Histology of the Bone PDF

Summary

This presentation details the histology of the bone, including important features, composition, and types of bone. It also discusses the functions of bone cells, such as osteoblasts, osteocytes, and osteoclasts.

Full Transcript

Histology of the Bone
Dr.Abdulhussain Sahib
 OBJECTIVES
a. Important features.
b. Composition.
c. Its types of bone and covering.
d. Its cells and their function.
 Bone is a specialized connective tissue , has a rich
vascular supply composed of calcified
extracellular material, the bone matrix, and
following three major cell types :
1.Osteocytes
2.Osteoblasts
3.Osteoclasts
Function of the bone:
Support the body.
Protect many internal organs.
Act as the body’s Ca2+ reservoir.
 Osteoblasts

Osteoblasts Originating from mesenchymal stem cells.
Osteoblasts produce the organic components of bone
matrix, including:
Type I collagen fibers.
Proteoglycans.
Glycoproteins such as osteonectin.

Deposition of the inorganic components of bone also
depends on osteoblast activity.
 Active osteoblasts are located exclusively at the
surfaces of bone matrix, to which they are bound
by integrins, typically forming a single layer of
cuboidal cells joined by adherent and gap junctions.
When their synthetic activity is completed, some
osteoblasts differentiate as osteocytes entrapped in
matrix-bound lacunae, some flatten and cover the
matrix surface as bone lining cells, and the
majority undergo apoptosis.
 Matrix components are secreted at the cell
surface in contact with existing bone matrix,
producing a layer of unique collagen-rich
material called osteoid between the
osteoblast layer and the preexisting bone
surface.
This process of bone appositional growth is
completed by subsequent deposition of
calcium salts into the newly formed matrix.
 Important components of osteoid include type I
collagen, the protein osteocalcin, which binds
Ca2+ and matrix vesicles with enzymes
generating PO4-.
High concentrations of Ca2+ and PO4- ions cause
formation of hydroxyapatite crystals, whose
growth gradually calcifies the entire matrix.
 Osteocytes

These are the cells of mature bone.
They lie in the lacunae of bone, and represent
osteoblasts that have become ‘imprisoned’ in the
matrix during bone formation.
During the transition from osteoblasts to
osteocytes, the cells extend many long dendritic
processes, which also become surrounded by
calcifying matrix. The processes thus come to
occupy the many canaliculi, 250-300 nm in
diameter, radiating from each lacuna.
 In contrast to osteoblasts, osteocytes have eosinophilic
or lightly basophilic cytoplasm. This is to be correlated
with:
The fact that these cells have negligible secretory
activity
The presence of only a small amount of endoplasmic
reticulum in the cytoplasm.

Osteocytes are present in greatest numbers in
young bone, the number gradually decreasing
with age.
 Diffusion of metabolites between osteocytes and
blood vessels occurs through the small amount of
interstitial fluid in the canaliculi between the bone
matrix and the osteocytes and their processes.
Osteocytes also communicate with one another
and ultimately with nearby osteoblasts and bone
lining cells via gap junctions at the ends of their
processes.
 Functions:
1. They probably maintain the integrity of the
lacunae and canaliculi, and thus keep open the
channels for diffusion of nutrition through bone.
2. They play a role in removal or deposition of
matrix and of calcium when required.
 Osteoclasts
These are bone removing cells.
They are found in relation to surfaces where bone removal is taking
place (Bone removal is essential for maintaining the proper shape of
growing bone).
At such locations the cells occupy pits called resorption bays or
lacunae of Howship.
Osteoclasts are very large cells (20 to 100 μm or even more in
diameter).
They have numerous nuclei: up to 20 or more.
The cytoplasm shows numerous mitochondria and lysosomes
containing acid phosphatase.
 At sites of bone resorption the surface of an osteoclast shows many
folds that are described as a ruffled membrane.
Removal of bone by osteoclasts involves demineralization and
removal of matrix.
Bone removal can be stimulated by factors secreted by :
osteoblasts,
by macrophages,
 or by lymphocytes.
It is also stimulated by the parathyroid hormone.
 bone matrix

1.Inorganic salts ,about 65% of the dry weight of bone.
2.Organic ground substance and collagen fibres(35%).
The ground substance (or matrix) of bone consists
of an organic matrix in which mineral salts are
deposited.
 THE ORGANIC MATRIX

This consists of a ground substance in which collagen fibres are embedded.
The ground substance consists of :
Glycosaminoglycans.
Proteoglycans
Water.
Two special glycoproteins osteonectin and osteocalcin are present in
large quantity.
They bind readily to calcium ions and, therefore, play a role in
mineralization of bone.
Various other substances including chondroitin sulphates, phospholipids
and phosphoproteins are also present.
 The collagen fibres (Type I collagen) (They are sometimes
referred to as osteoid collagen).
The fibres are usually arranged in layers, running parallel to one
another.
Collagen fibres of bone are synthesized by osteoblasts.
The matrix of bone shows greater density than elsewhere
immediately around the lacunae, forming capsules around them,
similar to those around chondrocytes in cartilage.
The term osteoid is applied to the mixture of organic ground
substance and collagen fibres (before it is mineralized).
 THE INORGANIC IONS
The ions present are predominantly calcium and phosphorus (or
phosphate).
Others also present in significant amounts, include:
Magnesium.
Carbonate.
Hydroxyl.
Chloride.
Fluoride.
Citrate.
Sodium.
Potassium.
 Periosteum & Endosteum

External and internal surfaces of all bones are
covered by connective tissue of the periosteum
and endosteum, respectively.
The periosteum is an outer fibrous layer of dense
connective tissue, containing mostly bundled type
I collagen, but also fibroblasts and blood vessels.
Bundles of periosteal collagen, called perforating
(or Sharpey) fibers, penetrate the bone matrix
and bind the periosteum to the bone.
 Periosteal blood vessels branch and penetrate the bone,
carrying metabolites to and from bone cells.
The periosteum’s inner layer is more cellular and includes
osteoblasts, bone lining cells, and mesenchymal stem
cells referred to as osteoprogenitor cells.
With the potential to proliferate extensively and produce
many new osteoblasts, osteoprogenitor cells play a
prominent role in bone growth and repair.
 Internally the very thin endosteum covers
small trabeculae of bony matrix that
project into the marrow cavities.
The endosteum also contains
osteoprogenitor cells, osteoblasts, and bone
lining cells, but within a sparse, delicate
matrix of collagen fibers.
TYPES OF BONE
 Woven bone

Woven bone is nonlamellar and characterized by random disposition
of type I collagen fibers and is the first bone tissue to appear in
embryonic development and in fracture repair.
Woven bone is usually temporary and is replaced in adults by lamellar
bone, except in a very few places in the body, for example, near the
sutures of the calvaria and in the insertions of some tendons.
In addition to the irregular, interwoven array of collagen fibers, woven
bone typically has a lower mineral content (it is more easily
penetrated by x-rays) and a higher proportion of osteocytes than
mature lamellar bone.
These features reflect the facts that immature woven bone forms
more quickly but has less strength than lamellar bone.
 Lamellar bone

Most bone in adults, compact or cancellous, is organized
as lamellar bone, characterized by multiple layers or
lamellae of calcified matrix, each 3-7 μm thick.
The lamellae are organized as parallel sheets or
concentrically around a central canal.
In each lamella, type I collagen fibers.
 An osteon (or Haversian system) refers to the
complex of concentric lamellae, typically 100-
250 μm in diameter, surrounding a central canal
that contains small blood vessels, nerves, and
endosteum.
Between successive lamellae are lacunae, each
with one osteocyte, all interconnected by the
canaliculi containing the cells’ dendritic processes
 Processes of adjacent cells are in contact via gap
junctions, and all cells of an osteon receive
nutrients and oxygen from vessels in the central
canal.
The outer boundary of each osteon is a layer
called the cement line that includes many more
noncollagen proteins in addition to mineral and
collagen.
 Each osteon is a long, sometimes bifurcated,
cylinder generally parallel to the long axis of the
diaphysis.
Each has 5-20 concentric lamellae around the
central canal that communicates with the marrow
cavity and the periosteum.
Canals also communicate with one another through
transverse perforating canals (or Volkmann
canals) that have few, if any, concentric lamellae.
 All central osteonic canals and perforating canals
form when matrix is laid down around areas with
preexisting blood vessels.
Scattered among the intact osteons are numerous
irregularly shaped groups of parallel lamellae called
interstitial lamellae.
These structures are lamellae remaining from osteons
partially destroyed by osteoclasts during growth and
remodeling of bone.
 Compact bone

Compact bone (eg, in the diaphysis of long bones)
also includes parallel lamellae organized as multiple
external circumferential lamellae immediately
beneath the periosteum and fewer inner
circumferential lamellae around the marrow
cavity.
The lamellae of these outer and innermost areas of
compact bone enclose and strengthen the middle
region containing vascularized osteons.
Transverse section and longitudinal section through
compact bone to show
Haversian canals and the Volkmann's canal
 Cancellousbone (spongy bone)
Cancellous bone is made up of a meshwork of bony plates or rods
called trabeculae.
Each trabeculus is made up of a number of lamellae between
which there are lacunae containing osteocytes.
Canaliculi, containing the processes of osteocytes, radiate from
the lacunae.
The trabeculae enclose wide spaces that are filled in by bone
marrow.
They receive nutrition from blood vessels in the bone marrow.
The trabeculae are covered externally by vascular end steum
containing osteoblasts, osteoclasts and osteoprogenitor cells.