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Discover the components, functions, and classification of bones in the human skeletal system. Learn about bone tissue types, bone markings, and microscopic anatomy that make up the structure. Explore bone formation and the importance of the skeleton in supporting the body, protecting organs, and enabling movement.
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5 The Skeletal System
The Skeletal System Parts of the skeletal system Bones (skeleton) Joints Cartilages Ligaments (connect two or more bones) Two subdivisions of the skeleton Axial skeleton Appendicular skeleton
Functions of Bones Support the body Protect soft organs Skull and vertebrae for brain and spinal cord Rib cage for thoracic cavity organs Allow movement due to attached skeletal muscles Store minerals and fats Calcium and phosphorus Fat in the internal marrow cavity Blood cell formation (hematopoiesis)
Spongy bone Compact bone Figure 5.1
Bones of the Human Body The adult skeleton has 206 bones Two basic types of bone tissue Compact bone Homogeneous Spongy bone Small needle-like pieces of bone Many open spaces
Classification of Bones on the Basis of Shape Bones are classified as: Long Short Flat Irregular
Classification of Bones Long bones Typically longer than they are wide Shaft with heads situated at both ends Contain mostly compact bone All of the bones of the limbs (except wrist, ankle, and kneecap bones) Example: Femur Humerus
Classification of Bones Short bones Generally cube-shaped Contain mostly spongy bone Includes bones of the wrist and ankle Sesamoid bones are a type of short bone which form within tendons (patella) Example: Carpals Tarsals
Classification of Bones Flat bones Thin, flattened, and usually curved Two thin layers of compact bone surround a layer of spongy bone Example: Skull Ribs Sternum
Spongy bone Compact bone Figure 5.1
Classification of Bones Irregular bones Irregular shape Do not fit into other bone classification categories Example: Vertebrae Hip bones
Anatomy of a Long Bone Diaphysis Shaft Composed of compact bone Epiphysis Ends of the bone Composed mostly of spongy bone
Articular cartilage Proximal epiphysis Spongy bone Epiphyseal line Periosteum Compact bone Medullary cavity (lined by endosteum) Diaphysis Distal epiphysis (a) Figure 5.3a
Anatomy of a Long Bone Periosteum Outside covering of the diaphysis Fibrous connective tissue membrane Perforating (Sharpey’s) fibers Secure periosteum to underlying bone Arteries Supply bone cells with nutrients
Endosteum Yellow bone marrow Compact bone Periosteum Perforating (Sharpey’s) fibers Nutrient arteries (c) Figure 5.3c
Anatomy of a Long Bone Articular cartilage Covers the external surface of the epiphyses Made of hyaline cartilage Decreases friction at joint surfaces
Articular cartilage Compact bone Spongy bone (b) Figure 5.3b
Anatomy of a Long Bone Epiphyseal plate Flat plate of hyaline cartilage seen in young, growing bone Epiphyseal line Remnant of the epiphyseal plate Seen in adult bones
Articular cartilage Proximal epiphysis Spongy bone Epiphyseal line Periosteum Compact bone Medullary cavity (lined by endosteum) Diaphysis Distal epiphysis (a) Figure 5.3a
Anatomy of a Long Bone Marrow (medullary) cavity Cavity inside of the shaft Contains yellow marrow (mostly fat) in adults Contains red marrow for blood cell formation in infants In adults, red marrow is situated in cavities of spongy bone and epiphyses of long bones
Articular cartilage Proximal epiphysis Spongy bone Epiphyseal line Periosteum Compact bone Medullary cavity (lined by endosteum) Diaphysis Distal epiphysis (a) Figure 5.3a
Bone Markings Surface features of bones Sites of attachments for muscles, tendons, and ligaments Passages for nerves and blood vessels Categories of bone markings Projections or processes—grow out from the bone surface Terms often begin with “T” Depressions or cavities—indentations Terms often begin with “F”
Osteon (Haversian system) Lamellae Blood vessel continues into medullary cavity containing marrow Spongy bone Perforating fibers Compact bone Periosteal blood vessel Central (Haversian) canal Periosteum Perforating (Volkmann’s) canal (a) Blood vessel Figure 5.4a
Microscopic Anatomy of Compact Bone Osteon (Haversian system) A unit of bone containing central canal and matrix rings Central (Haversian) canal Opening in the center of an osteon Carries blood vessels and nerves Perforating (Volkmann’s) canal Canal perpendicular to the central canal Carries blood vessels and nerves
Microscopic Anatomy of Bone Lacunae Cavities containing bone cells (osteocytes) Arranged in concentric rings called lamellae Lamellae Rings around the central canal Sites of lacunae
Lamella Osteocyte Canaliculus Lacuna (b) Central (Haversian) canal Figure 5.4b
Osteon Lacuna (c) Central canal Interstitial lamellae Figure 5.4c
Microscopic Anatomy of Bone Canaliculi Tiny canals Radiate from the central canal to lacunae Form a transport system connecting all bone cells to a nutrient supply
Lamella Osteocyte Canaliculus Lacuna (b) Central (Haversian) canal Figure 5.4b
Formation of the Human Skeleton In embryos, the skeleton is primarily hyaline cartilage During development, much of this cartilage is replaced by bone Cartilage remains in isolated areas Bridge of the nose Parts of ribs Joints
Bone Growth (Ossification) Epiphyseal plates allow for lengthwise growth of long bones during childhood New cartilage is continuously formed Older cartilage becomes ossified Cartilage is broken down Enclosed cartilage is digested away, opening up a medullary cavity Bone replaces cartilage through the action of osteoblasts
Bone Growth (Ossification) Bones are remodeled and lengthened until growth stops Bones are remodeled in response to two factors Blood calcium levels Pull of gravity and muscles on the skeleton Bones grow in width (called appositional growth)
Articular cartilage Hyaline cartilage Spongy bone New center of bone growth New bone forming Epiphyseal plate cartilage Growth in bone width Medullary cavity Bone starting to replace cartilage Invading blood vessels Growth in bone length New bone forming Bone collar Hyaline cartilage model Epiphyseal plate cartilage In an embryo In a child In a fetus Figure 5.5
Bone starting to replace cartilage Bone collar Hyaline cartilage model In an embryo Figure 5.5, step 1
Hyaline cartilage New center of bone growth Medullary cavity Invading blood vessels Growth in bone length In a fetus Figure 5.5, step 2
Articular cartilage Spongy bone New bone forming Epiphyseal plate cartilage Growth in bone width Invading blood vessels New bone forming Epiphyseal plate cartilage In a child Figure 5.5, step 3
Bone growth Bone remodeling Growing shaft is remodeled as: Bone grows in length because: Articular cartilage 1 Cartilage grows here. Epiphyseal plate 2 Cartilage is replaced by bone here. 1 Bone is resorbed here. 3 2 Cartilage grows here. Bone is added by appositional growth here. 4 Cartilage is replaced by bone here. 3 Bone is resorbed here. Figure 5.6
Types of Bone Cells Osteocytes—mature bone cells Osteoblasts—bone-forming cells Osteoclasts— bone-destroying cells Break down bone matrix for remodeling and release of calcium into the bloodstream Bone remodeling is performed by both osteoblasts and osteoclasts
Wolff’s Law • States that healthy bone will adapt to the loads under which it is placed. • Stress is detected by osteocytes. • The osteocytes will signal for increased osteoblast activity in these areas.
Wolff’s Law Examples • Tennis players racquet arms are consistently larger and more dense than their non-racquet arms
Wolff’s Law Examples • “Surfer’s Knots” occur from chronic stress usually to top of the foot or knees.
Surfer’s Knots Fun Facts • In the late 60’s people would surf excessively to build up the knots on their feet. • This would prevent them from being able to fit into a standard issue military boot, therefore disqualifying them from the draft for the Vietnam War.
Wolff’s Law Examples • Bones also respond to the lack of stress. • Astronauts typically lose 1-2% of overall bone mass per month spent in space. • Calcium, vitamin D supplements, growth hormones and exercise regiments are all implemented by astronauts to prevent bone loss. • No methods have been found to definitively prevent bone loss during space travel
Astronaut Bone Loss Bone density loss is a real concern NASA is studying as long-term space travel missions are being planned. Maybe you can help resolve this issue..!!...!!
Bone Fractures Fracture—break in a bone Types of bone fractures Closed (simple) fracture—break that does not penetrate the skin Open (compound) fracture—broken bone penetrates through the skin