 7: Micro-texturing by recrystallization of calcium phosphate blocks in hydrothermal conditions 127 Introduction 128 Materials and Methods 130 Samples characterization 132 Results 133 Macroscopic observations 133 Microstructural changes (SEM) 133 Crystalline phase conversion (XRD) 139 iv Mechanical properties 142 Fractured surfaces 142 Discussion 145 Conclusions 150 References 150 Chapter 8: Toughening of textured calcium phosphate blocks by polymer impregnation 155 Foreword 156 Introduction 156 Materials and Methods 157 Samples preparation 157 Characterization 158 Results 158 Porosity and microstructure 158 Composition 161 Mechanical properties 161 Discussion 162 Conclusions 164 References 164 Chapter 9: Synthesis and outlook 167 Curriculum Vitae 171

info:eu-repo/classification/ddc/620

ddc:620

Mass Spectrometric Analyses of Post-Translationally Modified Proteins / Massenspektrometrische Analyse post-translational modifizierter Proteine

Hsiao, He-Hsuan

09 August 2010

No description available.

500 Naturwissenschaften

Biology (incl. Psychology)

ChopNSpice

Kalziumphosphat-Präzipitation (CPP)

Glykosylierungen

Massenspektrometrie (MS)

Phosphorylierungen

Pseudo-Neutral-Loss Scan

SUMOylierungen

ChopNSpice

Calcium Phosphate Precipitation (CPP)

Glycosylation

Mass Spectrometry (MS)

Phosphorylation

Post-Translational Modifications (PTMs)

Pseudo-Neutral-Loss Scan

SUMOylation

58.3

WA 320: Spektroskopie {Biologie}

WA 330: Chromatographie {Biologie}

WA 340: Elektrophorese {Biologie}