BIO11.01 Module 2 Skeletal System - Cartilage and Bone (9-12-2024)-1.pdf

Transcript

Skeletal System
(Part 1: Cartilage and Bone – Tissue Level)

BIO11.01 Human Biology, Health and Disease, Lecture
First Semester 2024-2025
September 16, 2024
Page References
Tortora 16th edition
Chapter 4 (pp. 134-137)
Cartilage
Microscopic features of bone
Chapter 6
Bone (Overview)
Chapter 9 (pp. 270-274)
Classification of Joints
Skeletal System
Recall: Types of connective tissue,
What are its functions?
Made up of cartilage and bone
Bones articulate with each other
through joints.
Both cartilage and bone are
specialized type of connective
tissue
Supports the structural
framework of the body.
Bone and Cartilage
Bone and cartilage serve distinct
functions within the skeletal system.
At the tissue level, bone and
cartilage both consist of cells that
are surrounded by an extracellular
matrix (ECM).
The ECM sustains and supports the
cells
Many protein and mineral
components
The appearance of the extracellular
matrix depends on the type and
function of the tissue.
Imagine a milk tea drink…
If the pearls/boba are the cells, the
milk tea itself will be the ECM… :)
How much boba do you want?
“Yesss.”
GEL-LIKE AND FLEXBILE ECM IN CARTILAGE.
Its cells (chondrocytes) are surrounded by an
ECM that is predominantly made of collagen
and elastic fibers.
HIGHLY MINERALIZED AND SOLID ECM IN BONE. Osteocytes are present
within the dark spaces within the mineralized matrix.
 Presence of Ground Substance
Tissue Function Organization Vascularity Covering
calcification (ECM) Component
Seen in areas of the None Chondroitin sulfate Chondrocytes are Avascular Perichondrium
body that needs to + Fibers (e.g., randomly arranged (Blood vessels
endure more strain collagen, elastic within the ECM. Cartilage are limited to
Cartilage (e.g., body weight); fibers) does not the
Elasticity (e.g., Cells appear to be have a blood perichondrium;
Cell Type: expansion of the floating within the supply. nutrients are
Chondrocyte ribcage); Provides a extracellular matrix. carried to
smooth surface for chondrocytes via
articulation (e.g., the ECM.)
joints)
Rigid tissue that Yes Calcium phosphate Regular arrangement Vascular Periosteum
provides a Developing bone + Fibers (e.g., of osteocytes within
framework for the undergoes a collagen) the mineralized ECM. Blood vessels
body as well as process known as are present
Bone
locomotion; Protects ossification Compact bone appears within
vital organs (e.g., associated with a to be organized into designated
Cell Type:
cranium and ribcage); marked deposition osteons. spaces of the
Osteocyte
Provides attachment of calcium bone.
for skeletal muscles. phosphate In spongy bone, they
(hydroxyapatite) are organized to form
within the ECM. trabeculae.
Cartilage
Flexible yet firm type of connective tissue that serve different functios
in the body.
This type of tissue is composed of cells called chondrocytes which are
housed in structures called lacunae.
The matrix is composed of chondroitin sulfate which may be admixed
with collagen and elastic fibers.
Chondroitin provides cartilage resilience (ability to assume its original shape
after deformation).
Collagen provides strength and stability to the cartilage.
The Three Types of Cartilage

Hyaline Cartilage Fibrocartilage Elastic Cartilage

There are three types of cartilage seen in the human body, each serving a very specific
function:
1. Hyaline cartilage
2. Elastic cartilage
3. Fibrocartilage
Hyaline Cartilage
This is the most common type of
cartilage.
Hyaline = “glassy”
Extracellular matrix appears like
frosted glass.
This cartilage is seen on the ends
of long bones (articular surface),
tips of ribs, airways (tracheal
cartilage) and in some portions of
the skull (e.g., nasal cartilage)
Hyaline cartilage also provides
the necessary framework for
later bone formation
(endochondral ossification).
Expansion of the ribcage
The articular
cartilage provides a
gliding surface for
the smooth
movement of joints.
 The nose is made up
of hyaline cartilage.

Trachea and bronchi
are surrounded by rings
of hyaline cartilage.
Elastic Cartilage
Recall: The role of elastic fibers
in the skin (dermis).
This a flexible and springy
cartilage due to the abundance
of elastic fibers in its matrix.
This can be seen in the
cartilage supporting the ear
(pinna) as well as in the
epiglottis.
The ECM in elastic cartilage is densely packed with elastic
fibers. This gives elastic cartilage its characteristic properties.
A special stain was used in this
photomicrograph of elastic
cartilage. The dense black
fibers indicate that the ECM
surrounding the chondrocytes
is filled with elastic fibers.
The epiglottis directs air to the lungs and food
to the esophagus. This structure is made up of
elastic cartilage.
When the food has already
gone down the esophagus, the
epiglottis immediately bounced
back to its original form, hence
the need for elastic cartilage.

Note: The food needs gravity to
go down to the esophagus.
Eating in a supine position
might lead the food to the
trachea causing blockage of the
airway, a phenomenon known
as aspiration.
Fibrocartilage
This type of cartilage has been
reinforced with more collagen
fibers making it resistant to
tensile and warping forces.
Some examples include the
intervertebral discs (annulus
fibrosus), symphysis pubis, and
the meniscus of the knee.
These are weight bearing and
bending regions of the body
FIBROCARTILAGE
DENSELY PACKED COLLAGEN FIBERS ARE SEEN IN THE ECM
The spine bears the weight of the
upper body. The intervertebral discs
between the vertebrae are made up of
fibrocartilage.
Fibrocartilage in the
symphysis pubis

Cushions the pelvis
from shearing
movements from
normal physical
activities (e.g. while
walking or running)

Becomes more flexible
in pregnant women to
accommodate the
baby passing through
during childbirth.
The meniscus bears the weight of the
upper body at the level of the knee joint.
It is made up of fibrocartilage to cushion
the knee when standing still and while
walking.
Cartilage
Distinctively, cartilage does
not have a blood or nerve
supply.
Blood vessels are confined
to the surrounding
perichondrium.
Nutrients and gases go
into the chondrocytes via
the extracellular matrix.
Clinical Correlation:
Cauliflower Ear
Commonly associated with
combat sports athletes, mixed
marital artists, boxers and
wrestlers
Deformity of the ear that is
commonly associated with
blunt trauma
Blood pooling on the ear could
lead to improper regeneration
of elastic cartilage and could
lead to permanent deformities.
Functions of Bone
Support
Bone serves as the structural framework of the body.
Attachment for soft tissues (connective tissue, fat, etc.)
Serves a points of attachment for muscle (via tendons)
Protection
Protects vital organs from potential injury (e.g., the cranium protects the
brain while the ribcage protects the heart and lungs)
Aids in movement
Skeletal muscles produce movement by acting on bones
Muscle contractions move a bone by its joint creating movement
Functions of Bone
Blood cell production
Within bones lies red bone marrow. Red bone marrow produce
red blood cells, white blood cells and platelets through a process
known as hemopoiesis.
In adults, this is localized to the sternum (breast bone), hip bones,
vertebrae (back bone), skull and humerus (arm bone).
In newborns, all bone marrow is red (and is involved in
hemopoiesis) but with increasing age, a proportion becomes
yellow bone marrow.
Functions of Bone
Mineral homeostasis
Bone serves as reservoirs for calcium and phosphorous. 99% of
calcium is stored in the bone
On demand, bone may release calcium into the body
Storage of fats
In contrast to red bone marrow, yellow bone marrow is made up
of fat cells. Fat serve as reservoirs of energy and can be used on
demand.
Bone
Bone is a specialized type of connective
tissue wherein calcium phosphate is
deposited within the matrix.
Bone is produced by cells called
osteoblasts.
When it is surrounded by the bone
matrix, the osteoblast transforms to
become an osteocyte.
Osteoclasts are responsible for
reabsorbing bone (e.g., removing existing
bone).
Increase concentration of calcium in
the body
Bone remodeling (e.g., gradual
change in the shape of the bone)
Compact and Spongy (Cancellous) Bone
Bone can be classified depending on how the ECM and the cells are
organized.
Compact bone appears dense and solid.
Cancellous bone appears porous with spaces in between. The bony
structures within spongy bone are called trabeculae.
The spaces are filled with bone marrow elements.
COMPACT BONE

OSTEON OR HAVERSIAN SYSTEM
Osteonic Bone Lamellae
(Haversian) Canal (Orange Rings)
(White Arrow)
Concentric rings of
Center of the ECM that consists of
osteon that mineral salts (mostly
contain blood calcium and
vessels and nerves. phosphates) which
Remember that give bone hardness
bone is and compressive
vascularized. strength + collagen for
tensile strength
The dark spaces (blue arrows) within
the lamellae are called lacuna
(similar to the term used in
cartilage). These structures contain
osteocytes.

Canaliculi (red arrows) are
small spaces originating from
the lacuna. These structures
house the processes
emanating from osteocytes.
These would provide ways for
nutrients to reach osteocytes
and eliminate wastes. These
also allow the cells to
communicate with each other.
COMPACT BONE FORMS OSTEONS
CANCELLOUS BONE (TRABECULAE) WITH BONE MARROW
Note the structure of spongy bone. Unlike
compact bone, the haversian canal is absent.
Lamellae, lacunae (with osteocytes) and
canaliculi are present.
Cortical and Medullary Bone
A bone can be divided into an
outer cortex and an inner
medulla.
Cortical bone - forms the
cortex (outer boundary) of
the bone.
Compact bone
Medullary bone is seen at
the core of the bone
producing a space that will
be filled up with bone
marrow elements.
Spongy bone
Lamellar Bone and Non-lamellar (Woven) Bone
Compact bone and spongy bone are
examples of lamellar bone.
Lamellar bone is characterized with a
more organized arrangement of
collagen fibers within the matrix.
Consists of a layer of bone matrix with
closely packed collagen fibers
During bone development, immature
bone tissue will organize to form
lamellar bone.
Regular arrangement of fibers within
lamellar bone provides additional
strength
Non-lamellar (Woven) and Lamellar Bone
Non-lamellar bone (woven bone) is
described to be a fast-growing
bone.
Has irregularly arranged
(disorganized) collagen fibers within
the matrix.
Given its faster rate of formation,
woven bone plays an important role
in the creation of new bone as well as
the healing of fractures
Where would you see lamellar bone
in the human body?
Woven bone needs to be reinforced to withstand physical stress. It will
develop to be lamellar bone (either spongy or compact) later on.
COMPACT BONE
SPONGY BONE
Chipboard / Particle Board (Irregularly arranged wood chips)
-VS-
Plywood (Laminated wood)
Regions of Long Bones
Epiphysis – This refers to the ends of long
bones.
Diaphysis – This area refers to the middle
shaft of the bone.
Metaphysis (epiphyseal plate) – Area
between the diaphysis and the epiphyses.
This area is made up of cartilage and indicates
ongoing growth of the long bone.
The epiphyseal plate is only present in young,
growing individuals. In adulthood the epiphyseal
plate will ossify forming an epiphyseal line.
Primary ossification center – diaphysis
Hyaline cartilage in the metaphysis (epiphyseal plate)
Milk and Bone Growth
Would someone still grow tall by drinking
milk?
Drinking milk would provide an
additional source of calcium and would
make bones stronger.
If the epiphyseal plate has disappeared,
one would not grow tall anymore.
Throughout life, bone still has to grow.
However, drinking milk as part of one’s
diet will increase the girth of bone.
Dwarfism and Gigantism
He Pingping (74 cm [2 ft. 5 in.])
Sultan Kösen (251 cm [8 ft. 2 in.])
These conditions are associated
with over or underproduction of
growth hormone (GH) that is
produced by the pituitary gland
in the brain.
Joints
“Articulations” or “Arthroses”
Refers to the point where two bones meet
Joints can be classified based on the following criteria:
Structural Classification
Based on the tissues that hold the bones together
Presence of a synovial cavity
Functional Classification
Range of Motion
Note: A joint will have its own structural and functional classification. These
terms would overlap.
Structural Classification
When referring to the structural classification, consider the tissue that
bind the bones together.
Fibrous joints – This joint is held by connective tissue with dense
collections of collagen fibers
Cartilaginous joints – Bones are held together by cartilage
Synovial joints – This type of joint is joined by ligaments and has a
fluid filled space known as the synovial cavity. This cavity is then
surrounded by a tough capsule of connective tissue.
Functional Classification
When referring to the functional
classification, this refers to the range
of motion.
Diarthroses – permits movement
Amphiarthroses – permits movement
to a certain degree
Synarthroses – restrictive, do NOT
permit any movement
Synarthroses are classified further
based on the type of tissue joining
the bones together
Examples of Fibrous Joints
Sutures – joints that connect the bones of the skull together
The interlocking edges of the suture would give the cranium additional
strength and decrease the chances of fracturing
Syndesmoses – bones are joined together by dense connective tissue
Dentoalveolar joints – the connective tissue holds the tooth to the socket of
the jaw
Interosseous Membranes – bones are held together by sheets of
connective tissue
Binds long bones together while permitting movement
Radius + ulna, Tibia + fibula
Skull (superior view)
In this view, the anterior
portion of the skull (frontal
bone) is joined to the parietal
bone by sutures. Note the
interlocking pattern present
on the sutures.
Skull (posterior view)
In this view, the interlocking
pattern of the suture. Take note
that some sutures are completely
made up of bone and thus
classified as a synostosis. These
joints are classified as synarthrosis
because they are immovable.

These bones are
completely fused by
age 6.
In infants (neonates), the sutures in the skull have not completely closed, these openings
are referred to as fontanelles.
 Interosseous Dentoalveolar Joints
Membrane (Syndesmosis)
Sutures
Synostosis
“Bone-to-bone”
Bones are articulated
directly to each other
(e.g., sacrum)
Cartilaginous Joints
a.) Synchondroses
Bones are joined
together exclusively by
hyaline cartilage (These
could also be classified
as synarthroses.)

b.) Symphyses
Bones are held together
by fibrocartilage (These
could also be classified
as amphiarthroses.)
Recall: Where can you
locate fibrocartilage? ☺
Synovial Joint
Synovial joint are diarthroses - Joints
that permit movement

Structure:
Synovial capsule - dense fibrosus
tissue that covers the joint. This has
the consistency of uncooked egg
white.
Synovial membrane - produces
synovial fluid that lubricates the
joint.
Articular cartilage is also observed at
the ends of the involved bones.
Gout is a form of
(painful) arthritis that
develops over specific
joints due to the
accumulation of uric
acid (as an effect of a
purine-rich diet). Initial
signs and symptoms
involve pain and
redness on the affected
joint (e.g., big toe).
Tophi (crystalline deposits of uric acid) developing on the joints
in uncontrolled cases of gout. As uric acid crystals accumulate,
gross deformities over the affected joint eventually appear.
Purine-rich foods
”Popping Joints”

”Popping joints” can occur when
air is released from the synovial
fluid.

After a joint has been “popped,”
it might take a few minutes
before air builds up again in the
joint.
Fractures
Refers to any break in the bone
Breaks in the bone may not have to
be visible by x-rays or by the naked
eye
Stress fractures are microscopic
fissures in the bone with no
evidence of injury to other tissues
Due to repeated strenuous activities
(e.g., running and jumping) and may
be observed in professional athletes.
Stress fractures
on the metatarsal
bone of the right
foot is due to
repeated stress
over a period of
time (e.g.,
running). In some
cases, this may
cause pain and
swelling.
Types of Fractures
Open (compound)
The broken ends of the bone
protrude through the skin
Closed
The bone does not break through
the skin
ULNA

Open Fracture
X-ray was taken on two
RADIUS different views.
Note the ulna is
protruding from the skin.

Classify the fracture
encountered on the
radius.

ULNA RADIUS
Stages of Fracture Repair

Reactive Phase
Reparative Phase
[Initial] Fibrous cartilage callous formation
[Late] Bony callus formation
Bone Remodeling Phase
Stages of Fracture Repair
Bone heals more rapidly than
cartilage because of its blood supply.
Reactive Phase
Early inflammatory phase that occurs
after the traumatic injury
Ruptured blood vessels within the
bone leads to the formation of a mass
of clotted blood around the site of
injury (fracture hematoma)
6-8 hours after the injury
Bone cells adjacent to the fracture
hematoma dies
Macrophages and osteoclasts remove
the damaged tissue and bone
Stages of Fracture Repair
Reparative Phase (Fibrous cartilage callous formation)
Blood vessels grow into the fracture hematoma and clean up dead
cells and debris
Fibroblasts and chondroblasts from the periosteum would now
produce collagen fibers creating a fibrous cartilage (soft) callus to
bridge the broken ends of bone.
Formation of the soft callus takes about 3 weeks.
Stages of Fracture Repair
Reparative Phase (Bony callus formation)
In areas of the callus that is closer to a developed blood supply,
bone would now develop.
Woven bone (non-lamellar) initially develops over the bone
Eventually, these would now form spongy bone trabeculae.
The bony callus forms when fibrous cartilage is gradually
converted to spongy bone.
This process may last up to 3-4 months.
LAMELLAR BONE WOVEN BONE
Stages of Fracture Repair
Bone Remodeling Phase
The callus now undergoes remodeling or reshaping
This phase is the longest any may last for years
Dead portions of the original bone fragments are reabsorbed by
osteoclasts
Compact bone replaces spongy bone around the area of the
fracture
In some cases, repair has been so thorough that the fracture line is
undetectable.
Fracture of the humerus (diaphysis) of an infant at birth. Given their young age, bone
repair and remodeling is successful as seen in subsequent radiographs.
Fracture Repair
Although bone has an
adequate blood supply,
healing may still take
months.
Calcium and phosphorus
is only deposited gradually
and bone cells tend to
reproduce slowly.
Reduction refers to the
process of setting a
fracture (closed vs. open). The use of plaster clasts would fall
under closed reduction.
In some situations, metal implants might be used
to align bones together.
Summary
When studying bone at the tissue level, compare the to what was
observed in cartilage.
Similarities
Both are types of connective tissue (cells are suspended within an extracellular
matrix.
Cells are housed in lacunae
Differences
The cells are different (chondrocytes vs osteocytes)
Cartilage is designed for flexibility and elasticity, Bone is meant to serve as a rigid
structure serving as the body’s framework and protection
What are the components within the ECM? Chondroitin sulfate in cartilage,
Calcium phosphate in bone
Blood supply: absent in cartilage, present in bone
Summary
Bone can be classified in different ways.
Cortical vs. Medullary Bone
Non-lamellar (woven bone) vs. Lamellar bone (compact and
spongy bone)
Remember: ”Lamellar” → It has lamellae.
Classification of joints can overlap
Structural classification (What holds the joint together?)
Functional classification (Range of motion?)
Thank you!