Bone Histology PDF

Summary

This document provides a detailed explanation of bone histology, encompassing the structure, composition, and different types of bone cells. It covers topics like osteoblasts, osteocytes, and osteoclasts, their roles in bone formation and resorption, the makeup of bone tissue, and the distinction between cortical and cancellous bone.

Full Transcript

BONE HISTOLOGY
Bone tissue (osseous tissue), which is also
called bone in the uncountable sense of that word, is
hard tissue, a type of specialised connective tissue.
It has a honeycomb-like matrix internally, which helps
to give the bone rigidity. Bone tissue is made up of
different types of bone cells.
Osteoblasts and osteocytes are involved in the
formation and mineralisation of bone; osteoclasts are
involved in the resorption of bone tissue.
 Modified (flattened) osteoblasts become the lining cells that
form a protective layer on the bone surface.
The mineralised matrix of bone tissue has an organic
component of mainly collagen called ossein and an inorganic
component of bone mineral made up of various salts.
Bone tissue is mineralized tissue of two types,
cortical bone and cancellous bone.
Other types of tissue found in bones include bone marrow,
endosteum, periosteum, nerves, blood vessels and cartilage.
 BONE STRUCTURE

Bone is not uniformly solid, but consists of a flexible
matrix (about 30%) and bound minerals (about 70%),
which are intricately woven and continuously
remodeled by a group of specialized bone cells.
Their unique composition and design allows bones to
be relatively hard and strong, while remaining
lightweight.
 Bone matrix is 90 to 95% composed of elastic collagen
fibers, also known as ossein,and the remainder is
ground substance.
The elasticity of collagen improves fracture resistance.
The matrix is hardened by the binding of inorganic
mineral salt, calcium phosphate, in a chemical
arrangement known as bone mineral, a form of
calcium apatite.
It is the mineralization that gives bones rigidity
 Bone is actively constructed and remodeled throughout life by
special bone cells known as osteoblasts and osteoclasts.
Within any single bone, the tissue is woven into two main
patterns, known as cortical and cancellous bone, each with a
different appearance and characteristics.
 BONE CORTEX
The hard outer layer of bones is composed of cortical bone, which
is also called compact bone as it is much denser than cancellous
bone.
It forms the hard exterior (cortex) of bones.
The cortical bone gives bone its smooth, white, and solid
appearance, and accounts for 80% of the total bone mass of an
adult human skeleton.
It facilitates bone's main functions—to support the whole body, to
protect organs, to provide levers for movement, and to store and
release chemical elements, mainly calcium.
 It consists of multiple microscopic columns, each called an osteon or
Haversian system.
Each column is multiple layers of osteoblasts and osteocytes around a
central canal called the osteonic canal.
Volkmann's canals at right angles connect the osteons together.
The columns are metabolically active, and as bone is reabsorbed and
created the nature and location of the cells within the osteon will
change.
Cortical bone is covered by a periosteum on its outer surface, and an
endosteum on its inner surface.
 The endosteum is the boundary between the cortical bone and
the cancellous bone.
The primary anatomical and functional unit of cortical bone is
the osteon.
 BONE TRABECULAE
Cancellous bone or spongy bone, also known
as trabecular bone, is the internal tissue of the
skeletal bone and is an open cell porous network that
follows the material properties of biofoams.
Cancellous bone has a higher
surface-area-to-volume ratio than cortical bone and it
is less dense.
This makes it weaker and more flexible.
 The greater surface area also makes it suitable for metabolic
activities such as the exchange of calcium ions.
Cancellous bone is typically found at the ends of long bones,
near joints, and in the interior of vertebrae.
Cancellous bone is highly vascular and often contains red
bone marrow where hematopoiesis, the production of blood
cells, occurs.
The primary anatomical and functional unit of cancellous
bone is the trabecula.
 The trabeculae are aligned towards the mechanical load
distribution that a bone experiences within long bones such as
the femur.
As far as short bones are concerned, trabecular alignment has
been studied in the vertebral pedicle.
Thin formations of osteoblasts covered in endosteum create an
irregular network of spaces, known as trabeculae.
 Within these spaces are bone marrow and
hematopoietic stem cells that give rise to platelets,
red blood cells and white blood cells.
Trabecular marrow is composed of a network of rod- and
plate-like elements that make the overall organ lighter and
allow room for blood vessels and marrow.
Trabecular bone accounts for the remaining 20% of total
bone mass but has nearly ten times the surface area of
compact bone.
 Osteoblast
Osteoblasts are mononucleate bone-forming cells.
They are located on the surface of osteon seams and make a protein
mixture known as osteoid, which mineralizes to become bone.
The osteoid seam is a narrow region of a newly formed organic matrix, not
yet mineralized, located on the surface of a bone.
Osteoid is primarily composed of Type I collagen.
Osteoblasts also manufacture hormones, such as prostaglandins, to act
on the bone itself.
The osteoblast creates and repairs new bone by actually building around
itself.
First, the osteoblast puts up collagen fibers.
These collagen fibers are used as a framework for the osteoblasts' work.
Osteoblast
 The osteoblast then deposits calcium phosphate which is
hardened by hydroxide and bicarbonate ions.
The brand-new bone created by the osteoblast is called
osteoid.
Once the osteoblast is finished working it is actually
trapped inside the bone once it hardens.
When the osteoblast becomes trapped, it becomes known
as an osteocyte.
Other osteoblasts remain on the top of the new bone and
are used to protect the underlying bone, these become
known as bone lining cells
 Osteocyte
Osteocytes are cells of mesenchymal origin and originate from osteoblasts
that have migrated into and become trapped and surrounded by a bone
matrix that they themselves produced.
The spaces the cell body of osteocytes occupy within the mineralized
collagen type I matrix are known as lacunae, while the osteocyte cell
processes occupy channels called canaliculi.
The many processes of osteocytes reach out to meet osteoblasts, osteoclasts,
bone lining cells, and other osteocytes probably for the purposes of
communication.
Osteocytes remain in contact with other osteocytes in the bone through gap
junctions—coupled cell processes which pass through the canalicular
channels.
Osteocyte
 Osteoclast
Osteoclasts are very large multinucleate cells that are responsible for the
breakdown of bones by the process of bone resorption.
New bone is then formed by the osteoblasts.
Bone is constantly remodeled by the resorption of osteoclasts and created
by osteoblasts.
Osteoclasts are large cells with multiple nuclei located on bone surfaces
in what are called Howship's lacunae (or resorption pits).
These lacunae are the result of surrounding bone tissue that has been
reabsorbed.
 Because the osteoclasts are derived from a monocyte stem-cell
lineage, they are equipped with phagocytic-like mechanisms similar
to circulating macrophages.
Osteoclasts mature and/or migrate to discrete bone surfaces.
Upon arrival, active enzymes, such as
tartrate-resistant acid phosphatase, are secreted against the mineral
substrate.
The reabsorption of bone by osteoclasts also plays a role in calcium
homeostasis
Osteoclast
 BONE COMPOSITION

Bones consist of living cells (osteoblasts and osteocytes)
embedded in a mineralized organic matrix.
The primary inorganic component of human bone is
hydroxyapatite, the dominant bone mineral, having the nominal
composition of Ca10(PO4)6(OH)2.
 The organic components of this matrix consist mainly of
type I collagen—"organic" referring to materials produced
as a result of the human body—and inorganic components,
which alongside the dominant hydroxyapatite phase, include
other compounds of calcium and phosphate including salts.
Approximately 30% of the acellular component of bone
consists of organic matter, while roughly 70% by mass is
attributed to the inorganic phase.
 The collagen fibers give bone its tensile strength, and the
interspersed crystals of hydroxyapatite give bone its
compressive strength.
These effects are synergistic.
The exact composition of the matrix may be subject to change
over time due to nutrition and biomineralization, with the
ratio of calcium to phosphate varying between 1.3 and 2.0
(per weight), and trace minerals such as magnesium, sodium,
potassium and carbonate also be found
 CARTILAGE
Cartilage is a resilient and smooth type of connective tissue. Semi-transparent and
non-porous, it is usually covered by a tough and fibrous membrane called
perichondrium.
In tetrapods, it covers and protects the ends of long bones at the joints as
articular cartilage, and is a structural component of many body parts including the
rib cage, the neck and the bronchial tubes, and the intervertebral discs.
In other taxa, such as chondrichthyans and cyclostomes, it constitutes a much greater
proportion of the skeleton.
It is not as hard and rigid as bone, but it is much stiffer and much less flexible than
muscle.
The matrix of cartilage is made up of glycosaminoglycans, proteoglycans, collagen
fibers and, sometimes, elastin.
It usually grows quicker than bone.
CARTILAGE
 Because of its rigidity, cartilage often serves the purpose of holding tubes
open in the body.
Examples include the rings of the trachea, such as the cricoid cartilage
and carina.
Cartilage is composed of specialized cells called chondrocytes that
produce a large amount of collagenous extracellular matrix, abundant
ground substance that is rich in proteoglycan and elastin fibers.
Cartilage is classified into three types — elastic cartilage, hyaline cartilage
, and fibrocartilage — which differ in their relative amounts of collagen
and proteoglycan.
 As cartilage does not contain blood vessels or nerves, it is
insensitive.
However, some fibrocartilage such as the meniscus of the knee has
partial blood supply.
Nutrition is supplied to the chondrocytes by diffusion.
The compression of the articular cartilage or flexion of the elastic
cartilage generates fluid flow, which assists the diffusion of
nutrients to the chondrocytes.
Compared to other connective tissues, cartilage has a very slow
turnover of its extracellular matrix and is documented to repair at
only a very slow rate relative to other tissues.
 TYPES OF CARTILEGE
There are three different types of cartilage: elastic (A), hyaline (B), and fibrous (C).
In elastic cartilage, the cells are closer together creating less intercellular space.
Elastic cartilage is found in the external ear flaps and in parts of the larynx.
Hyaline cartilage has fewer cells than elastic cartilage; there is more intercellular
space.
Hyaline cartilage is found in the nose, ears, trachea, parts of the larynx, and
smaller respiratory tubes.
Fibrous cartilage has the fewest cells so it has the most intercellular space.
Fibrous cartilage is found in the spine and the menisci
TYPES OF CARTILEGE