Skeletal System Microanatomy PDF

Summary

This document provides information on the skeletal system. It covers various topics including the classification of bones, bone structure, and the different functions of bone, and highlights the major steps in bone fractures. It also touches on bone development and growth, and the remodeling and repair of bones, and contains diagrams and descriptions of the different parts of bone. It is likely a useful resource for students studying human anatomy and physiology.

Full Transcript

Hole’s Essentials of Human Anatomy & Physiology

Unit 5: Chapter 7
Skeletal System
What are the functions of the
skeletal system?
Functions of Bone Tissue
∙ Support of the body tissues
∙ Legs & pelvis support body’s weight
∙ Atlas supports the skull
∙ Protection of underlying organs
∙ Skull – protects the brain, eyes, ears
∙ Rib cage & shoulder girdle – protects heart and lungs
∙ Pelvic girdle – protects lower abdominal organs and internal
reproductive organs
∙ Movement
∙ Skeletal muscles attached to bones by tendons serve to move bones
∙ Muscles use bones to work in opposition to cause movement
Functions of Bone Tissue
∙ Mineral Homeostasis
∙ Bones store many minerals including:
∙ Calcium salts, mainly calcium phosphate
∙ Magnesium, sodium, potassium, carbonate ions
∙ Harmful minerals stored:
∙ Lead, radium, strontium
∙ Energy storage
∙ Yellow marrow in the shaft of long bones
∙ Serves as an important chemical energy storage (fat)
∙ Can convert back to red marrow if blood cells are needed and revert
back to yellow marrow when there is a blood cell surplus
Functions of Bone Tissue
∙ Hematopoiesis
∙ Blood cell formation
∙ All blood cells are formed in the red marrow of certain bones
∙ Children: mostly in medullary cavities of long bones
∙ Adults: spongy bones of skull, ribs, sternum, clavicles, vertebrae,
hip bones
Classification of Bones
Bones are classified according to their shape (4)
 Classification of Bones
∙ Long bones
∙ Typically longer than wide
∙ Have a shaft with heads at both ends
∙ Contain mostly compact bone
∙ Examples:
∙ Femur (thigh bone),
∙ humerus (arm bone),
∙ all the bones of the limbs (except
wrist and ankle)
Classification of Bones
∙ Short bones
∙ Generally cube-shape
∙ Contain mostly spongy bone
∙ Examples: Carpals (wrist), tarsals (ankle)
Classification of Bones
∙ Flat bones
∙ Thin layers of compact bone
around a layer of spongy bone
∙ Usually curved
∙ Examples: Skull, ribs,
sternum (breastbone),
scapula (shoulder blade)
Classification of Bones
∙ Irregular bones
∙ Irregular shape
∙ Do not fit into other bone
classification categories
∙ Example: Vertebrae, hip,
auditory ossicles
 Classification of Bones
Sesamoid Bone
– Round shape
– Embedded within tendons adjacent to joints
Example: patella
Bone Structure – Gross Anatomy
∙ Diaphysis = shaft
∙ Consists of a central medullary cavity filled
with marrow
∙ Surrounded by a thick collar of compact
bone
∙ Epiphyses = expanded ends
∙ 1-proximal & 1-distal
∙ Consists mainly of spongy bone
∙ Surrounded by thin layer of compact bone
∙ Epiphyseal plate =
∙ area of hyaline (articular) cartilage causing
lengthwise growth of a long bone at
junction of epiphyses and diaphysis
∙ Epiphyseal line =
∙ remnant of epiphyseal plate
Epiphyseal line vs Epiphyseal plate
Bone Structure – Gross Anatomy
∙ Periosteum
= Tough, outer dense white fibrous connective tissue protective covering
of the diaphysis
∙Richly supplied with blood vessels, nerves
∙Serves as an osteogenic layer contains osteoblasts & osteoclasts, cells
that form and repair bone tissue
∙Serves as an insertion for tendons and ligaments

∙ Endosteum
= Thin, inner lining of the medullary cavity
∙Contains osteoblast & osteoclast cells

∙ Medullary cavity
= Hollowed central region
∙Houses marrow
Bone Structure – Gross Anatomy
∙ Articular cartilage
= Pad of hyaline cartilage covering the external
surface of the epiphyses
∙Decreases surface friction
∙Osteoarthritis – thinning of articular cartilage

∙ Sharpey’s fibers
= Secures periosteum to underlying bone

∙ Nutrient arteries
∙Supply bone cells with nutrients
∙Enter bone thru nutrient foramen
in compact bone
 4.
5.
1.
6.

7.
2.

8.

9.

10.

3.
Classification of Bones
∙ Bones are classified according to their types (2)
∙ Compact bone
∙ homogeneous, mainly in long bones
∙ continuous extracellular matrix w/o space
∙ dense, concentric circles of osseous tissue
∙ site of red blood cell formation in children
∙ Spongy bone
∙ heterogeneous, mainly in short bones
∙ small needle-like pieces of bone
∙ many open spaces
∙ site of red blood cell formation in adults
∙ lightens bone
Histology of Compact Bone – Micro Anatomy
∙ Osteon (Haversian System)
∙ Structural unit of bone
∙ Elongated cylinders cemented together
to form the long axis of bone
∙ Components of an osteon:
∙ Osteocytes – spider shaped bone cells
∙ Lacunae – chambers/cavities containing
osteocytes
∙ Lamellae – concentric matrix of collagen and
calcium salts
∙ Central canal (Haversian canal) – center of
osteon containing blood vessels and nerves
∙ Communicating canals within compact bone
∙ Canaliculi – connect the lacunae together
∙ Volkman canals (Perforating canals) – connect
blood vessels and nerve supply of adjacent
central canals together
∙ Perpendicular to the central canal
Histology of Compact Bone – Micro Anatomy

https://www.youtube.com/watch?v=rZy_GMWV87g – histology video (dry)
https://www.youtube.com/watch?v=inqWoakkiTc – bone biology
Histology of Spongy Bone – Micro Anatomy
∙ Consist of poorly organized trabeculae
∙ Trabeculae are small needle-like pieces of bone
∙ Open space exists between trabeculae
∙ Nourished by diffusion from nearby central canals
Histology of Bone
∙ Organic component (35%) – CELLS
∙ Osteoprogenitor cells: -- Derived from mesenchyme (a loosely organized,
mainly mesodermal embryonic tissue that develops into connective and skeletal tissues, including blood and
lymph); Can undergo mitosis and become osteoblasts
∙ Osteoblasts -- Form bone matrix by secreting collagen; Cannot
undergo mitosis BUILDERS!!!
∙ Osteocytes -- Mature bone cells derived from osteoblasts; Principle
bone cell; Cannot undergo mitosis; Maintain daily cellular activities
∙ Osteoclasts -- Function in bone reabsorption (destroy and clear
away bone matrix; Important in development, growth, maintenance
and repair of bone
∙ Osteoid -- Primarily collagen, which give bone its tensile strength and
flexibility
∙ Inorganic component (65%) – MINERAL SALTS
∙ Hydroxyapatite, which is primarily calcium phosphate, gives bone its
hardness and compression strength

∙ https://www.youtube.com/watch?v=78RBpWSOl08 – osteoblasts and osteoclasts
Skeletal system microanatomy
Whaddya know?
1. What is the process of red blood cell formation?

2. What is the hormone, released by the kidney’s, that stimulates red
blood cell formation?

3. What type of marrow produces blood cells?

4. Where is that marrow found in children? Adults?

5. What are the two types of bone?

6. What are the four shapes of bone? And give an example of each.

7. What is the inorganic compound that makes up bone?

1. What is the process of red blood cell formation?
hematopoiesis
2. What is the hormone, released by the kidney’s, that stimulates red
blood cell formation?
erythropoietin
3. What type of marrow produces blood cells?
red marrow
4. Where is that marrow found in children? Adults?
Medullary cavity; spongy bone
5. What are the two types of bone?
Spongy; compact
6. What are the four shapes of bone? And give an example of each.
Short 🡪 carpals, tarsals, patella
Long 🡪 humerus, femur, radius, ulna, tibia, fibula, metacarpals,
metatarsals, phalanges
Flat 🡪 ribs, sternum, cranial and facial bones
Irregular 🡪 hip bones, vertebra
7. What is the inorganic compound that makes up bone?
Hydroxyapatite
8

15
9

10

11

16
12

13
14
Articular cartilage
8

Epiphyseal
15 plate
9
Epiphysis

Spongy 10
bone

Compact bone
11

Diaphysis
Medullary 16
12 cavity

Periosteum
13
Endosteum
14
 17

18
19

20
 Compact bone
17
Spongy bone
18 Periosteum
19

Haversian Canal
20
Lacunae

Haversian
canal

Canaliculi
Lamella
https://www.youtube.com/watch?v=nwrykH3Nhtg
Bone Fractures

∙ Fracture = A break in a bone

∙ Types of bone fractures
∙ Closed (simple) fracture – break that does not penetrate the skin healing
time 6-8 weeks (longer for large bones and elderly)
∙ Open (compound) fracture – broken bone penetrates through the skin

∙ Bone fractures are treated by reduction and immobilization
∙ Reduction – realignment of the bone
∙ Closed reduction:
∙ bones are reset into normal position
∙ Open reduction:
∙ surgery secures bones with pins,wires
Bone Fractures

∙ Classification by cause - Traumatic, spontaneous, pathologic
∙ Classification by nature of break
∙ Greenstick – Incomplete fracture; splintered fracture common in children
∙ Spiral – complete fracture; caused by excessive twisting of bone
∙ Comminuted – complete fracture; fragments the bone
∙ Transverse – complete fracture; at right angle to axis of bone
∙ Fissured – Incomplete fracture; incomplete longitudinal break
∙ Oblique – complete fracture; fracture at some other angle, not right angle
 Major Steps in Repair of Bone Fractures
∙ 1. Hematoma is formed
∙ 2. Break is splinted by fibrocartilage to form a callus
∙ 3. Fibrocartilage callus is replaced by a bony callus
∙ 4. Bony callus is remodeled to form a permanent patch
Major Steps in Repair of Bone Fractures

∙ 1. Hematoma (blood clot) is formed
∙ Broken bone ruptures blood vessels
∙ Blood escapes and forms a hematoma around break
∙ Periosteum tears
∙ Blood vessels in surrounding tissues dilate
∙ Tissues swell and inflammation occurs
 Major Steps in Repair of Bone Fractures
∙ 2. Break is splinted by fibrocartilage to form a callus
∙ Granulation tissue develops
∙ Fibroblasts produce fibrocartilage
∙ Fibrocartilage fills gap between ends of the broken bone
far from blood vessels
∙ Osteoblasts from periosteum invade hematoma
∙ Osteoblasts form spongy bone near
blood vessels
∙ Phagocytes remove blood clot
∙ Osteoclasts reabsorb bone fragments
∙ ***which bony pieces??
 Major Steps in Repair of Bone Fractures
∙ 3. Fibrocartilage callus is replaced by a bony callus
∙ Cartilage callus breaks down
∙ Bony callus fills space

∙ 4. Bony callus is remodeled to form a permanent patch
∙ Osteoclasts remove excess bony tissue
∙ More bone is produced at site of healing fracture than needed
1. What type of fracture is found only in youth, with an incomplete fracture of
bone?
greenstick
2. What type of fracture involves the bone erupting through the skin?
Compound or open
3. What term describes the medical fixing of a simple fracture
Closed reduction
4. What type of fracture involves the bone breaking into multiple pieces?
comminuted
5. What are the four major steps in bone repair after a fracture?
Hematoma formation
Fibrocartilage callus formation
Bony callus formation
Remodeling to form a permanent patch
6. What type of cell makes new bone? Breaks down bone? Forms collagen?
Osteoblast; osteoclast; osteoid
7. What is the inorganic component of bone?
Hydroxyapatite
8. How long does it take to heal a typical fracture? (not long bones or the elderly)
6-8 weeks
Bone Development
∙ The skeleton of an embryo is composed of hyaline cartilage CT
loosely shaped like bones.
∙ This skeleton provides supporting structures for ossification to
begin.
∙ At about 6-7 weeks gestation, ossification begins and
continues throughout life.
∙ Ossification follows one of two patterns:
∙ Intramembranous Ossification: flat bones originate between
sheetlike layers of connective tissue
∙ Endochondral Ossification: bones begin as hyaline cartilage
masses that are replaced by bone tissue
∙ Most bones of the skeleton are formed in this manner.
∙ Cartilage remains in isolated areas
∙ Bridge of the nose, parts of ribs, and joints
∙ Articular cartilage cover ends of bone; persist for life
∙ Epiphyseal plates in ends of long bones
 Bone Development
∙In long bones:
∙Cartilage begins calcification in diaphyses center
∙At the primary ossification center
∙Epiphyses remain cartilagenous at first and continue to grow
∙Secondary ossification centers appear in each epiphysis
∙The Epiphyseal plate remains between the two ossification centers
Bone Growth (longitudinal growth)
∙ During infancy and childhood, long bones lengthen entirely by growth at
the epiphyseal plates
∙ Epiphyseal plates allow for bone lengthening until adulthood
∙ As a child grows,
∙ 1. cartilage cells are produced by mitosis on the epiphyseal side of
the plate (#3 in picture)
∙ 2. cartilage cells are destroyed and replaced by bone on the
diaphyseal side of the plate (#4)
∙ 3. The bone on the diaphyseal side increases in length but the
thickness of the plate remains relatively constant

NOTE: New cartilage is also
generated at the external
ends of articular cartilage (#1)
and destroyed at the internal
ends of articular cartilage (#2)
Bone Growth (appositional growth)
∙ During infancy and childhood, long bones thicken (increase in
diameter) by appositional growth.
∙ a. Occurs in osteogenic layer of periosteum
∙ b. Osteoblasts lay down matrix of compact bone on the outer
surface
∙ c. Osteoclasts destroy the bone matrix at the endosteal surface
∙ Thickness of the bone remains relatively constant
Bone Remodeling and Repair
Bone Growth
∙ The rate of bone growth is controlled by:
∙ a. hGH
∙ b. Sex hormones
∙ Ossification of most bones is completed by age 25.
∙ Growth ceases when primary and secondary ossification
centers meet
Bone Remodeling and Repair
∙ Once a bone has been formed, it is continuously remodeled
throughout life.
∙ This process involves the action of osteoblasts and osteoclasts
and 2 hormones (calcitonin & parathyroid hormone).
∙ Bones are remodeled through the actions of osteoclasts and
osteoblasts
∙ Blood calcium homeostasis is affected

∙ A. Rate of Remodeling Varies
∙ 1. every 4 months – femur
∙ 2. may take a lifetime for diaphyses to be replaced
∙ B. Osteoclasts are large multinucleate cells responsible for
bone reabsorption
∙ 1. secrete lysosomal enzymes to digest organic matrix
∙ 2. secrete acids that solubilize calcium salts that enter
blood as ions
 Bone Remodeling and Repair
∙ Control of Bone Remodeling/Calcium Homeostasis involves 2 hormones,
and is a negative feedback mechanism

∙ Parathyroid hormone (PTH) is secreted by parathyroid glands when
blood calcium levels are low:
∙ a. Stimulates osteoclast activity (breaks down bone/reabsorption of
bone), releasing Ca2+ into the blood
∙ b. Kidney tubules reabsorb Ca2+ back into the blood
∙ c. Resulting in an increase in blood calcium levels (back to normal)

∙ Calcitonin is secreted by the thyroid gland when blood calcium levels
are high:
∙ a. Inhibits bone reabsorption, increases osteoblast activity (bony
matrix building/deposition of bony matrix)
∙ b. Kidney tubules secrete excess Ca2+ into the urine
∙ c. Resulting in a decrease in blood calcium levels (back to normal)
 Add the following to the picture
to the left:
4 1.Parathyroid gland
2
2.Thyroid gland
3.Parathyroid hormone
4.Calcitonin
8 5.Stimulates osteoblasts (to
5
deposit calcium in bones)
6.Stimulates osteoclasts (to
remove calcium from bones)
10 7.Increases calcium uptake in
Kidneys
8.Decreases calcium uptake in
Kidneys
9.Increases calcium uptake in
small intestine
9 10.Decreases calcium uptake in
small intestine

6 7
1
3
Bone Remodeling and Repair
∙ Minerals needed for bone remodeling:
∙ Calcium – component of hydroxyapatite
∙ Phosphorus – component of hydroxyapatite
∙ Magnesium – needed for osteoblast activity
∙ Boron – inhibits calcium loss
∙ Manganese – needed for development of new matrix

∙ Vitamins needed for bone growth, remodeling, repair:
∙ Vitamin D – greatly increases intestinal absorption of dietary calcium
and slows its urine loss
∙ Deficiency causes rickets in children and osteomalacia in adults
∙ Vitamin C – helps maintain bone matrix (collagen synthesis)
∙ Deficiency causes scurvy
∙ Vitamin A – required for bone reabsorption, controls the activity,
distribution and coordination of osteoblasts & osteoclasts during
development
∙ Vitamin B12 – plays a role in osteoblast activity
Bone Remodeling and Repair
∙ Hormones needed for bone growth and remodeling:
∙ human Growth Hormone (hGH)
∙ Secreted by the pituitary gland
∙ Responsible for general growth of all tissues
∙ Stimulates reproduction of cartilage cells at epiphyseal plate
∙ (Acromegaly – picture next slide)
∙ Sex hormones
∙ Estrogen and Androgens (testosterone)
∙ Aid osteoblast activity to promote new bone growth
∙ Degenerates cartilage cells in epiphyseal plate (closes the plate)
∙ Estrogen effect is greater than androgen (testosterone) effect,
though synergistic in males
∙ Thyroid hormones T3 and T4
∙ T3 = triiodothreonine
∙ T4 = thyroxine
∙ stimulates replacement of cartilage by bone in plate
∙ PTH & Calcitonin – already discussed
Bone Remodeling and Repair
∙ Exercise increases bone growth:
∙ In response to the pull of muscles and gravity on bones (where)
∙ Bones become thicker as more osteocytes are made because of the
stress placed on the bone
∙ 3-5% bone calcium exchange/year
∙ https://vimeo.com/62985496

Acromegaly is a rare
disorder in which the
anterior pituitary
gland produces too
much human growth
hormone. This
causes an increased
growth in bone and
soft tissue.