Chapter 6: Bones And The Skeletal System PDF

Summary

This document details the structure and functions of bones and cartilage. It includes an overview of different bone types and their roles in the body. The document also describes the processes of bone formation, bone healing, and various bone disorders.

Full Transcript

Chapter 6: Bones and
the Skeletal System
 Adult cartilage
 No blood vessels or nerves
 High water content
 Surrounded by
perichondrium

 Dense irregular connective
tissue, blood supply
Three types
 Hyaline (articular, costal,
respiratory, nasal)
 Elastic (external ear, epiglottis)
 Fibrocartilage (knee,
intervertebral discs)
Functions of Bone (organ)
Support: framework that supports the body
Protection : protective case for the brain, spinal
cord, and vital organs
Movement: anchors/levers for muscles
Mineral storage: reservoir for minerals,
especially calcium and phosphate, and growth
factors
Blood cell formation: hematopoiesis
Triglyceride storage: fat
Hormone production: osteocalcin, energy cycle
Classification of Bones: Location
Axial skeleton
 Skull
 Vertebrae
 Rib cage
Appendicular skeleton
 Upper and lower limbs
 Shoulders
 Hips
 Classification of Bones: Shape

Long bones
 Longer than they are wide
Flat bones
 Thin, flattened, curved
 Includes sternum, scapula,
skull and ribs
Classification of Bones: shape
Short bones
 Cube-shaped, wrist/ankle
 Sesamoid, inside tendons
Irregular bones
 Odd shapes (ex. Vertebrae)
Bone markings: for muscle/ligament/tendon
attachment, joint surfaces, or conduits for
blood vessels/nerves
Condyle –round prominence at the end of a bone, often at a joint
articulation
Epicondyle –a prominence on the distal part of a long bone,
attachment point for muscles and ligaments
Trochanter –protruberances by which muscles attach or bones
connect to each other
Tubercle –a round nodule, small emience
Tuberosity –a rounded, long/oblong prominence
Trochlea –a grooved structure like a pulley’s wheel
Fossa –a depression or hollow
Foramen –an opening
Meatus –external opening of a canal/passage leading into the body
Gross Anatomy of Bones
Compact bone – dense outer
layer, smooth surface
Gross Anatomy of Bones
Spongy bone –
inner honeycomb
layer= trabeculae
filled with
red/yellow marrow
Structure of flat, irregular,
short bones
Sandwich-like
Thin plates of spongy
bone, diploë , covered
in compact bone
No defined marrow
cavity
No diaphysis or
epiphyses
Covered by
connective tissue
layers
Structure of Long Bone
I. Diaphysis
Tubular shaft
Exterior: compact bone collar,
thin layer of spongy bone
Interior: medullary cavity with
yellow marrow (fatty marrow)
Structure of Long Bone
II.. Epiphyses
Expanded ends of long
bones
Exterior is compact bone
Interior is spongy bone

Epiphyseal line/plate
separates the diaphysis
from the epiphyses
Which of the following is not a
type of cartilage?
a) Hyaline
b) Elastic
c) Fibrocartilage
d) Dense regular
What type of cartilage is found at the
joint surface between two bones?
A.Fibrocartilage
B. Hyaline
C. Elastic
Structure of Long Bone
Bone Membranes
Periosteum (two layers)
Outer fibrous layer is
dense irregular
connective tissue
Inner osteogenic layer
contains osteogenic stem
cells
Richly supplied with nerve
fibers, blood, and
lymphatic vessels
Anchoring point, collagen
Bone Membranes
Endosteum – delicate layer
covering internal bone
surfaces
Covers trabeculae of spongy
bone
Lines the canals of compact
bone
Contains osteogenic stem cells
Which membrane would you find on the
outer surface of this skull bone?
A. Periosteum
B. Endosteum
Which membrane would you around the
trabeculae of this skull bone?
A. Periosteum
B. Endosteum
Hematopoietic Tissue
(Red Marrow)
Infants
 Found in the medullary cavity (long
bones) and all areas of spongy bone
Adults
 Found in the diploë of flat bones (hip,
sternum, etc.), and the head of the
femur and humerus

Homeostatic help: yellow marrow
can convert to red marrow under
conditions of extreme anemia
If you were treating a person with leukemia,
where would you try to get healthy bone
marrow from a donor?
A. Hip
B. Humerus
C. Skull
D. Vertebrae
Types of Bone cells
Osteogenic cell
 Bone stem cell (actively dividing cells)
 Gives rise to osteoblasts and more progenitors.
Osteoblasts
 Bone-building cells
Types of Bone cells
Osteocytes (mature bone cells)
 Monitor and maintain bone matrix
 In lacunae or lining bone surfaces
Osteoclasts
 Bone-digesting cells (resorption)
Microscopic Structure: Compact Bone
Haversian system/Osteon:
structural unit, pillar
Lamella : weight-bearing
columns, collagen in
adjacent lamella alternate
to resist twisting
Haversian/ Central canal:
contains blood vessels and
nerves
Volkmann’s canals:
horizontal channels
connecting the medullary
cavity to the Haversian
canal and Periosteum
Microscopic Bone Structure
Microscopic Structure: Compact Bone
Haversian system/Osteon:
structural unit, pillar
Osteocytes: mature bone
cells
Lacunae: small cavities in
bone containing osteocytes
at lamella junctions
Canaliculi: hair-like canals
that connect lacunae to
each other and the central
canal
Microscopic Bone Structure
Microscopic Structure: Spongy
bone
Trabeculae align along
lines of stress
Irregularly arranged
lamella with osteocytes
and canaliculi
 Chemical Composition of Bone
Organic Components –resist tension
 Bone cells
 Osteoid : unmineralized bone matrix
 Osteoblasts secrete: proteoglycans,
glycoproteins, and collagen
▪ Allows bone to resist stretching and
twisting
▪ About 1/3 of the bone matrix
▪ “Sacrificial bonds” between
collagen break and reform to
prevent large-scale fractures
Chemical Composition of Bone
Inorganic components–
resist compression
 Mineral salts
 65% of bone by mass
 Mainly calcium
phosphate crystals tightly
packed around the
collagen fibers
 Responsible for bone
hardness and resistance
to compression
Bone Development
Osteogenesis (ossification) includes:
The formation of the bony skeleton in
embryos
Bone growth until early adulthood
Bone thickness, remodeling, and
repair in adults
 Embryonic development
Most of the human
skeleton is first formed of
cartilage or fibrous
membranes
Cartilage cells are able to
divide and multiply
quickly. Thus, the cartilage
can grow as rapidly as the
fetus does http://schoolbag.info/biology/humans/6.html
Embryonic development
Beginning in the third month and continuing
through prenatal development, the cartilage is
gradually replaced by bone
Formation of the Bony Skeleton
Begins at week 8 of embryonic development
A.) Intramembranous ossification
Bone develops from a fibrous membrane
Forms flat, cranial bones of skull
B.) Endochondral ossification
Bone forms by replacing hyaline cartilage
Forms all other bones of the body
Stages of Intramembranous
Ossification
1. Mesenchymal cells produce fibrous
membrane
2. Ossification center appears with osteoblasts
Stages of Intramembranous
Ossification
3. Bone matrix is woven in-between blood vessels
4. Spongy bone and outer periosteum form
Stages of Intramembranous
Ossification
5. Compact (lamellar) bone forms
6. Red marrow appears in spongy bone
Endochondral Ossification
Uses hyaline cartilage
“bones” as models for
bone construction
Requires breakdown of
hyaline cartilage prior to
ossification
Stages of Endochondral Ossification
1. Blood vessels infiltrate the perichrondrium converting it
to periosteum = primary ossification center

2. Mesenchymal cells become osteoblasts
Stages of Endochondral Ossification
3. Formation of bone collar around the diaphysis

4. Hyaline cartilage calcifies, matrix deteriorates, creates
cavities as chondrocytes die
Stages of Endochondral Ossification
5. Invasion of internal cavities by the periosteal bud,
spongy bone formation by osteoclasts and osteoblasts

6. Formation of the medullary cavity, elsewhere cartilage
continues expanding
Stages of Endochondral Ossification
7. @birth, secondary ossification centers form in the epiphyses

8. Spongy bone replaces cartilage of the epiphyses

Hyaline cartilage remains only in the epiphyseal plates,
articular cartilage
Growth of Bone/Cartilage
Appositional (outside-in)
 Cells secrete matrix against the external face of
existing cartilage
Growth of Bone/Cartilage
Interstitial (inside-out)
 Lacunae-bound cells divide and secrete new matrix,
expanding the tissue from within
Growth of Bone/Cartilage
Long bones lengthen by interstitial growth
Bones get thicker by appositional growth
Timing
 Most bone/cartilage development is complete
by adolescence

Calcification (hardening) of cartilage occurs
 During normal bone growth
 During old age
Postnatal Bone Growth: Long bones
Cartilage closest to the
epiphysis is quiescent
(resting)
Cartilage next to the
diaphysis is organized into
stacks that allow fast,
efficient growth
Four distinct zones form
Proliferative/Growth
Hypertrophic
Calcification
O. ssification
Functional Zones: Long Bone Growth
Growth zone
Chondrocytes
divide, pushing the
epiphysis away
from the diaphysis
Functional Zones: Long Bone Growth
Transformation zones
Older chondrocytes
hypertrophy
(enlarge)
Matrix calcification;
chondrocytes die
Functional Zones: Long Bone Growth
Ossification zone
New bone formation
by osteoblasts and
osteoclasts
Long Bone Growth+Remodeling
Epiphyseal ends are
remodeled to
maintain the correct
proportion
diaphysis:epiphyses
Bone Growth+Remodeling
Appositional growth for width
Osteoblasts
Add bone appositionally
(outside in) from periosteum
Osteoclasts
Resorb bone near surface of
endosteum
Overall effect
Bone increases in width
Bone doesn’t get too heavy
Epiphyseal plate closure

Chondroblasts divide less
often
Plate becomes thinner,
replaced with bone tissue
~18 females
~21 males
Hormonal Regulation of Bone Growth
Infancy and childhood
Growth hormone and thyroid hormone
Deficiencies or excesses  homeostatic imbalances
Hormonal Regulation of Bone Growth
Puberty
Primarily testosterone and.
estrogens
Initially promotes
adolescent growth spurts
Causes masculinization
and feminization of the
skeleton
Later induces epiphyseal
plate closure (You’re done
growing up!)
Bone homeostasis: remodeling
5-10% of our bone is recycled every year
WHY? calcium storage/release
Spongy bone: replaced every 3-4 years
Compact bone: replaced every 10 years
Prevents bones from becoming brittle

High-stress areas remodeled more frequently (femur)
Bone Deposition
Occurs where bone is injured or
added strength is needed by
osteoblasts
Diet: Requires protein, vitamins
C, D, and A, calcium,
phosphorus, magnesium, and
manganese
Enzyme: Requires alkaline
phosphatase for mineralization
of bone
High alkaline phosphatase levels
in blood may indicate:
A. Osteoporosis
B. Bone Cancer
C. Bed-ridden patient with a lack of physical activity
Bone Resorption
Osteoclasts secrete:
Lysosomal enzymes digest organic
matrix
Hydrochloric acid that converts
calcium salts into soluble forms
Phagocytosis matrix/osteocytes
Result: stored calcium is released
into blood supply
 Physiological Roles for Calcium
 Transmission of nerve impulses
 Muscle contraction
 Blood coagulation
 Cell division
 Secretion by glands and nerve cells
 Bone structure
 Intestine absorbs using Vitamin D
 Control of Remodeling
1.) Hormonal mechanisms maintain calcium
homeostasis in the blood
-Conversation between intestine, brain, and
bones
-Decides whether and when remodeling occurs
2.) Mechanical forces act on the skeleton
-Decides where remodeling occurs
Control of Remodeling
1.) Hormonal
mechanisms maintain
calcium homeostasis in
the blood
Falling blood Ca2+ levels
signal the parathyroid
glands to release PTH=
parathyroid hormone
PTH signals osteoclasts
to degrade bone matrix
and release Ca2+ into
the blood
 Hormonal Mechanism
1) Hormonal: Rising blood
Ca2+ levels trigger the
thyroid to release calcitonin
Calcitonin stimulates
calcium deposit and storage
in bone
NOTE: Calcitonin’s effects
are more pronounced in
childhood than adulthood
 Response to Mechanical Stress
2.) Mechanical forces act on the
skeleton
Wolff’s law: Bones grow in
response to the forces placed
upon them
Curved bones are thickest
where they are most likely to
buckle
Bones atrophy when not
stressed/used
Bony projections =muscle
attachments
Deforming a bone makes an
electrical current ->osteocytes
 How is this person handed?
A. Left handed
B. Right handed

http://biomedicalcomputationreview.org/4/1/posters/taylor_Tennis_poster.pdf
In a patient whose parathyroid glands
have been removed, you would expect
that person’s blood calcium levels to
_______.
a) decrease
b) increase
c) stay the same
d) increase twofold
Bone Fractures (Breaks)
Bone fractures are classified by:
POSITION: Displaced v. Non-displaced
DEGREE OF BREAK: Complete v.
Incomplete
ORIENTATION: Linear v. transverse
SKIN DAMAGE: Compound (open/breaks
skin) v. Simple (closed/no break in skin)
Common Types of Fractures
Comminuted
Bone breaks into three or more pieces
Common in the elderly

Spiral
Ragged break when bone is severely
twisted
Common sports injury

Depressed
Bone is pressed inward
Typical of skull fractures
Common Types of Fractures
Spiral
Ragged break when bone is severely twisted
Common sports injury
Common Types of Fractures
Depressed
Bone is pressed inward
Typical of skull fractures
Common Types of Fractures. Compression
Bone is crushed
Typical of osteoporosis (crushed vertebrae)
Common Types of Fractures
Epiphyseal
Epiphysis separates from diaphysis
Common Types of Fractures
Greenstick
Incomplete fracture (one
side of the bone breaks
and the other side bends)
Common in children with
growing, flexible bones
Treatment
Reduction –
realignment of
broken bone ends
Immobilization –by
cast or traction
Stages of Bone Healing

Hematoma formation
Torn blood vessels
hemorrhage, mass of
clotted blood
Cells without blood
supply die off
Pain and inflammation
 Stages of Bone Healing
Fibrocartilaginous callus
forms “splint” across fracture
New blood vessels form
Phagocytic cells begin
cleaning debris
Fibroblasts secrete collagen
across the break
Chondroblasts secrete
cartilage
Stages of Bone Healing

Bony callus formation
Osteoblasts form spongy
bone
Fibrocartilaginous callus
converts into a bony (hard)
callus
Process continues for 2-3
months similar to
endochondral ossification
Stages of Bone Healing
Bone remodeling
Excess material is
removed
New compact bone
rebuilds shaft walls
Takes several months to
complete
Total 6-8 weeks for young
adults, longer for elderly
New treatments for damaged bones
Electrical stimulation:
speeds healing after large
fractures
Ultrasound: reduces time to
heal broken arms and shins
Fibular graft: improved way
to graft bone in areas with
severe damage
 New treatments for damaged bones
VEGF: growth factor that increases blood supply
Bone substitutes (implanted at damaged sites)
Includes natural (coral) and synthetic materials
Sometimes coated with BMP (bone morphogenic protein)
3-D printed bones
Perfectly designed to match a patient
Made out of titanium powder - heated and fused
together by a laser, one layer at a time
Includes passages for nerves and blood vessels
Which treatment would you
choose for a severe break?
A. 3-D printed bone
B. Fibular graft
C. Coral/synthetic bone
Homeostatic Imbalances
Osteomalacia
Bones are inadequately mineralized causing
softened, weakened bones
Main symptom is pain when weight is put on the
affected bone
Caused by insufficient calcium or vitamin D
 Homeostatic Imbalances.Rickets
Bones of children are inadequately
mineralized causing softened, weakened
bones
Bowed legs and deformities of the pelvis,
skull, and rib cage are common
Caused by insufficient calcium or vitamin D
What treatments would you recommend
for someone with Osteomalacia or
Rickets?
A. Calcium rich foods
B. Sunlight
C. A and B
D. None of the above
What type of bone disorder is
shown here (b)?
A. Osteomalacia
B. Greenstick fracture
C. Osteoporosis
Homeostatic Imbalances

Osteoporosis
Group of diseases in which bone reabsorption
outpaces bone deposit
Bones are porous and light
Spongy bone of the spine, femur neck are vulnerable
Occurs most often in postmenopausal women
Severe cases: Even sneezing or stepping off a curb
can cause fractures (pathologic fractures)
 Osteporosis prevention
Good diet EARLY in life (calcium and
Vitamin D)
Weight-bearing exercise
Don’t smoke (reduces estrogen levels)
Drink fewer carbonated beverages/alcohol
Fluoride (already in water supply)
NOTE: Genetic change in Vitamin D receptor
increases risk of osteoporosis
Osteoporosis Treatments
Calcium, Vitamin D supplements
Weight-bearing exercise
Drugs that stimulate osteoblasts, inhibit
osteoclasts
Hormone replacement therapy (only slows bone
loss)
Other risks
Paget’s Disease
Characterized by excessive bone formation and
breakdown
RESULT: spotty weaknesses in bone
Overabundance of spongy bone relative to compact
bone
Generally affects adults over age 40
Usually localized to spine, femur, pelvis and skull
Other bone disorders
ACHONDROPLASIA
Form of genetic dwarfism (FGFR-3 gene)
Reduced cartilage formation reduces
endochondral bone formation
Other bone disorders
OSTEOGENESIS IMPERFECTA
Insufficient collagen deposition
Bones become brittle and shatter easily
Other bone disorders
OSTEOSARCOMA
Bone cancer
Most common between ages of 10 and 25
Why?????