Bones PDF

Summary

This document provides an overview of bone anatomy. It describes the macroscopic structure of bones, including compact and spongy bone, as well as the diaphysis, epiphysis, and epiphyseal plate. The physical properties of bones, such as tensile and compressive strength, are also discussed. Key concepts for bone biology are also described.

Full Transcript

BONES Macroscopic Structure of Bone

There are two primary forms of bone tissue
Bone is a type of connective tissue that visible macroscopically:
consists of cells, fibers, and ground
substance, with its extracellular matrix 1. Compact Bone (Substantia
calcified, distinguishing it from other Compacta): This is dense, solid
connective tissues. The calcified matrix bone tissue that forms the outer layer
makes bone an ideal tissue for its primary of bones. It appears as a continuous
functions: mass, with only microscopic spaces
visible.
Support and Protection: Bone 2. Spongy Bone (Substantia
provides the internal support for the Spongiosa): This is lighter and more
body and forms the skeleton. It serves as porous, consisting of a lattice of
a framework for the attachment of branching bone spicules called
muscles and tendons, which are trabeculae. The spaces between
essential for movement and locomotion. trabeculae are filled with bone
Bones also protect vital organs, such as marrow.
the brain and heart.
Reservoir for Calcium: Bone acts as a In long bones such as the femur or humerus,
dynamic storage depot for calcium. It the structure is organized into:
plays an important metabolic role by
storing calcium, which can be mobilized 1. Diaphysis (Shaft): The central part of
as needed to maintain the calcium ion a long bone, made up of a thick-
concentration in the blood and other walled cylinder of compact bone
bodily fluids. surrounding the medullary cavity,
Hematopoiesis: The bone encloses which contains bone marrow.
bone marrow, which is the site of blood 2. Epiphysis (Ends): The ends of long
cell production (hematopoiesis). bones consist mostly of spongy bone
covered by a thin layer of compact
Physical Properties of Bone bone. The spongy bone here is
continuous with the marrow cavity in
Bones exhibit a remarkable combination of adults.
physical properties: 3. Epiphyseal Plate: In growing bones,
the epiphysis is separated from the
Tensile Strength: Resistance to stretching. diaphysis by a cartilaginous plate,
Compressive Strength: Ability to which allows for bone growth in
withstand forces that compress the bone. length. Bone growth occurs here, with
Elasticity: Some flexibility allows bones cartilage continuously being replaced
to absorb shock. by bone tissue.
4. Metaphysis: The area between the
Lightweight: Despite its strength, bone is
relatively light, thanks to its efficient epiphysis and diaphysis, containing
internal architecture. the growth zone where the transition
from cartilage to bone occurs.
Dynamic Tissue: Bone is continually
The surface of bones, except where tendons,
remodeled in response to mechanical
ligaments, or articular cartilage cover it, is
stresses, metabolic needs, and nutritional
invested by the periosteum, a fibrous layer
influences. Disuse leads to atrophy, and
with osteogenic potency (ability to produce
increased use results in hypertrophy.
bone tissue). The periosteum is absent in
areas covered by articular cartilage and where
tendons and ligaments insert into the bone.

The inner surfaces, including the medullary
cavity and the cavities within spongy bone,
 are lined by the endosteum, a thin cellular of osteons, containing blood vessels
layer with similar osteogenic potential as the and connective tissue.
periosteum. TOV Volkmann’s Canals: Transverse or
oblique channels that connect
In flat bones (like those of the skull), Haversian canals to the bone's
compact bone forms two layers, the outer surface and marrow cavity. These
and inner tables, which enclose a thin layer channels are not surrounded by
of spongy bone called the diploe. The concentric lamellae and allow blood
pericranium covers the outer surface of vessels from the periosteum to
skull bones, while the dura mater covers penetrate the bone.
the inner surface.

Microscopic Structure of Bone

At the microscopic level, bone is mostly
composed of bone matrix (mineralized
extracellular substance) arranged in layers
called lamellae:

Osteocytes are the mature bone
cells, housed in small cavities called
lacunae, spaced uniformly
throughout the bone matrix.
Canaliculi are slender channels that ***SHARPEY’S FIBERS
radiate from each lacuna, allowing
the osteocytes to communicate and - are coarse bundles of collagen fibers that
exchange nutrients with neighboring extend from the outer layer of the
cells. periosteum into the bone matrix, anchoring
the periosteum to the underlying bone.
The lamellae of compact bone are arranged
in three common patterns: - occupy irregular channels, while calcified
fibers appear as faint streaks in the outer
1. Haversian Systems (Osteons): portions of compact bone.
Cylindrical structures consisting of Osteoprogenitor cells
concentric lamellae surrounding a Bone Cells - Osteoblasts
Osteoclasts
central Haversian canal, which
Osteocytes
contains blood vessels and nerves. Four types of cells are involved in bone
Each osteon typically contains 4-20 development, maintenance, and remodeling:
lamellae.
2. Interstitial Systems: Irregular pieces Osteoprogenitor Cells
of lamellar bone found between
Haversian systems, remnants of old Origin: Derived from embryonic
osteons that have been partially mesenchymal cells, which have broad
resorbed. developmental potential.
3. Circumferential Lamellae: Located Location: Found on or near all free
on the external and internal surfaces surfaces of bones, including the
of compact bone, these lamellae run endosteum, inner layer of the
around the circumference of the periosteum, and trabeculae of
bone, just beneath the periosteum or calcifying cartilage in growing bones.
endosteum. Morphology:
o Pale-staining, elongated or oval
Two types of vascular channels are found in nuclei.
compact bone: o Scant cytoplasm that is acidophilic
or faintly basophilic.
HCL Haversian Canals: Longitudinal Function:
channels that run through the centers
 o They have limited differentiation o Produce growth factors that
potential and can only become regulate bone growth and
osteoblasts or chondroblasts. respond to hormonal signals
o Most active during bone growth (e.g., parathyroid hormone).
but can be reactivated for fracture
repair. Osteocytes
o They proliferate and differentiate to
replenish osteoblasts during the Origin: Mature osteoblasts that have
continual internal remodeling of become embedded in the bone
bone. matrix.
o Unlike osteoblasts, they are capable Location: Reside in lacunae within
of cell division. the mineralized matrix.
o Bone-lining cells: Morphology:
OSTEOBLASTS that have o Flattened cells with long, slender
become inactive after completing processes that extend through
their role in bone formation. canaliculi, connecting them with
Although they are inactive, they neighboring osteocytes and
are not morphologically surface cells.
distinguishable from o These processes are
osteoprogenitor cells. These cells interconnected through gap
can become reactivated and turn junctions, allowing for nutrient
back into osteoblasts when needed, and signal exchange.
such as during bone repair after Function:
injury. o Maintain the bone matrix and
regulate mineral content.
Osteoblasts o Play a role in detecting
mechanical stress on bone,
Origin: Formed from which influences bone
osteoprogenitor cells. remodeling.
Location: Found on bone surfaces o Controversial role in osteocytic
where active bone formation is osteolysis (once thought to
occurring. mobilize calcium directly from
Morphology: the matrix, now largely attributed
o Cuboidal or columnar cells to osteoblast and osteoclast
arranged in an epithelioid layer. interaction).
o Intense basophilic cytoplasm o Some osteocytes revert to
with a prominent Golgi complex. quiescent bone-lining cells upon
o The nucleus is typically release from their lacunae during
positioned away from the bone bone resorption.
surface.
Function: Osteoclasts
o Responsible for synthesizing
bone matrix (osteoid), which Origin: Formed from mononuclear
includes type-I collagen, precursors in the bone marrow,
proteoglycans, and non-collagen specifically from granulocyte-
proteins (osteocalcin, macrophage progenitors.
osteopontin, etc.). Location: Found on bone surfaces
o When embedded in the matrix undergoing resorption, occupying
they secrete, they differentiate shallow depressions called
into osteocytes. Howship’s lacunae.
o Release enzymes involved in
bone resorption, including "Osteoclasts sail on Howship's
procollagenase and plasminogen Lacunae, where they clash and dig
activator, helping to expose their bone pits!"
mineralized bone for osteoclast
action. "Osteo-CLASH with the ship!"
 Morphology:
o Large, multinucleated cells with
diameters of up to 150 µm,
containing 10-50 nuclei.
o Their bone-facing surface forms Bone Matrix
a ruffled border, an area with
deep membrane infoldings The bone matrix is composed of two main
responsible for bone degradation. components:
o Surrounded by a sealing zone,
which isolates the resorption area Organic Matrix (35%): Composed
from the rest of the bone. mostly of type-I collagen fibers
embedded in a ground substance rich
in proteoglycans. These fibers give
bone its tensile strength and
flexibility.
Inorganic Matrix (65%):
Comprised primarily of calcium
phosphate in the form of
hydroxyapatite crystals. These
crystals are deposited along the
collagen fibers and give bone its
hardness and ability to resist
compression.

Periosteum and Endosteum

The periosteum consists of two layers:
Function: 1. Outer Fibrous Layer: Dense
o Responsible for bone resorption
connective tissue with numerous
by creating an acidic environment blood vessels.
in the subosteoclastic 2. Inner Osteogenic Layer: Contains
compartment, which dissolves the osteoprogenitor cells that can
mineral matrix. differentiate into osteoblasts when
o Secrete lysosomal enzymes such
bone growth or repair is needed.
as acid hydrolases that degrade Sharpey’s Fibers are collagen
organic components of bone. bundles from the periosteum that
o Regulated by several hormones:
penetrate the outer layers of bone,
▪ Parathyroid hormone anchoring it securely.
(PTH) indirectly stimulates
osteoclasts by triggering
The endosteum lines the internal surfaces of
osteoblasts to release an
bones and is composed of a thin layer of
osteoclast-activating factor.
squamous cells with osteogenic potential.
▪ Calcitonin inhibits osteoclast
activity, reducing bone
resorption. dormancy
Types of Ossification
period
of

o Osteoclasts remain quiescent until
activated by metabolic or There are two primary processes by which
hormonal signals and are long- bone forms:
lived, modulating between active
and resting phases. 1. Intramembranous Ossification:
o Osteoclast differentiation is
highly dependent on signals from Definition: Bone formation occurs
osteoblasts, which are thought to directly in mesenchymal tissue
release factors that guide their without a cartilage precursor.
formation and activation.
 Location: Occurs in flat bones of Osteoblasts lay down bone
the skull (e.g., frontal, parietal, matrix on the remaining
occipital, and temporal bones). cartilage framework, forming
trabeculae.
The center of the cartilage
model (diaphysis) becomes the
Process: primary ossification center.
Later, similar processes occur
Mesenchymal cells in at the ends of the bone
connective tissue condense (epiphyses), forming
and differentiate into secondary ossification
osteoblasts. centers.
Osteoblasts begin secreting The remaining cartilage
bone matrix, forming between the diaphysis and
trabeculae (thin strands of epiphysis becomes the
bone matrix). epiphyseal plate (growth
The trabeculae grow and plate), allowing bones to grow
interconnect, forming a in length.
network of bone.
Osteoblasts trapped in the End result: Formation of long
matrix become osteocytes. bones with distinct diaphyses and
The bone matrix mineralizes, epiphyses.
forming woven bone (with
randomly oriented collagen Growth of Long Bones
fibers).
Over time, woven bone is Primary Ossification Center:
replaced by lamellar bone Long bone development begins with
(highly-ordered in layers). a primary ossification center in the
diaphysis (shaft).
End result: Formation of flat Chondrocytes in the center enlarge,
bones, which provide protection and and cartilage matrix calcifies. Blood
structure (e.g., skull, clavicle). vessels invade, bringing
osteoprogenitor cells which form
2. Endochondral Ossification: bone around the calcified cartilage.

Definition: Bone formation that Periosteal Bone Formation:
occurs by replacing a pre-existing Concurrently, bone forms beneath the
cartilage model with bone. periosteum, forming a periosteal
Location: Occurs in most long collar around the diaphysis.
bones (e.g., femur, tibia) and bones of This appositional growth continues
the vertebral column. to thicken the diaphysis.
Process:
Secondary Ossification Centers:
The cartilage model (hyaline Secondary ossification centers form
cartilage) grows in length and later in the epiphyses (ends of long
width. bones), typically after birth.
Chondrocytes in the center of These centers differ from the primary
the cartilage model enlarge center, as they lack periosteal bone
(hypertrophy), and the formation.
surrounding matrix begins to
calcify. Growth in Length:
The calcified cartilage is Bone lengthens due to continuous
invaded by blood vessels and interstitial growth at the epiphyseal
osteoprogenitor cells, which plates located between the epiphyses
differentiate into osteoblasts. and diaphysis.
 Chondrocytes in the epiphyseal osteogenic potential and
plates proliferate and align in begins depositing new bone,
columns. As they move toward the forming a bony callus
diaphysis, they mature and consisting of woven bone
hypertrophy, leading to calcification trabeculae, which starts to
and eventual replacement by bone. bridge the bone fragments.
3. Remodeling:
o The bone is remodeled over
time, where excess bone is
Long bone growth occurs at the resorbed, re-establishing the
epiphyseal plate through the marrow cavity and restoring
continuous replacement of cartilage by the bone to its normal shape
bone. The process is divided into four and function.
distinct zones:
1. Zone of Proliferation: Joints And Synovial Membranes
Chondrocytes divide, contributing to
elongation. Types of Joints: Bones are connected at
2. Zone of Maturation: Chondrocytes joints (articulations) which allow varying
enlarge. degrees of movement:
3. Zone of Hypertrophy:
Chondrocytes become vacuolated Synarthroses: Joints with little or no
and VERY large. movement.
4. Zone of Provisional Calcification: o Synostoses: Bone connects
Matrix calcifies around hypertrophic directly to bone (e.g., skull
chondrocytes. sutures).
5. Zone of Degeneration: o Synchondroses: Bones are
Chondrocytes die, osteoprogenitor connected by cartilage.
cells invade the calcified cartilage o Syndesmoses: Bones are
and deposit bone matrix, replacing connected by dense
the cartilage with bone. connective tissue (e.g.,
between long bones).
After puberty, the epiphyseal plate Diarthroses (Synovial Joints):
closes, and no further growth in length is These joints allow free movement.
possible.
The articular surfaces of bones are
Bone Repair covered with hyaline cartilage.
These joints are enclosed in a joint
1. Formation of Blood Clot capsule made of two layers:
(Hematoma): 1. Outer fibrous layer: Dense
o After a bone fracture, the first connective tissue, continuous
step in the repair process is with the periosteum.
the formation of a blood clot 2. Inner synovial layer
(hematoma) at the site of (synovium): A cellular layer
injury. This provides the that secretes synovial fluid.
foundation for healing.
2. Granulation Tissue and Callus Synovium:
Formation: The synovium lacks a continuous
o The hematoma is replaced by epithelial lining; instead, connective
granulation tissue, which tissue is exposed to the synovial
condenses into connective fluid.
tissue. This leads to the It contains two main types of cells:
formation of a 1. Fibroblast-like cells: Secrete
fibrocartilaginous callus collagen, proteoglycans, and
that temporarily stabilizes the lubricating molecules like
fracture site. hyaluronate and lubricin.
o The periosteum (bone's outer
layer) reactivates its
 2. Macrophages: Remove 3. What covers most of the outer surface of
debris from joint wear-and- bones, providing an osteogenic layer?
tear. a) Endosteum
Lymphocytes are found deeper b) Marrow
within the synovium. c) Periosteum
In some areas, synovium may rest d) Synovial membrane
directly on the fibrous layer or be
separated by loose connective or Answer: c) Periosteum
adipose tissue. Rationale: The periosteum is a specialized
connective tissue covering bone surfaces,
Synovial Fluid: except where articular cartilage is present

Synovial fluid is a transudate from 4. Which part of the bone is responsible for
blood capillaries, similar in its longitudinal growth during development?
composition to interstitial fluid. It a) Compact bone
contains hyaluronate and lubricin b) Epiphyseal plate
for lubrication. c) Bone marrow
Fluid exchange occurs via d) Perichondrium
transudation from blood capillaries
into the joint cavity, and movement Answer: b) Epiphyseal plate
through the synovium, facilitated by Rationale: The epiphyseal plate (growth
joint flexion. plate) allows for the elongation of bones
during growth
Aging: As individuals age, villi in the
synovium increase in size and number, and 5. Where is the articular cartilage of a long
small areas of cartilage may form within bone found?
them.
a) On the diaphysis
b) At the epiphysis
c) In the medullary cavity
QUESTIONS d) Surrounding the periosteum

1. Which type of bone consists of a three- Answer: b) At the epiphysis
Rationale: Articular cartilage covers the
dimensional lattice of branching bony
joint surfaces at the ends of long bones to
spicules?
facilitate smooth movement
a) Compact bone 6. Which component in bone matrix is
b) Cancellous (spongy) bone
responsible for hardness and strength?
c) Dense bone
d) Periosteum a) Collagen fibers
b) Glycoproteins
Answer: b) Cancellous (spongy) bone c) Hydroxyapatite crystals
Rationale: Spongy bone consists of d) Elastic fibers
trabeculae that create a labyrinthine structure
filled with bone marrow Answer: c) Hydroxyapatite crystals
Rationale: Bone hardness comes from
2. The primary centers of ossification in long hydroxyapatite, a crystalline form of
bones appear in which part of the bone? calcium phosphate
a) Epiphyses
b) Diaphysis 7. Which hormone increases bone resorption?
c) Metaphysis
d) Periosteum a) Calcitonin
b) Growth hormone
Answer: b) Diaphysis c) Parathyroid hormone
Rationale: Primary ossification centers form d) Insulin
in the diaphysis during fetal development
Answer: c) Parathyroid hormone
Rationale: Parathyroid hormone stimulates
osteoclast activity, leading to increased bone
resorption

8. Which of the following is absent where
tendons insert into bone?

a) Endosteum
b) Periosteum
c) Bone marrow
d) Compact bone

Answer: b) Periosteum
Rationale: The periosteum is absent where
tendons and ligaments insert directly into the
bone

9. What is the name of the structure formed
when periosteum becomes incarcerated in
bone matrix?

a) Sharpey’s fibers
b) Osteons
c) Canaliculi
d) Trabeculae

Answer: a) Sharpey’s fibers

Rationale: Sharpey's fibers anchor the
periosteum to the bone by penetrating the
bone matrix

10. In which area of long bones does
appositional growth contribute to bone
diameter?

a) Epiphyseal plate
b) Diaphysis
c) Marrow cavity
d) Periosteum

Answer: d) Periosteum

Rationale: Appositional growth increases
bone diameter by adding layers to the bone
surface from the periosteum