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==='''The advantages and disadvantages of stiffness'''===
 
==='''The advantages and disadvantages of stiffness'''===
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[[File:QMFig 2.15.jpg|thumb|'''Fig. 2.15  Ossification of limb bones''']]
    
A major dynamic physical property of the supporting tissues is their energy absorption ability (Fig. 2.2) or stiffness.  The stiffer the material, the less kinetic energy it is able to absorb.  Since bones function as levers, stiffness is a desirable property; the higher the proportion of mineral, the stiffer the bone.  Bone mineral first appears in bones of the developing fetus at sites where stiffness is needed most. This is either for protection, such as in the cranium to protect the brain from external pressure, or to aid correct development, as in the long bones of the limbs, the shape of which is necessary for the correct form of the  muscular system (Fig. 2.15).  The most highly mineralised bones in the body are the aptly named petrous temporal bone and the auditory ossicles, both involved in the detection and interpretation of sound waves.  These bones assist the process of hearing best if they manage to avoid the absorption of the energy of sound waves.  But because of this, they are brittle, and must be protected from other forms of mechanical stress by being enclosed by softer bone.
 
A major dynamic physical property of the supporting tissues is their energy absorption ability (Fig. 2.2) or stiffness.  The stiffer the material, the less kinetic energy it is able to absorb.  Since bones function as levers, stiffness is a desirable property; the higher the proportion of mineral, the stiffer the bone.  Bone mineral first appears in bones of the developing fetus at sites where stiffness is needed most. This is either for protection, such as in the cranium to protect the brain from external pressure, or to aid correct development, as in the long bones of the limbs, the shape of which is necessary for the correct form of the  muscular system (Fig. 2.15).  The most highly mineralised bones in the body are the aptly named petrous temporal bone and the auditory ossicles, both involved in the detection and interpretation of sound waves.  These bones assist the process of hearing best if they manage to avoid the absorption of the energy of sound waves.  But because of this, they are brittle, and must be protected from other forms of mechanical stress by being enclosed by softer bone.
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:::::These views of a sheep fetus at 38 and 44 days after conception have the mineralised bone stained with alizarin. They show which bones and parts of bones need the stiffening properties of hydroxyapatite crystals to ensure normal development, even though limb bones are not needed to support the weight of the animal at this stage.  
 
:::::These views of a sheep fetus at 38 and 44 days after conception have the mineralised bone stained with alizarin. They show which bones and parts of bones need the stiffening properties of hydroxyapatite crystals to ensure normal development, even though limb bones are not needed to support the weight of the animal at this stage.  
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:::::Why are the bones of the skull and thorax relatively well developed?  
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:::::Why are the bones of the skull and thorax relatively well developed?
    
==='''Energy economy – getting the most out of legs'''===
 
==='''Energy economy – getting the most out of legs'''===

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