| Preface to the Second Edition | p. xi |
| Preface to the First Edition | p. xiii |
| Introduction | p. 1 |
| The Structure of Bone Tissue | p. 3 |
| Bone at the Molecular Level | p. 4 |
| The Cells of Bone | p. 11 |
| Woven and Lamellar Bone | p. 12 |
| Fibrolamellar and Haversian Bone | p. 14 |
| Primary and Secondary Bone | p. 20 |
| Compact and Cancellous Bone | p. 21 |
| A Summary of Mammalian Bone Structure | p. 24 |
| Nonmammalian Bone | p. 25 |
| The Mechanical Properties of Materials | p. 27 |
| What Is Bone For? | p. 27 |
| Mechanical Properties of Stiff Materials | p. 28 |
| Stress, Strain, and Their Relationship | p. 29 |
| Anisotropy | p. 37 |
| Viscoelasticity | p. 40 |
| Modes of Loading | p. 41 |
| Fracture and Toughness | p. 42 |
| Fracture Mechanics | p. 49 |
| Creep Rupture | p. 51 |
| Fatigue Fracture | p. 51 |
| The Mechanical Properties of Bone | p. 54 |
| Elastic Properties | p. 54 |
| Orientation Effects | p. 55 |
| Strain Rate Effects | p. 57 |
| Strength | p. 58 |
| Orientation Effects | p. 60 |
| Strain Rate Effects | p. 61 |
| Modes of Loading | p. 62 |
| Inferring Bone Material Properties from Whole Bone Behavior | p. 62 |
| Fracture Mechanics Properties | p. 64 |
| Creep Rupture | p. 67 |
| Fatigue Fracture | p. 69 |
| Modeling and Explaining Elastic Behavior | p. 74 |
| Modeling Fracture in Tension | p. 82 |
| The Effects of Stress Concentrations | p. 82 |
| The Effects of Remodeling | p. 86 |
| Anisotropy in Fracture | p. 88 |
| Fracture of Bone in Compression | p. 91 |
| Fracture of Bone in Bending | p. 93 |
| Mechanical Properties of Haversian Systems | p. 99 |
| Cancellous Bone | p. 104 |
| Bone as a Composite | p. 104 |
| Microdamage | p. 110 |
| Microcracking Phenomena | p. 110 |
| The Mechanical Effects of Microcracking | p. 112 |
| Strain Rate, Creep, and Fatigue: Pulling the Threads Together | p. 117 |
| Fracture in Bone: Conclusions | p. 122 |
| The Adaptation of Mechanical Properties to Different Functions | p. 124 |
| Properties of Bone with Different Functions | p. 124 |
| A General Survey of Properties | p. 129 |
| Mesoplodon Rostrum: A Puzzle | p. 137 |
| Property Changes in Ontogeny | p. 138 |
| Cancellous Bone | p. 146 |
| Mechanical Properties of Cancellous Bone Material | p. 146 |
| Mechanical Properties of Cancellous Bone Tissue | p. 150 |
| Functions of Cancellous Bone | p. 158 |
| Principal Stresses | p. 159 |
| Arrangement of Trabeculae in Cancellous Bone | p. 162 |
| Joins Between Trabeculae | p. 167 |
| Energy Absorption of Cancellous bone | p. 168 |
| Cancellous Bone in Sandwiches and in Short Bones | p. 170 |
| Cancellous Bone in Tuberosities | p. 170 |
| Medullary Bone | p. 170 |
| The Size of Trabeculae | p. 171 |
| Cancellous Bone with No Compact Bone | p. 172 |
| Conclusion | p. 173 |
| The Properties of Allied Tissues | p. 174 |
| Calcified Cartilage | p. 174 |
| Collagenous Tissues of Teeth | p. 176 |
| Cement | p. 176 |
| Dentin | p. 177 |
| Narwhal Dentin | p. 180 |
| Enamel | p. 183 |
| Fish Scales | p. 191 |
| Dentin vs. Bone | p. 191 |
| The Shapes of Bones | p. 194 |
| Shapes of Whole Bones | p. 194 |
| Designing for Minimum Mass | p. 196 |
| Long Bones | p. 197 |
| Why Are Long Bones Hollow? | p. 197 |
| How Hollow Should Bones Be? | p. 199 |
| How Stiff Should Bones Be? | p. 210 |
| Flat or Short Bones with Cancellous Bone | p. 212 |
| Sandwich Bones | p. 212 |
| Short Bones | p. 217 |
| Synergy Between Cortical and Cancellous Bone | p. 219 |
| Paying for Strength with Mass | p. 220 |
| Minimum Mass of Compact Bone Material | p. 220 |
| Minimum Mass of Cancellous Bone | p. 224 |
| The Swollen Ends of Long Bones | p. 225 |
| Euler Buckling | p. 231 |
| Interactions Between Bone Architecture and Bone Material Properties | p. 236 |
| The Mechanical Importance of Marrow Fat | p. 239 |
| Methods of Analyzing Stresses and Strains in Whole Bones | p. 241 |
| Conclusion | p. 243 |
| Articulations | p. 245 |
| The Synovial Joint | p. 247 |
| The Elbow | p. 248 |
| The Swelling of Bones Under Synovial Joints | p. 254 |
| Intervertebral Disks | p. 261 |
| Sutures | p. 262 |
| Epiphyseal Plates | p. 263 |
| Joints in General | p. 268 |
| Conclusion | p. 271 |
| Bones, Tendons, and Muscles | p. 272 |
| Tendons | p. 273 |
| Sesamoids and Ossified Tendons | p. 277 |
| Attachment of Tendons to Bone | p. 280 |
| Muscles Produce Bending Stresses in Bones | p. 283 |
| Why Do Tendons Run Close to Joints? | p. 285 |
| Muscles as Stabilizing Devices | p. 294 |
| Curvature of Long Bones and Pauwels' Analyses | p. 294 |
| Skeletons in General | p. 299 |
| Pelvic and Pectoral Girdles | p. 300 |
| Limbs | p. 301 |
| Fusion and Loss of Bones | p. 302 |
| The Vertebral Column | p. 304 |
| The Skull | p. 307 |
| Conclusion | p. 307 |
| Safety Factors and Scaling Effects in Bones | p. 309 |
| Safety Factors | p. 309 |
| Size and Shape | p. 327 |
| Scaling | p. 327 |
| Elastic Similarity | p. 329 |
| Geometric Similarity | p. 331 |
| Conclusion | p. 336 |
| Modeling and Reconstruction | p. 337 |
| The Need for Feedback Control | p. 337 |
| What Do We Need to Know? | p. 341 |
| Classic Experiments | p. 343 |
| The Nature of the Signal | p. 345 |
| Electrical Effects | p. 345 |
| Direct Measurement of Strain | p. 349 |
| How Does Bone Respond to the Signal? | p. 350 |
| Postclassical Experiments | p. 354 |
| In Search of the Algorithm | p. 357 |
| Precision of Response | p. 364 |
| Modeling of Cancellous Bone | p. 367 |
| The Functions of Internal Remodeling | p. 368 |
| Removing Dead Bone | p. 369 |
| Improving the Blood Supply | p. 370 |
| Mineral Homeostasis | p. 371 |
| Changing the Grain | p. 372 |
| Taking out Microcracks | p. 374 |
| It's a Pathological Mistake | p. 377 |
| Bone Cell Biology | p. 378 |
| Conclusion | p. 378 |
| Summing up | p. 380 |
| References | p. 381 |
| Index | p. 425 |
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