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Bone formation and development 14
- 1. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Human Anatomy & Physiology, Sixth Edition
Elaine N. Marieb
PowerPoint® Lecture Slides prepared by Vince Austin, University of Kentucky
Bones and Skeletal Tissues
H. Biology II
Adapted 2014-2015
- 2. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
2
INTRODUCTION
Bone is made up of several different tissues working
together: bone, cartilage, dense connective tissue,
epithelium, various blood forming tissues, adipose
tissue, and nervous tissue.
Each individual bone is an organ; the bones, along
with their cartilages, make up the skeletal system.
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3
The Skeletal System: Bone Tissue
Dynamic and ever-changing throughout life
Skeleton composed of many different tissues
cartilage, bone tissue, epithelium, nerve, blood forming tissue, adipose,
and dense connective tissue
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4
Functions of Bone
Supporting & protecting soft tissues
Attachment site for muscles making
movement possible
Storage of the minerals, calcium &
phosphate -- mineral homeostasis
Blood cell production occurs in red bone
marrow (hemopoiesis)
Energy storage in yellow bone marrow
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Importance of Ionic Calcium in the Body
Calcium is necessary for:
Transmission of nerve impulses
Muscle contraction
Blood coagulation
Secretion by glands and nerve cells
Cell division
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6
Anatomy of a Long Bone
diaphysis = shaft
epiphysis = one end of a
long bone
metaphyses are the areas
between the epiphysis and
diaphysis and include the
epiphyseal plate in growing
bones.
Articular cartilage over
joint surfaces acts as
friction reducer & shock
absorber
Medullary cavity = marrow
cavity
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7
Anatomy of a Long Bone
Endosteum = lining of
marrow cavity
Periosteum = tough
membrane covering bone
but not the cartilage
fibrous layer = dense
irregular CT
osteogenic layer = bone
cells & blood vessels
that nourish or help with
repairs
- 8. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
8
Histology of Bone
A type of connective tissue as seen
by widely spaced cells separated by
matrix
Matrix of 25% water, 25% collagen
fibers & 50% crystalized mineral
salts
4 types of cells in bone tissue
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9
HISTOLOGY OF BONE TISSUE
Bone (osseous) tissue consists of widely separated cells
surrounded by large amounts of matrix.
The matrix of bone contains inorganic salts, primarily
hydroxyapatite and some calcium carbonate, and
collagen fibers.
These and a few other salts are deposited in a
framework of collagen fibers, a process called
calcification or mineralization.
The process of calcification occurs only in the
presence of collagen fibers.
Mineral salts confer hardness on bone while collagen
fibers give bone its great tensile strength.
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10
Bone Cells
1. Osteogenic cells undergo cell division and develop
into osteoblasts.
2. Osteoblasts are bone-building cells.
3. Osteocytes are mature bone cells and the principal
cells of bone tissue.
4. Osteoclasts are derived from monocytes and serve
to break down bone tissue.
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11
Cells of Bone
Osteoprogenitor cells ---- undifferentiated cells
can divide to replace themselves & can become osteoblasts
found in inner layer of periosteum and endosteum
Osteoblasts--form matrix & collagen fibers but can’t divide
Osteocytes ---mature cells that no longer secrete matrix
Osteoclasts---- huge cells from fused monocytes (WBC)
function in bone resorption at surfaces such as endosteum
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12
Osteoblasts Osteocytes Osteoclasts
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13
Matrix of Bone
Inorganic mineral salts provide bone’s hardness
hydroxyapatite (calcium phosphate) & calcium carbonate
Organic collagen fibers provide bone’s flexibility
their tensile strength resists being stretched or torn
remove minerals with acid & rubbery structure results
Bone is not completely solid since it has small spaces for
vessels and red bone marrow
spongy bone has many such spaces
compact bone has very few such spaces
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14
Compact Bone
Compact bone is arranged in units called osteons or
Haversian systems .
Osteons contain blood vessels, lymphatic vessels,
nerves, and osteocytes along with the calcified
matrix.
Osteons are aligned in the same direction along lines
of stress. These lines can slowly change as the
stresses on the bone changes.
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15
Compact or
Dense Bone
Looks like solid hard layer of bone
Makes up the shaft of long bones and the external
layer of all bones
Resists stresses produced by weight and movement
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16
Histology of Compact Bone
Osteon is concentric rings (lamellae) of calcified matrix
surrounding a vertically oriented blood vessel
Osteocytes are found in spaces called lacunae
Osteocytes communicate through canaliculi filled with
extracellular fluid that connect one cell to the next cell
Interstitial lamellae represent older osteons that have been
partially removed during tissue remodeling
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17
Spongy Bone
Spongy (cancellous) bone does not contain osteons.
It consists of trabeculae surrounding many red
marrow filled spaces.
It forms most of the structure of short, flat, and
irregular bones, and the epiphyses of long bones.
Spongy bone tissue is light and supports and
protects the red bone marrow.
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18
The Trabeculae of Spongy Bone
Latticework of thin plates of bone called trabeculae oriented along lines of
stress
Spaces in between these struts are filled with red marrow where blood cells
develop
Found in ends of long bones and inside flat bones such as the hipbones,
sternum, sides of skull, and ribs.
No true Osteons.
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19
Blood and Nerve Supply of Bone
Periosteal arteries
supply periosteum
Nutrient arteries
enter through nutrient
foramen
supplies compact bone of
diaphysis & red marrow
Metaphyseal & epiphyseal
aa.
supply red marrow &
bone tissue of epiphyses
- 20. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
20
BONE FORMATION
All embryonic connective tissue begins as
mesenchyme.
Bone formation is termed osteogenesis or
ossification and begins when mesenchymal cells
provide the template for subsequent ossification.
Two types of ossification occur.
Intramembranous ossification is the formation of
bone directly from or within fibrous connective
tissue membranes.
Endochondrial ossification is the formation of bone
from hyaline cartilage models.
- 21. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Stages of Intramembranous Ossification
Forms some flat bones of the skull, mandible, and clavicle.
An ossification center appears in the fibrous connective tissue
membrane
Bone matrix is secreted within the fibrous membrane
The matrix surrounds the cell and then calcifies as the
osteoblast becomes an osteocyte.
The calcifying matrix centers join to form bridges of
trabeculae that constitute spongy bone with red marrow
between.
On the periphery the mesenchyme condenses and develops
into woven bone and the periosteum.
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Stages of Intramembranous Ossification
Figure 6.7.1
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Stages of Intramembranous Ossification
Figure 6.7.2
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Stages of Intramembranous Ossification
Figure 6.7.3
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Stages of Intramembranous Ossification
Figure 6.7.4
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26
Endochondral Ossification
Endochondrial ossification involves replacement of
cartilage by bone and forms most of the bones of the
body
The first step in endochondrial ossification is the
development of the cartilage model.
Begins in the second month of development
Uses hyaline cartilage “bones” as models for bone
construction
Requires breakdown of hyaline cartilage prior to
ossification
- 27. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
27
Endochondral Bone Formation
Development of Cartilage model
Mesenchymal cells form a cartilage
model of the bone during development
Growth of Cartilage model
in length by chondrocyte cell division
and matrix formation ( interstitial
growth)
in width by formation of new matrix
on the periphery by new chondroblasts
from the perichondrium (appositional
growth)
- 28. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Stages of Endochondral Ossification
Formation of bone collar
Cavitation of the hyaline: cartilage cells in mid-
region burst and change pH triggering calcification
and chondrocyte death
Invasion of internal cavities by the periosteal bud,
and spongy bone formation
Formation of the medullary cavity; appearance of
secondary ossification centers in the epiphyses
Ossification of the epiphyses, with hyaline cartilage
remaining only in the epiphyseal plates
- 29. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
29
Stages of Endochondral Ossification cont.
Development of Primary Ossification
Center
perichondrium lays down
periosteal bone collar
nutrient artery penetrates center of
cartilage model
periosteal bud brings osteoblasts
and osteoclasts to center of
cartilage model
osteoblasts deposit bone matrix
over calcified cartilage forming
spongy bone trabeculae
osteoclasts form medullary cavity
- 30. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
30
Stages of Endochondral Ossification Cont.
Development of Secondary Ossification Center
blood vessels enter the epiphyses around time of birth
spongy bone is formed but no medullary cavity
Formation of Articular Cartilage
cartilage on ends of bone remains as articular cartilage.
- 31. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Formation
of bone
collar
around
hyaline
cartilage
model.
1
2
3
4
Cavitation
of the
hyaline
cartilage
within the
cartilage
model.
Invasion of
internal cavities
by the
periosteal bud
and spongy
bone formation.
5 Ossification of the
epiphyses; when
completed, hyaline
cartilage remains
only in the
epiphyseal plates
and articular
cartilages
Formation of the
medullary cavity as
ossification continues;
appearance of
secondary ossification
centers in the
epiphyses in
preparation for stage 5.
Hyaline
cartilage
Primary
ossification
center
Bone
collar
Deteriorating
cartilage matrix
Spongy
bone
formation
Blood
vessel of
periostea
l bud
Secondary
ossification
center
Epiphyseal
blood vessel
Medullary
cavity
Epiphyseal
plate
cartilage
Spongy
bone
Articular
cartilage
Stages of Endochondral Ossification
Figure 6.8
- 32. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Postnatal Bone Growth- Timeline
Growth in length of long bones
Cartilage on the side of the epiphyseal plate closest
to the epiphysis is relatively inactive
Cartilage abutting the shaft of the bone organizes
into a pattern that allows fast, efficient growth
Cells of the epiphyseal plate proximal to the resting
cartilage form three functionally different zones:
growth, transformation, and osteogenic
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Long Bone Growth and Remodeling
Figure 6.10
- 34. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Osteoblasts beneath
the periosteum
secrete bone matrix,
forming ridges that
follow the course of
periosteal blood
vessels.
1 2 3 4As the bony ridges
enlarge and meet,
the groove
containing the
blood vessel
becomes a tunnel.
The periosteum
lining the tunnel is
transformed into an
endosteum and the
osteoblasts just
deep to the tunnel
endosteum secrete
bone matrix,
narrowing the canal.
As the osteoblasts
beneath the endosteum
form new lamellae, a new
osteon is created.
Meanwhile new
circumferential lamellae
are elaborated beneath
the periosteum and the
process is repeated,
continuing to enlarge
bone diameter.
Artery Periosteum Penetrating canal
Central canal of osteon
Periosteal ridge
Appositional Growth of Bone
Figure 6.11
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35
Factors Affecting Bone Growth
Nutrition
adequate levels of minerals and vitamins
calcium and phosphorus for bone growth
vitamin C for collagen formation
vitamins K and B12 for protein synthesis
Sufficient levels of specific hormones
during childhood need insulinlike growth factor
promotes cell division at epiphyseal plate
need hGH (growth), thyroid (T3 &T4) and insulin
sex steroids at puberty
At puberty the sex hormones, estrogen and testosterone, stimulate sudden
growth and modifications of the skeleton to create the male and female
forms.
- 36. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
36
Factors that affect Bone Growth
EXERCISE: Within limits, bone has the ability to alter its
strength in response to mechanical stress by increasing deposition
of mineral salts and production of collagen fibers.
Removal of mechanical stress leads to weakening of bone
through demineralization (loss of bone minerals) and collagen
reduction.
reduced activity while in a cast
astronauts in weightless environment
bedridden person
Weight-bearing activities, such as walking or moderate
weightlifting, help build and retain bone mass.
- 37. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Bone Remodeling
Remodeling units – adjacent osteoblasts and
osteoclasts deposit and resorb bone at periosteal and
endosteal surfaces
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38
Bone Remodeling
Remodeling is the ongoing replacement of old bone
tissue by new bone tissue.
Old bone is constantly destroyed by osteoclasts,
whereas new bone is constructed by osteoblasts.
In orthodontics teeth are moved by braces. This
places stress on bone in the sockets causing
osteoclasts and osteoblasts to remodel the sockets
so that the teeth can be properly aligned
Several hormones and calcitriol control bone
growth and bone remodeling
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39
Bone Remodeling
Ongoing since osteoclasts carve out small tunnels and
osteoblasts rebuild osteons.
osteoclasts form leak-proof seal around cell edges
secrete enzymes and acids beneath themselves
release calcium and phosphorus into interstitial fluid
osteoblasts take over bone rebuilding
Continual redistribution of bone matrix along lines of
mechanical stress
distal femur is fully remodeled every 4 months
- 40. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Bone Deposition
Occurs where bone is injured or added strength is
needed
Requires a diet rich in protein, vitamins C, D, and A,
calcium, phosphorus, magnesium, and manganese
Alkaline phosphatase is essential for mineralization
of bone
Sites of new matrix deposition are revealed by the:
Osteoid seam – unmineralized band of bone matrix
Calcification front – abrupt transition zone between
the osteoid seam and the older mineralized bone
- 41. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
Bone Resorption
Accomplished by osteoclasts
Resorption bays – grooves formed by osteoclasts as
they break down bone matrix
Resorption involves osteoclast secretion of:
Lysosomal enzymes that digest organic matrix
Acids that convert calcium salts into soluble forms
Dissolved matrix is transcytosed across the
osteoclast’s cell where it is secreted into the
interstitial fluid and then into the blood
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During infancy and childhood, epiphyseal plate
activity is stimulated by growth hormone
During puberty, testosterone and estrogens:
Initially promote adolescent growth spurts
Cause masculinization and feminization of specific
parts of the skeleton
Later induce epiphyseal plate closure, ending
longitudinal bone growth
Hormonal Regulation of Bone Growth During
Youth
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Control of Remodeling
Two control loops regulate bone remodeling
Hormonal mechanism maintains calcium
homeostasis in the blood
Mechanical and gravitational forces acting on the
skeleton
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Hormonal Mechanism
Rising blood Ca2+ levels trigger the thyroid to
release calcitonin
Calcitonin stimulates calcium salt deposit in bone
Falling blood Ca2+ levels signal the parathyroid
glands to release PTH
PTH signals osteoclasts to degrade bone matrix and
release Ca2+ into the blood
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Hormonal Mechanism
Figure 6.12
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46
Hormonal Mechanism
Parathyroid hormone (PTH) is secreted if
Ca+2 levels falls
PTH gene is turned on & more PTH is
secreted from gland
osteoclast activity increased, kidney retains
Ca+2 and produces calcitriol
Calcitonin hormone is secreted from
parafollicular cells in thyroid if Ca+2 blood
levels get too high
inhibits osteoclast activity
increases bone formation by osteoblasts
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47
Calcium Homeostasis & Bone Tissue
Skeleton is a reservoir of Calcium & Phosphate
Calcium ions involved with many body systems
nerve & muscle cell function
blood clotting
enzyme function in many biochemical reactions
Small changes in blood levels of Ca+2 can be deadly
(plasma level maintained 9-11mg/100mL)
cardiac arrest if too high
respiratory arrest if too low
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48
Development of Bone Tissue
Both types of bone formation begin with
mesenchymal cells
Mesenchymal cells transform into
chondroblasts which form cartilage
OR
Mesenchymal cells become osteoblasts
which form bone
Mesenchymal Cells
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Developmental Aspects of Bones
Mesoderm gives rise to embryonic mesenchymal
cells, which produce membranes and cartilages that
form the embryonic skeleton
The embryonic skeleton ossifies in a predictable
timetable that allows fetal age to be easily
determined from sonograms
At birth, most long bones are well ossified (except
for their epiphyses)
- 50. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
50
Developmental Aspects of Bone Tissue
5th Week =limb bud appears as mesoderm
covered with ectoderm
6th Week = constriction produces hand or
foot plate
and skeleton now totally cartilaginous
7th Week = endochondral ossification
begins
8th Week = upper & lower limbs
appropriately named
- 51. Copyright © 2004 Pearson Education, Inc., publishing as Benjamin Cummings
AGING AND BONE TISSUE
By age 25, nearly all bones are completely ossified
A single gene that codes for vitamin D docking
determines both the tendency to accumulate bone
mass early in life, and the risk for osteoporosis later
in life
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52
AGING AND BONE TISSUE
In old age, bone resorption predominates
Of two principal effects of aging on bone, the first is the loss of
calcium and other minerals from bone matrix (demineralization),
which may result in osteoporosis.
very rapid in women 40-45 as estrogens levels decrease
in males, begins after age 60
The second principal effect of aging on the skeletal system is a
decreased rate of protein synthesis
decrease in collagen production which gives bone its tensile
strength
decrease in growth hormone
bone becomes brittle & susceptible to fracture