Histo - 1st Colloquium Annotated Slides PDF

Summary

This document contains notes on histology, specifically bone and cartilage. It details growth patterns, the structure and function of cartilage, and other relevant biological concepts.

Full Transcript

For Colloquium 2
HISTOLOGY COLLOQUIUM II GROWTH PATTERNS

Appositional growth (perichondrium):
1 - BONE AND CARTILAGE Chondrogenic cells ➞ chondroblasts ➞ chondrocytes

Interstitial growth (isogenous groups):
Both are specialized connective tissues, that resist mechanical Existing chondrocytes make more matrix
stresses

CHONDROCYTES
CARTILAGE
are specialized cells that produce and maintain the extracelular
matrix
Specialized avascular connective tissue; Chondrocytes are ovoid or rounded cells (10-30µm)
Cells (chondroblasts and chondrocytes) and extracellular Large nucleus with prominent nucleolus;
matrix ECM (composed of glycosaminoglycans and proteo- Rich network of rER, a well-developed Golgi, glycogen
glycans, which are intimately associated with the collagen (II, inclusions.
I) and elastic fibers embedded within the matrix);
Each cell is located into small, individual compartments –
lacunae; CARTILAGE CELLS
Cartilage has cell nests (isogenous groups);
Cartilage is covered with perichondrium (Perichondrium is not Chondrogenic cells: spindle-shaped cells, that are derived from
found - on articular surfaces and around fibrocartilage). mesenchymal cells, ovoid nucleus, few mitochondria and small
Cartilage supports but retains some flexibility. Golgi apparatus in cytoplasm.

Chondroblasts: ovoid cells with basophilic cytoplasm - rich
network of rER, a well-developed Golgi apparatus, numerous
mitochondria, an abundance of secretory vesicles in cytoplasm.

CARTILAGE ECM
Collagen is the major matrix protein. Type II collagen forms the
bulk of the fibrils, there are also type XI, X, IX. All those types
are specific for catilage.
Proteogycans – hyaluronic acid, chondroitin sulfate and
keratan sulfate are joined to a core protein to form a PG
HISTOGENESIS monomer. Each hyaluronic acid molecule is associated with
~80 PG monomers and form PG aggregates.
Mesenchymal cells retract their processes;
Congregates are called chondrification centers; Glycoproteins – tenascin, fibronectin.
These cells differentiate into chondroblasts and begin
secreting a matrix around themselves;
HYALINE CARTILAGE
The chondroblasts become entrapped in their own matrix in
small individual compartments called lacunae. Hyalin cartilage matrix is highly hydrated to provide diffusion of
small molecules. The matrix is amorphous, homogeneous in
Chondroblasts surrounded by matrix are chondrocytes, they
are still capable to cell division and production of ECM. This light microscope because the refractive index of the collagen
process or type of growth is called interstitial growth. fibrils and the ground substance is nearly the same.
The groups formed from one chondrocyte are known as
isogenous groups.

PERICHONDRIUM
Outer fibrous layer – type I collagen, fibroblasts, blood vessels
Inner cellular layer – chondrogenic (progenitor) cells
Perichondria are present in elastic and most hyaline cartilages,
but absent in fibrocartilage.

Functions:
Protection;
Nourishment (cells receive nutrients from blood vessels in
perichondrium by diffusion through the matrix);
Cartilage growth (the chondrogenic cells undergo division and
differentiate into chondroblasts, which begin to produce martix;
in this way cartilage growths from periphery and this process is
called appositional growth)

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THREE TYPES OF CARTILAGE
Variations in the amount and arrangement of extracellular
matrix components give rise to the three types of cartilage

Hyaline Cartilage
Trachea and bronchi
Nose
Ribs
Articulating surfaces of joints
Growth plates

Elastic Cartilage
Pinna of ear
Epiglottis

Fibrocartilage
Modified hyaline cartilage, covers articular surfaces of joints;
Intervertebral disks,
The free or articular surface has no perichondrium, but in
Pubic symphysis,
opposite surface is contact with bone;
In articular disks;
In adults it is 2 -5 mm thick
Where tendons attach to bones

HYALINE CARTILAGE
The most common cartilage of the body;
Perichondrium
Abundance of type II collagen and aggrecans in ECM. The
matrix of hyaline cartilage is composed of type II collagen,
proteoglycans, glycoproteins, and extracellular fluid.
Three types of cells are associated with cartilage:
chondrogenic cells, chondroblasts, and chondrocytes.
Prominent isogenous cell groups (8 – 16 cells)

Matrix is subdivided into two regions:
Territorial matrix - basophilic (poor in collagen and rich in
chondroitin sulfate);
Interterritorial matrix (more colagen type II and poorer in
proteoglycans than the territorial matrix)

Subdivide into zones:
superficial (tangential) zone – type II collagen fibers that are
arranged paralelly to the free surface
transitional zone – round chondrocytes are distributed within
the matrix
radial zone – chondrocytes and collagen fibers are arranged
into short columns perpendicular to the free surface;
calcified zone – calcified matrix and few chondrocytes

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ELASTIC CARTILAGE
Perichondrium is rich in elastic fibers; BONE
Abundance of elastic fibers in ECM;
Elastic cartilage contains type II collagen and abundant elastic Bone is connective tissue characterized by a mineralized
fibers scattered throughout its matrix, giving it more pliability. extracellular matrix
The chondrocytes are more abundant and larger;
Small isogenous cell groups (2-3 cells); Extracelular matrix:
Matrix is not divided in teritorries. Organic: Colagen I
Occasional lacunae display two chondrocytes, indicative of Non organic: hydroxiapatite
interstitial growth.
Periosteum:
Fibrous layer
Cellular layer

Cells:
Mesenchymal
Osteoprogenitor
Osteoblast
Osteocyte
Osteoclast - from monocyte

OSTEOPROGENITOR CELL
derived from embryonic mesenchymal cells and retain their
ability to undergo mitosis.
Located in the inner cellular layer of the periosteum,
FIBROCARTILAGE endosteum, lining Haversian canals;
Fibrocartilage is a tissue intermediate between dense regular Undergo mitotic division, have potentional to form osteoblasts
connective tissue and hyaline cartilage. or chondroblasts;
Perichondrium is absent; Spindle-shaped, oval nucleus, poorly developed organelles.
Wide interterritories; More active during the period of growth and regeneration.
Contains chondrocytes arranged in long rows separated by
collagen fibers;
Rich with type I and type II collagen (because it’s rich in OSTEOBLAST
collagen type I, the fibrocartilage matrix is acidophilic). derived from osteoprogenitor cells;
Fibrocartilage from intervertebral disc of the bull shows Responsible for the synthesis of the organic components of
chondrocytes aligned in parallel rows, lying singly in individual the bone matrix (including type I collagen, proteoglycans, and
lacunae. glycoproteins) and mineralization process.
The cytoplasm of these cells is not evident. Also possess receptors for parathyroid hormone;
The matrix contains thick bundles of collagen fibers. Osteoblasts are located on the surface of the bone in a sheet-
The adjacent areas reveal hyaline cartilage of the opposing like arrangement of cuboidal to columnar cells;
vertebrae, and dense connective tissue of the ligamentum Active cell – large nucleus with nucleolus, basophilic
longitudinale posterior. cytoplasm (rER, Golgi);
Processes form gap junctions with neighboring cells.

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 BONE MATRIX

50% dry weight is inorganic
OSTEOCYTES
The inorganic components of bone are crystals of calcium
Osteocytes are mature bone cells that derived from osteoblasts hydroxyapatite, composed mostly of calcium and phosphorus.
and are housed in lacunae within the calcified bony matrix.
Bone is storage site for calcium and phoshate;
Radiating out in all directions from the lacunae are narrow, Bone plays an important secondary role in the homeostatic
tunnel-like spaces (canaliculi) that house cytoplasmic regulation of blood calcium levels;
processes of the osteocyte.
Mineralization is a cell-regulated event;
Processes forming gap junctions between neighboring Alkaline phosphatase is important for mineralization.
osteocytes.
Nucleus is flattened; organic matrix
Cytoplasm is poor in organelles; Extracellular matrix: fibers + ground substance:
Secrete only substances for bone maintenance. Type I collagen (also small amount of type III and XIII)
Collagen molecules constitute about 90% of the total weight of
the bone matrix proteins;
proteoglycans: core protein with various numbers of attached
side chains of GAG – chondroitin sulfate, keratan sulfate;
glycoproteins: osteonectin, osteopontin, sialoprotein – mediate
cell attachment to ground substance and influence
mineralization;
bone-specific proteins: osteocalcin – binds calcium from blood
and stimulates bone remodeling;
growth factors and cytokines: small regulatory proteins – bone
morphogenetic proteins (BMPs).

PERIOSTEUM
connective tissue layer – is subdivided into 3 layers:
outer layer – connective tissue layer, nerves and blood vessels
OSTEOCLASTS
middle – rich with type I collagen fibers, what form also
Derived from fusion of mononuclear hemopoetic progenitor cells
Sharpey’s fibers, which penetrate into the bone
(monocytes);
inner cellular layer – osteoprogenitor (osteogenic) cells – have
These cells are responsible for bone resorption; ability to divide and become osteoblasts
Osteoclasts occupy Howship’s lacunae, that identify regions of Thus, from periosteum blood vessels enter into the bone canals
bone resorption;
and periosteum is responsible for bone growing of a thickness.
Osteoclasts are large, motile, multinucleated cells 150 μm in
diameter; they contain up to 50 nuclei and have an acidophilic
cytoplasm.
SHARPEY’S FIBRES
Marked acidophilia of cytoplasm - mitochondria, lysosoms; Collagen fibres from tendons and ligaments continues in
Osteoclasts resorb bone tissue by releasing protons and priosteum, and continuous as the collagen fibres of the bone
lysosomal enzymes;
matrix.
Ruffled border involved in resorption of bone – finger like
processes increasing surface for exocytosis of enzimes and
endocytosis of bone particles;
BONE TISSUE
Primary or immature or woven bone
The first bone to form during fetal development,
Characterized by irregular bundles of collagen;
No certain order for osteocytes;
Remain at sutures of the calvaria, insertions sites of tendons,
and alveoli of teeth.

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Secondary or mature or lamellar bone OSTEON OR HAVERSIAN SYSTEM
Composed of parallel (spongy bone) or concentric (compact Morphofunctional unit of compact bone;
bone) lamellae; Surrounded by cementing line composed mostly of calcified
Collagen fibers are arranged parallel each other within a given ground substance;
lamella; Consist of concentric lamellae;
Osteocytes in lacunae located between lamellae. Lamellae surrounding a Haversian canal, which contains the
vascular and nerve supply of osteon;
The collagen fibers are parallel in one lamellae but in different
COMPACT AND SPONGY BONE direction in adjacent lamellae.

SPONGY BONE
Lamellae are arrange in trabeculae or spicules; red bone
marrow between spicules.

LAMELLAR SYSTEM OF COMPACT BONE
Compact bone is composed of lamellae arranged in four
lamellar systems:
Inner circumferential lamellae,
Outer circumferential lamellae,
Osteons (Haversian lamella),
Interstitial lamella.

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VOLKMAN’S CANALS
Perforating canals in lamellar bone through blood vesels and
nerves travel from periosteum to Haversian canals;
They also connect Haversian canals to one another;
Volkmann’s canals are not surrounded by concentric lamallae.

STRUCTURE OF LONG BONE
Long bones have middle region - diaphysis and 2 expanded
ends – epiphysis.
The articular surface is covered with articular cartilage.
The small zone between diaphysis and epiphysis is called
metaphysis.
Large central cavity filled with bone marrow is named marrow
cavity.
Almost all thickness of the middle bone region is compact. At
the ends of the bone spongy bone is extensive.
Outer surface is covered with periosteum, then follow outer
circumferential lamellae and wide zone of osteons, inner
circumferential lamellae, covered from marrow cavity side with
endostium.

CALCIUM
Parathyroid hormone (PTH) acts on the bone to raise low
blood calcium levels to normal;
Calcitonin acts to lower elevated blood calcium levels to
normal.

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HISTOLOGY COLLOQUIUM II

2 - BONE GROWTH
Bone Tissue grows ONLY by Appositional Growth
Bone only grows appositionally
Bone does not grow by interstitial growth
Long bones need interstitial growth of cartilage to increase
their length

Bone as an organ grows two ways:

Intramembranous Ossification When osteoblasts become trapped in their lacunae these are
From Mesenchymal cells known as osteocytes.
Example: flat bone of skull Embryonic connective tissue – mesenchyme is highly
vascular, bony trabeculae are anastomosing, and appear to be
Endochondral Ossification acidophilic due to the presence of collagen.
Involves erosion of a cartilage model The large, multinuclear cells, osteoclasts, appear at the
Osteoprogenitor cells, osteoblasts and osteocytes perform the surface of bone trabeculae in the process of bone resorption.
same functions as the similar cells in intramembranous Within the bony trabeculae are osteocytes in their lacunae.
ossification Osteoid may be seen on the margins of the bony trabeculae.

INTRAMEMBRANOUS OSSIFICATION

All roofing bones of the Skull:
Frontal bone
Parietal bones
Occipital bone
Temporal bones
Mandible
Clavicle

Mesenchymal cells differentiate into osteoblasts – the bone-
forming cells, which begin synthesis and secretion of ground
substance and collagen (called osteoid) at multiple centres of
ossification. Osteoid calcifies to form bone.
Calcification quickly follows osteoid formation, and osteoblasts
trapped in their matrices in lacunae become osteocytes. They
are responsible for maintenance of the newly formed bone
tissue. The processes of these osteocytes are also surrounded
by forming bone, establishing a system of canaliculi.
The remaining osteoblasts continue the bone deposition
process at the bone surface.
This newly bone appears as spicules or trabeculae.
Continuous mitotic activity of mesenchymal cells provides a
supply of undifferentiated osteoprogenitor cells, which form
osteoblasts.
The bone then undergoes progressive remodelling into
lamellar bone by osteoclastic resorption and osteoblastic
deposition to form mature compact or trabecular bone.
The primitive mesenchyme remaining in the network of
developing bone differentiates into bone marrow.
Regions of the mesenchymal tissues that remain uncalcified
differentiate into the periosteum and endosteum of developing
bone.
The spongy bone deep to the periosteum and the periosteal
layer of the dura mater of flat bones are transformed into
compact bone.

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ENDOCHONDRAL OSSIFICATION The subperiosteal bone collar is formed of primary bone
(intramembranous bone formation)!!!
Developing bones are deposited as a hyaline cartilage model
and then this cartilage is replaced by bone tissue. All bones of
the body except: roofing bones of the skull, mandible, clavicle.

CARTILAGE MODEL
Miniature hyaline cartilage model formed in region of
developing embryo where bone is to develop.
Cartilage is covered with perichondrium.

BONE COLLAR FORMED BY INTRAMEMBRANOUS
OSSIFICATION
In the middle of diaphysis perichondrium becomes richly
vascularised;
Vascularization of perichondrium changes it to periosteum;
Chondrogenic cells become osteoprogenitor cells;
From osteoprogenitor cells starts differentiation of osteoblasts;
Osteoblasts secrete bone matrix
And form bone collar (=perihondral bone spicule) on the
surface of cartilage;
Bone colar is surrounded by periosteum.

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HYPERTROPHY OF CARTILAGE PRIMARY CENTRE OF OSSIFICATION
The bone collar prevents the diffusion of nutrients to the The bone collar becomes thicker and grows in each direction
chondrocytes; from the midriff of the diaphysis toward the epiphyses;
Chondrocytes within the diaphysis core hypertrophy and die The cartilage of the diaphysis is replaced by bone;
(apoptosis); Exept epiphyeal plates, which are responsible for the growth
With the death of the chondrocytes much of the matrix breaks
down, appear cavities; FORMATION OD SECONDARY CENTRE OF OSSIFICATION
Rest of matrix become calcified. Secondary centers of ossification begin to form at the
epiphysis;
Process starts around birth. For larger bones before and for
smaller after;
Process begins in same way as at primary center, except that
there is no bone collar; osteoblasts lay down bone matrix on
calcified cartilage scaffold.

EROSION OF CARTILAGE AND VASCULAR INVASION
(PRIMARY OSSIFICATION CENTRE)
Osteoclasts make holes in bone collar;
Blood vessels growth through the bony collar and vascularize
the cavity and forming primary center of ossification; BONE GROWTH IN LENGTH
Osteoclasts continue erosion of calcified cartilage matrix; It depends on epiphyseal plate.
Holes permit osteoprogenitor cells and blood vessels invade Chondrocytes proliferate and forming columns.
cartilage model;
Replacement by bone take place at the diaphyseal side.
With blood vessels enter hemopoetic cells un stem cells for There are 5 zones in epiphyseal plate.
forming reticular tissues. Both are necessary for forming red
bone marrow.
Interstitial Growth of Cartilage causes model to increase in
length
MIXED OR ENDOCHONDRAL SPICULES
Cell nests form, then cells secrete matrix as they mature
In primary ossification center still exist calcified cartilage septa;
Bone matrix laid down on septa of calcified cartilage forms the
complex – endochondral bone.
Endochondral bone is cartilage/bone complex into primary
bone marrow cavity.
Osteoclasts begin resorbing the complex enlarging the morrow
cavity.
The bone matrix becomes calcified to form a calcified
cartilage/calcified bone complex. This complex can be
appreciated in routinely stained histological sections because
calcified cartilage stains basophilic, whereas calcified bone
stains acidophilic

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 GROWTH IN THICKNESS
Bone can grow in thickness or diameter only by appositional
growth. The steps in these process are:
Periosteal cells differentiate into osteoblasts which secrete
collagen fibers and organic molecules to form the matrix.
Ridges fuse and the periosteum becomes the endosteum.
New concentric lamellae are formed.
Osetoblasts under the periosteum form new circumferential
lamellae.

EPIPHYSEAL PLATE Only by appositional growth at the bone’s surface
Periosteal cells differentiate into osteoblasts and form bony
ridges and then a tunnel around periosteal blood vessel.
Concentric lamellae fill in the tunnel to form an osteon.

Once the epiphyseal plate closes (disappears) the bone has
reached it full length

FACTORS AFFECTING BONE GROWTH

Minerals
Calcium - Makes bone matrix hard
Phosphorus - Makes bone matrix hard
Magnesium - Deficiency inhibits osteoblasts

Vitamins
Vitamin A - Controls activity, distribution, and coordination of
osteoblasts/osteoclasts
Vitamin B12 - May inhibit osteoblast activity
Vitamin C - Helps maintain bone matrix, deficiency leads to
decreased collagen production which inhibits bone growth and
repair; (scurvy - disorder due to a lack of Vitamin C)
Vitamin D (Calcitriol) - Helps build bone by increasing calcium
absorption. Deficiencies result in “Rickets” in children

Hormones
Human Growth Hormone - Promotes general growth of all
1. Zone of resting cartilage - anchors growth plate to bone body tissue and normal growth in children
2. Zone of proliferating cartilage - rapid cell division (stacked Insulin-like Growth Factor - Stimulates uptake of amino acids
coins) and protein synthesis
3. Zone of hypertrophic cartilage - cells enlarged & remain in Insulin - Promotes normal bone growth and maturity
columns Thyroid Hormones - Promotes normal bone growth and
4. Zone of calcified cartilage - thin zone, hypertrophied maturity
chondrocytes die, and cartilage matrix becomes calcified Estrogen and Testosterone - Increases osteogenesis at
5. Zone of ossification (erosion and vascular invasion) - puberty and are responsible for gender differences of
osteoclasts removing matrix; osteoblasts & capillaries move skeletons
in to create bone over calcified cartilage

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BONE REMODELLING HEALING IN BONE
Vitamin D
Nutrition
Physical activity
Age, hormones
PTH, PHRP
IL1, TNF,TGF-β
5-10% bone / yea

CALCIUM HOMEOSTASIS

Repair of a fractured bone by formation of new bone tissue
through periosteal and endosteal cell proliferation.

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HISTOLOGY COLLOQUIUM II

3 - MUSCLE TISSUE

ULTRASTRUCTURE OF SMOOTH MUSCLE CELLS
STRIATED MUSCLE - regularly arranged contractile units; actin and myosin contractile filaments!
Striated muscle cells display characteristic alternations of light intermediate filaments of desmin! (also vimentin in vascular
and dark cross-bands, which are absent in smooth muscle smooth muscle)
membrane associated and cytoplasmic dense bodies
Skeletal Muscle - long, cylindrical multinucleated muscle fibers containing α actinin (similar to Z lines)
with peripherally placed nuclei. Contraction is typically quick relatively active nucleus (smooth muscle cells make collagen,
and vigorous and under voluntary control. Used for elastin, and proteoglycans)
locomotion, mastication, and phonation. Each smooth muscle cell is surrounded by an external lamina

Cardiac Muscle - elongated, branched cells with a single Between individual muscle cells and between fasciculi is a
centrally placed nucleus and intercalated discs at the ends. network of supporting collagenous tissue; this is well
Contraction is involuntary, vigorous, and rhythmic. demonstrated in micrograph in which the collagen is stained
blue.
SMOOTH MUSCLE - possesses contractile machinery, but it is
irregularly arranged (thus, non-striated). Cells are fusiform with a
central nucleus. Contraction is involuntary, slow, and long
lasting.

microtubules (curved arrows)
actin filament (arrowheads)
intermediate filaments
dense bodies (desmin/vimentin plaques)
caveoli (membrane invaginations & vesicular system
contiguous with SER –functionally analogous to sarcoplasmic
SMOOTH MUSCLE
reticulum)

Fusiform or spindle-shaped, non-striated cells
Single, centrally-placed nucleus
Smooth muscular cells are present in bundles
Cell junctions – gap junctions
Contraction is non-voluntary
It is regulated by the autonomic nervous system, hormones
(such as bradykinins), and local physiological conditions.
Smooth muscle is found in the walls of hollow viscera (e.g., the
gastrointestinal tract, some of the reproductive tract, and the
urinary tract), walls of blood vessels, larger ducts of compound
glands, respiratory passages, and small bundles within the
dermis of skin.

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SMOOTH MUSCLE CONTRACTION STRIATED MUSCLE
also Ca+ dependent, but mechanism is different than striated
muscle. each skeletal muscle fiber is long, cylindrical, multinucleated
with peripherally placed nuclei, and striated.
1. Ca2+ ions released from caveloae/SER and complex with Contraction is typically quick and vigorous and under voluntary
calmodulin control.
2. Ca2+-calmodulin activates myosin light chain kinase The highly developed functions of the cytoplasmic organelles
3. MLCK phosphorylates myosin light chain of muscle cells has led to the use of a special terminology for
4. Myosin unfolds & binds actin; ATP-dependent contraction some muscle cell components: plasma membrane or
cycle ensues. plasmalemma = sarcolemma; cytoplasm = sarcoplasm;
5. Contraction continues as long as myosin is phosphorylated. endoplasmic reticulum = sarcoplasmic reticulum.
6. “Latch” state: myosin head attached to actin de- all muscle cells have basal laminae!
phosphorylated causing decrease in ATPase activity –
myosin head unable to detach from actin (similar to “rigor
mortis” in skeletal muscle).

Triggered by:
Voltage-gated Ca+ channels activated by depolarization
Mechanical stimuli
Neural stimulation
Ligand-gated Ca+ channels

Epimysium - dense irr. CT
Perimysium - less dense irr. CT
Endomysium - basal lamina and reticular fibers

The mechanism of smooth muscle contraction is as follows:
Thin filaments of actin are associated with tropomyosin.
Thick filaments composed of myosin only bind to actin if one
chain is phosphorylated.
Ca2+ ions in the cytosol of smooth muscle cells cause
contraction as in striated muscle, but the control of Ca2+ ion
movements is different. In relaxed smooth muscle, free Ca2+
ions are normally sequestered in sarcoplasmic reticulum
throughout the cell.
On membrane excitation, free Ca2+ ions are released into the
cytoplasm and bind to a protein called calmodulin (a calcium-
binding protein). The calcium-calmodulin complex then
activates an enzyme called myosin light-chain kinase, which The entire muscle is surrounded by epimysium, a dense
phosphorylates myosin and permits it to bind to actin. irregular collagenous connective tissue. Perimysium, a less
dense collagenous connective tissue derived from epimysium,
Actin and myosin subsequently interact by filament sliding to
produce contraction in a similar way to that for skeletal muscle. surrounds bundles (fascicles) of muscle fibers. Endomysium,
composed of reticular fibers and an external lamina (basal
Contraction of smooth muscle can be modulated by surface
receptors activating internal second messenger systems. lamina), surrounds each muscle fiber!
Expression of different receptors allows smooth muscle in
different sites to respond to several different hormones.
Compared with skeletal muscle, smooth muscle is able to
maintain a high force of contraction for very little ATP usage.

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 ORGANISATION OF SKELETAL MUSCLE FIBRES - THE
SACROMERE

Contractile unit of striated muscle:

Structures between Z lines:
2 halves of I bands (Actin only; thin filaments only)
A band (Actin and Myosin; thick & thin filaments)
H zone (Myosin only; thick filaments only)
M line (Mittelscheibe, Ger. “middle of the disc”)
Myofilaments
Actin
Myosin

Other structural proteins:
Titin (myosin-associated)
Multi-nucleated and striated Nebulin (actin-associated)
A bands - anisotropic (birefringent in polarized light) Myomesin (at M line)
I bands - isotropic (do not alter polarized light) α actinin (at Z line)
Z lines (Zwischenscheiben, Ger. “between the discs”) Desmin (Z line)
H zone (hell, Ger. “clear”) Vimentin (Z line)
Dystrophin (cell membrane)
The region of the myofibril between two successive Z disks,
known as a sarcomere, is 2.5 μm in length and is considered
the contractile unit of skeletal muscle fibers!
The dark bands are known as A bands (anisotropic with
polarized light) and the light bands as I bands (isotropic with
polarized light).
The center of each A band is occupied by a pale area, the H
band, which is bisected by a thin M line. Each I band is
bisected by a thin dark line, the Z disk (Z line).
During muscle contraction, the various transverse bands
behave characteristically. The I band becomes narrower, the H
band is extinguished, and the Z disks move closer together
(approaching the interface between the A and I bands), but the
width of the A bands remains unaltered.

I H M A

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T-TUBULE SYSTEM Ca2+ Stimulates Myosin-Actin Binding and Initiates Contraction:
Propagation of the Signal and Release of Ca2+ Myosin-actin binding inhibited by TnI
TnC binds Ca2+ (if present) and induces release of TnI from
T (transverse) Tubules actin
run perpendicular (transversely) to myofibrils Myosin binds actin; hydrolysis of ATP induces power stroke
conduct membrane depolarization deep into fibers Actin filaments move relative to myosin

Sarcoplasmic Reticulum
smooth ER
site of Ca2+ storage & release
terminal cisternae abut T-tubules forming triads when
myofibrils are viewed in longitudinal section

T tubules and sarcoplasmic reticulum are essential components
involved in skeletal muscle contraction!

CONTRACTION CYCLE
1. ATP binds myosin – myosin releases actin
2. ATP hydrolysis induces conformational change – myosin
head cocks forward 5nm (ADP+Pi remain bound to myosin).
3. Myosin binds weakly to actin, causing release of Pi
4. Release of Pi induces strong binding, power stroke, and
release of ADP
5. Myosin remains bound to actin if no more ATP is available
NEUROMUSCULAR JUNCTION (rigor conformation)
Synapse:
Action potential (AP) stimulates release of acetylcholine from
axon terminal into synaptic cleft
Acetylcholine in synaptic cleft binds Na+ channel receptors –
initiates sarcolemma AP

Signal Propagation:
T (transverse) Tubules
Run perpendicular (transversely) to myofibrils
Conduct membrane depolarization deep into fibers

Intracellular Ca2+ release:
Sarcoplasmic Reticulum
Smooth ER, site of Ca2+ storage
Voltage-gated channels in SR detect membrane depolarization
in T-tubule and release Ca2+ SLIDING FILAMENT THEORY
Muscle fibers are composed of many contractile units
(sarcomeres)
Changes in the amount of overlap between thick and thin
filaments allows for contraction and relaxation of muscle fibers
Many fibers contracting together result in gross movement
Note: Z lines move closer together; I band and H band
become smaller during contraction

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TYPES OF FIBRES From the atrioventricular node, the impulse is passed along a
specialised bundle of conducting fibres, the atrioventricular
Type I fibres (red fibres) bundle (of His), which initially divides into right and left bundle
Red muscles contain predominantly (but not exclusively) red branches, that then (halfway down the interventricular septum)
muscle cells. Red muscle fibres are comparatively thin and become Purkinje fibres which run immediately beneath the
contain large amounts of myoglobin and mitochondria. Red endocardium before penetrating the myocardium.
fibres contain an isoform of myosin with low ATPase activity,
i.e. the speed with which myosin is able to use up ATP.
Contraction is therefore slow. Red muscles are used when PURKINJE FIBRES (CELLS)
sustained production of force is necessary, e.g. in the control are larger than cardiomiocytes and have a pale staining central
of posture. area with most of the red-staining myofibrils around the
periphery of the cell.
Type II fibres
White muscle cells, which are predominantly found in white
muscles, are thicker and contain less myoglobin. ATPase
activity of the myosin isoform in white fibres is high, and
contraction is fast. Type IIA fibres (red) contain many
mitochondria and are available for both sustained activity and
short-lasting, intense contractions. Type IIB/IIX fibres (white)
contain only few mitochondria. They are recruited in the case
of rapid accelerations and short lasting maximal contraction.
Type IIB/IIX fibres rely on anaerobic glycolysis to generate the
ATP needed for contraction.

CARDIAC MUSCLE

1. Purkinje fibers, 2. endocardium, 3. myocardium

Muscle cells of the atria are somewhat smaller than those of the
ventricles. These cells also house granules (especially in the
right atrium) containing atrial natriuretic peptide!, a substance
that functions to lower blood pressure. This peptide acts by
decreasing the capabilities of renal tubules to resorb (conserve)
sodium and water.

HEART - CONDUCTIVE SYSTEM
The coordinated contraction of the heart is largely effected by
a specialised conducting system of modified cardiac muscle
fibres.
The initial impulse originates spontaneously in the sino-atrial
node situated in the right atrial wall near the entry of the
superior vena cava, but the impulse rate is controlled by the
autonomic nervous system.
The impulse passes through the muscle of the atria, causing
them to contract, and reaches the atrioventricular node in the
medial wall of the right atrium.

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MUSCLE REGENERATION AND GROWTH

Skeletal Muscle
Increase in size (hypertrophy)
Increase in number (regeneration/proliferation)
Satellite cells are proposed source of regenerative cells

Smooth Muscle
Increase in size (hypertrophy)
Increase in number (regeneration/proliferation)
Smooth muscle cells are proliferative
(e.g. uterine myometrium and vascular smooth muscle)
Vascular pericytes can also provide source of smooth muscle

Heart Muscle
Increase in size (hypertrophy)
Formerly thought to be non-proliferative
Post-infarction tissue remodeling by fibroblasts (fibrosis/
scarring)
New evidence suggests mitotic cardiomyocytes and re-
generation by blood or vascular-derived stem cells

6/6
HISTOLOGY COLLOQUIUM II

4 - BLOOD VESSELS
CARDIOVASCULAR AND LYMPH-VASCULAR SYSTEM
Transport systems that convey blood and lymph throughout
the body
Heart, blood vessels and lymphatic vessels
Cardiovascular sytem: Systemic and pulmonary circulation

fig. middle sized artery

Walls of blood vessels are composed of three layers: the
tunica intima, the tunica media, and the tunica adventitia.
The innermost layer, the tunica intima, is composed of a single
layer of flattened, squamous endothelial cells, which form a
tube lining the lumen of the vessel, and the underlying
subendothelial connective tissue.
The intermediate layer, the tunica media, is composed mostly
of smooth muscle cells oriented concentrically around the
lumen.
The outermost layer, the tunica adventitia, is composed mainly
of fibroelastic connective tissue arranged longitudinally.
The tunica intima houses in its outermost layer the internal
CARDIOVASCULAR SYSTEM elastic lamina, a thin band of elastic fibers that is well
Maintain blood flow to all organs in the body developed in medium-sized arteries.
Adjust the flow to organs as needs change The outermost layer of the tunica media houses another band
Provide enough flow and pressure for capillary exchange to of elastic fibers, the external elastic lamina, although it is not
occur distinguishable in all arteries.
Have enough blood pressure after capillary beds for blood to The deeper cells of the tunica media and tunica adventitia are
return to the heart nourished by the vasa vasorum.

TUNICA INTIMA
The endothelial cells (simple squamous epithelium) lining the
lumen of the blood vessel rest on a basal lamina.
Endothelial cells not only provide an exceptionally smooth
surface but also function in secreting types II, IV, and V
collagens, lamin, endothelin, nitric oxide, and von Willebrand
factor.
A subendothelial layer lies immediately beneath the
endothelial cells. It is composed of loose connective tissue and

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 a few scattered smooth muscle cells, both arranged
longitudinally.
Beneath the subendothelial layer is an internal elastic lamina
that is especially well developed in muscular arteries.
Separating the tunica intima from the tunica media, the internal
elastic lamina is composed of elastin, which is a !fenestrated!
sheet that permits the diffusion of substances into the deeper
regions of the arterial wall to nourish the cells there.

TUNICA MEDIA
The tunica media is the thickest layer of the blood vessel. The
concentric cell layers forming the tunica media comprise
mostly helically arranged smooth muscle cells.
Interspersed within the layers of smooth muscle are some
elastic fibers, type III collagen, and proteoglycans. The fibrous
elements form lamellae within the ground substance secreted
by smooth muscle cells.
MUSCULAR ARTERY
Regulate the flow of blood to various organs by contraction of
Larger muscular arteries have an external elastic lamina,
which is more delicate than the internal elastic lamina and smooth muscle, which constricts vessel
separates the tunica media from the overlying tunica
adventitia. T.intima: Endothelium, basal lamina, subendothelial layer, thick
internal elastic lamina
Capillaries and postcapillary venules do not have a tunica
media; in these small vessels, pericytes replace the tunica T.media: Up to 40 layers of smooth muscle cells; thick external
media elastic lamina
T.adventitia:Thin layer of fibroelastic connective tissue; vasa
TUNICA ADVENTITIA vasorum not very prominent; lymphatic vessels, nerve fibers
Covering the vessels on their outside surface is the tunica
adventitia, composed mostly of fibroblasts, type I collagen Muscular arteries frequently have both internal and external
fibers, and longitudinally oriented elastic fibers. Contain vasa elastic laminae.
vasorum, nerve fibers.
This layer becomes continuous with the connective tissue
elements surrounding the vessel. ARTERIOLE
Arteries with a diameter of less than 0.1 mm are considered to
be arterioles.
ELASTIC ARTERY T.intima: Endothelium; basal lamina, subendothelial layer not
OR CONDUCTING ARTERY very prominent; some elastic fibers instead of a defined
internal elastic lamina
Tunica intima: Endothelium, basal lamina, subendothelial T.media: One or two layers of smooth muscle cells
layer, incomplete internal elastic lamina T.adventitia: Loose connective tissue, nerve fibers
Tunica media: 40 to 70 fenestrated elastic membranes;
smooth muscle cells interspersed between elastic membranes;
thin external elastic lamina; vasa vasorum in outer half
Tunica adventitia: Thin layer of fibroelastic connective tissue,
vasa vasorum, lymphatic vessels, nerve fibers
Examples: Aorta, pulmonary, brachiocephalic, subclavian,
common carotid, common iliac arteries arteries
Elastic arteries have many elastic laminae and thus laminae
are not referred to as “internal” or “external”.

Thick muscular walls relative to lumen size
By definition: 1-3 layers of smooth muscle
Regulate flow to the capillary beds & reduces pressure

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COMPANION ARTERIOLE AND VENULE
Smallest venules: Postcapillary (Pericytic)venules
Very thin walls
Pericytes
Very permeable
Easiest to identify when comparing venule with companion
arteriole
Site of exchange of cells and molecules between blood and
tissues

CAPILLARY
capillaries composed of a single layer of endothelial cells, are
the smallest blood vessels.
Pericytes are located along the outside of the capillaries and
small venules, and appear to be surrounding them.
exvchange vessels
4-10 μm diameter
STRUCTURES OF CAPILLARIES REFLECT THEIR
FUNCTION

Continuous capillaries have no pores or fenestrae in their walls!
Endothelial cells connected by tight junctions and not very
leaky
Numerous pinocytotic vesicles for transport across
endothelium

Fenestrated capillaries possess pores (fenestrae) in their walls
that are covered by pore diaphragms.
Fenestrations (small pores) within cells that facilitate exchange
across them
Found in: endocrines, kidney and mucosa of GI
Most fenestrations have diaphragms except in the kidney

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Discontinuous sinusoidal capillaries (or Sinusoids)
Sinusoidal capillaries may possess discontinuous endothelial
cells and basal lamina and contain many large fenestrae
without diaphragms
HUGE transcellular pores (0.5-3 μm)
Fenestrations (50-80 nm)
Specialized cells (liver)
Gaps between endothelial cells
+/- Basal lamina
Larger diameter lumen

VEIN
are classified into three groups on the basis of their diameter
and wall thickness: small (10mm)
Have large lumen relative to thickness of the wall;
Do not have ext&int elastic laminae
Little muscle in the tunica media (thin tunica media) compared
to their companion arteries
Tunica adventitia is most prominent layer
Have valves to prevent backflow
Wall structure is more variable than in arteries
cardiac muscle in t. adventitia (vena cava and pulmonary
veins)
Irregular shaped lumen
Thin tunica media
LYMPATHIC VESSELS
Lymphatic vessels drain excess fluid from the tissues. They
begin as blind lymphatic capillaries which take up excess
tissue fluid. Lymph vessels contain no RBCs, but have some
lymphocytes.
Lymph flows through large and larger collecting vessels, with
histology resembling that of venules and veins (with valves).
Occasional lymph nodes are interposed in the lymphatic
vessel pathway, so the lymph flows through them
(macrophages monitor the lymph, lymphocytes may engage in
immune activities).
Lymph reaches the thoracic duct and right lymphatic duct, both
of which empty lymph into veins at the base of the neck, thus
restoring the fluid and any content (proteins, etc.) to the blood.

Location
Most of the body
Wall structure of veins is more variable than in arteries Not present in CNS and a few other places (bone)

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Functions
Return both tissue fluid and escaped plasma proteins to the
blood (from interstitial tissue spaces)
Circulate antibodies and return lymphocytes to blood

Open circulatory system

Lymph flows unidirectionally from peripheral tissue to heart.
Begin as blind-ending capillaries that converge
larger lymphatic vessels
2 lymphatic ducts (thoracic duct, right lymphatic duct)
venous circulation at junction of internal jugular and
subclavian veins
Lymph is filtered in lymph nodes

Lymphatic capillaries
Thin endothelium
NO tight junctions
Incomplete basal lamina
Lacteal is a lymphatic capillary in intestine

Large lymph vessels
resemble veins
many valves

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HISTOLOGY COLLOQUIUM II MAJOR PLASMA PROTEINS
Albumin- Maintain colloid osmotic pressure; transport insoluble
metabolites
5 - BLOOD AND BONE MARROW Globulins (α and β)- Transport metal ions, protein-bound lipids,
lipid-soluble vitamins
Globulins (γ) - Antibodies of immune defense
Complement proteins - Destruction of microorganisms and
BLOOD
initiation of inflammation
Clotting proteins - Formation of blood clots
Blood is a bright to dark red, viscous, slightly alkaline fluid (pH,
Plasma lipoproteins - Transport of triglycerides and cholesterol
7.4) that accounts for approximately 7-8% of the total body
to/from liver
weight.
The total volume of blood of an average adult is about 5 L, and FORMED ELEMENTS
it circulates throughout the body within the confines of the
Erythrocytes (red blood cells, RBC)
circulatory system.
Platelets (thrombocytes)
Blood is a specialized connective tissue composed of formed
Leukocytes (white blood cells, WBC)
elements - red blood cells (RBCs; erythrocytes), white blood
Granulocytes (with specific granules)
cells (WBCs; leukocytes), and platelets - suspended in a fluid
Neutrophil
component (the extracellular matrix), known as plasma.
Eosinophil
Basophil
BLOD FUNCTIONS
Agranulocytes (without specific granules)
1. transport of nutrients, oxygen, wastes, and carbon dioxide to
Lymphocyte (B-cell, T-cell)
and from the tissues
Monocyte
2. convey hormones, cytokines, chemokines, and other soluble
regulatory molecules
3. transport of leukocytes and antibodies through the tissues
BLOOD SMEAR
4. maintain homeostasis
Light microscopic examination of circulating blood cells is
performed by evenly smearing a drop of blood on a glass
Blood performs many important functions within the body
slide, air-drying the preparation, and staining it with mixtures of
including:
dyes specifically designed to demonstrate distinctive
characteristics of the cells.
Supply of oxygen to tissues (bound to hemoglobin, which is
The current methods are derived from the technique
carried in red cells)
developed in the late 19th century by Romanovsky, who used
Supply of nutrients such as glucose, amino acids, and fatty a mixture of methylene blue and eosin.
acids (dissolved in the blood or bound to plasma proteins (e.g.,
Most laboratories now use either the Wright or Giemsa
blood lipids))
modifications of the original procedure, and identification of
Removal of waste such as carbon dioxide, urea, and lactic blood cells is based on the colors produced by these stains.
acid
Methylene blue stains acidic cellular components blue, and
Immunological functions, including circulation of white blood eosin stains alkaline components pink!
cells, and detection of foreign material by antibodies
Coagulation, which is one part of the body's self-repair
mechanism (blood clotting after an open wound in order to
stop bleeding)
Messenger functions, including the transport of hormones and
the signaling of tissue damage
Regulation of body pH
Regulation of core body temperature
Hydraulic functions

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ERYTHROCYTES Rh BLOOD GROUP
Another important blood group, the Rh group, is so-named
Life span in blood: About 120 days. because it was first identified in rhesus monkeys.
This complex group comprises more than two dozen antigens,
Size and shape: although many are relatively rare. Three of the Rh antigens (C,
biconcave disk, 7.5-7.8 µm diameter, 2μm at thickest D, and E) are so common in the human population that the
point, 1 μm at thinnest erythrocytes of 85% of peaple have one of these antigens on
shape maintained by a cytoskeletal complex inside the their surface, and these individuals are thus said to be Rh-
plasma membrane (involving spectrin, actin and other positive (Rh+).
components) Individuals lacking these antigens are Rh-negative (Rh-).
flexible: RBC’s normally bend to pass through small ~15%
capillaries

LM appearance in smear: Pink circle with light center (center
is thinner because of the biconcave shape). No nucleus!
During differentiation in the bone marrow, large quantities of
the iron-containing respiratory pigment haemoglobin are
synthesised. Before release into the blood circulation, the
erythrocyte nucleus is extruded and, by maturity, all
cytoplasmic organelles degenerate. The fully differentiated
erythrocyte therefore simply consists of an outer plasma
membrane enclosing haemoglobin and the limited number of
enzymes necessary for maintenance of the cell.

Function:
Transport of oxygen and carbon dioxide
bound to haemoglobin (oxyhemoglobin and
carboxyhemoglobin)
majority of CO2 transported as HCO3-
pH homeostasis PLATELETS
carbonic anhydrase: CO2 + H2O → HCO3- + H+ Life Span: about 10 days
band 3 membrane protein: exchanges HCO3- for Shape, size, and origin: Small, biconvex disks, 2-3 µm in
extracellular Cl- diameter. Non-nucleated cell fragments derived from
cytoplasm of a very large cell, the megakaryocyte, in bone
marrow! Platelets have a life span of about 10 days.
LM appearance in smears: Small basophilic fragments, often
appearing in clusters.
TEM appearance: The platelet is bounded by a plasma
membrane, and has a bundle of microtubules around the
margin of the disk (which maintains the disk shape). There are
three types of granules, containing fibrinogen, plasminogen,
thromboplastin and other factors for clotting. There are also
membrane tubules and glycogen.
Function: Platelets initiate blood clots.
may be divided into four zones

ABO BLOOD GROUPS
The extracellular surface of the red blood cell plasmalemma
has specific inherited carbohydrate chains that act as antigens
and determine the blood group of an individual for the
purposes of blood transfusion.
The most notable of these are the A and B antigens, which
determine the four primary blood groups, A, B, AB, and O.
People who lack either the A or B antigen, or both, have
antibodies against the missing antigen in their blood; if they
undergo transfusion with blood containing the missing antigen,
the donor erythrocytes are attacked by the recipient's serum
antibodies and are eventually lysed.

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 Specific granules contain various enzymes and
pharmacological agents that aid the neutrophil in performing
its antimicrobial functions. In electron micrographs these
granules appear somewhat oblong.
Azurophilic granules, as already indicated, are lysosomes,
containing acid hydrolases, myeloperoxidase, the antibacterial
agent lysozyme, bactericidal permeability-increasing (BPI)
protein, cathepsin G, elastase, and nonspecific collagenase.
Tertiary granules contain gelatinase and cathepsins as well as
glycoproteins that are inserted into the plasmalemma.

EXTRAVASATION VIA DIAPEDES
Selectin-selectin receptor interaction causes neutrophil to slow
When a blood vessel wall is damaged, factors from the & roll along surface.
damaged endothelial cells and the ECM induce the clotting Chemokines from endothelium leads to expression of integrins
cascade. Platelets aggregate and release proteins for clot & immunoglobulin family adhesion molecules on neutrophil cell
formation and resolution: membrane.
Neutrophil firmly attached to vessel wall & extends pseudopod
1. Vasoconstriction –via release of serotonin into vessel wall.
2. Further platelet aggregation –mediated via thromboxane A2 Vascular permeability mediated by heparin & histamines
and ADP released by mast cells/basophils.
3. Fibrin polymerization –initiated by thromboplastin and free Once in connective tissue, neutrophils respond to
Ca++ chemoattractants & migrate to injury site.
4. Clot contraction – via actin, myosin, and ATP released into
the matrix of the clot
5. Clot resolution –platelet plasminogen activator (pPA,
converts plasminogen into active fibrinolytic plasmin)
6. Tissue repair –platelet derived growth factor (PDGF,
stimulates smooth muscle and fibroblast proliferation)

NEUTROPHIL

Life Span: < 1 week
Granulocyte with specific and non-specific granules

Specific granules
NEUTROPHIL ANTIBACTERIAL ACTIVITY
Type IV collagenase (aids migration)
Lactoferrin (sequesters iron) Chemotaxis and migration (chemokine synthesis and matrix

proteolysis)
Phospholipase A2 (leukotriene synthesis)
Lysozyme (digests bacterial cell wall) Phagocytosis and bacterial destruction

Digestion via lysozymes
Non-specific granules (lysosomes) Production of reactive oxygen compounds (respiratory
burst)
Lysozyme
Acid hydrolase Iron sequestration via lactoferrin

Myeloperoxidase Release factors to increase inflammatory response (and

increase neutrophil production)
Elastase

LM appearance in smear: About 9-12 µm in diameter (thus
larger than RBC). Nucleus long and multi-lobed (usually 2-4
lobes).
Cytoplasm has small, neutrally stained specific granules. Non-
specific granules are azurophilic.
TEM appearance: Multi-lobed nucleus and numerous specific
granules and lysosomes (=azurophilic granules in LM).
Function: Primarily antibacterial
Neutrophils leave the blood and follow chemotaxic signals to
sites of wounding or other inflammation, and phagocytose
foreign agents such as bacteria. Pus is composed largely of
dead neutrophils.

Three types of granules are present in the cytoplasm of
neutrophils:
1. Small, specific granules (0.1 μm in diameter)
2. Larger azurophilic granules (0.5 μm in diameter)
3. Tertiary granules.
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EOSINOPHIL BASOPHIL

Life Span: < 2 weeks Life Span: 1-2 years (?)
Granulocyte with specific and non-specific granules Granulocyte with specific and non-specific granules

Specific granules Specific granules
Major basic protein Histamine
Eosinophilic cationic protein Heparin
Neurotoxin Eosinophil chemotactic factor
Histaminase Phospholipids for synthesis of leukotrienes, e.g. slow-
reacting substance of anaphylaxis ( SRS-A )
Non-specific granules (lysosomes)
Lysozyme Non-specific granules (lysosomes)
Acid hydrolase Lysozyme
Myeloperoxidase Acid hydrolase
Elastase Myeloperoxidase
Elastase
LM appearance in smear: About 10-14 µm in diameter.
Bilobed nucleus. The cytoplasm has prominent pink/red LM appearance in smear: About 9-11 µm in diameter. The
(acidophilic) specific granules (stained with eosin dye). cytoplasm contains large, basophilic purple/black specific
Basophilic cytoplasm (stained with m.blue). granules (stained with the basic dye). Acidophilic cytoplasm
(stained with eosin). The nucleus is usually bilobed, but usually
TEM appearance: The specific granules are ovoid in shape, is partially obscured by granules, which can lie over it.
and contain a dark crystalloid body composed of major basic
protein (MBP), effective against parasites. The rest of the TEM appearance: The specific granules vary in size and
granule contains other anti-parasitic substances. The shape, and have occasional myelin figures (usually formed
cytoplasm also contains lysosomes (=azurophilic granules). from phospholipids). The cytoplasm also has some lysosomes
(=azurophilic granules).
Function:
Anti-parasitic activity Function: Allergies and anaphylaxis (hypersensitivity reaction)
Mediators of inflammatory/allergic responses in tissues Binding of antigens to membrane-bound IgE antibodies
Inactivate leukotrienes and histamine secreted by induces degranulation of specific granules, which leads to
basophils allergic reaction.
Engulf and sequester antigen-antibody complexes In hypersensitivity reaction, widespread vasodilation
Inflammatory stimulus increases production/release (arteriolar) and vessel leakiness induce circulatory shock.
of eosinophils from bone marrow, whereas Bronchial spasms cause respiratory insufficiency;
inflammatory suppression decreases eosinophil combined effect is anaphylactic shock.
numbers in peripheral blood.
But, they also secrete PRO-inflammatory Similarity to tissue mast cells: Tissue mast cells also have IgE
chemokines AND they can degranulate receptors and similar (though not identical) granule content.
inappropriately to cause tissue damage (as in Mast cells and basophils have a common precursor in bone
reactive airway disease) marrow.

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LYMPHOCYTE MONOCYTE

Life Span: variable (few days to several years) Life Span: few days in blood, several months in connective
tissue
LM appearance in smear: Small lymphocyte (about 90% of
lymphocytes you will see) are ~6-7 µm in diameter, while large LM appearance in smears: About 12-15 µm in smears, thus
lymphocytes may be up to about 15 µm. Round, dense the largest leukocyte. Large, eccentric nucleus either oval,
nucleus (abundant heterochromatin). The basophilic kidney-shaped or horseshoe-shaped, with delicate chromatin
cytoplasm of a small lymphocyte is a narrow rim around the that is less dense than that of lymphocytes. Pale basophilic
nucleus, and when well stained is pale blue. T-lymphocytes cytoplasm, often bluish gray, may contain occasional stained
and B-lymphocytes cannot be distinguished in a smear. granules (lysosomes = azurophilic granules). Large
lymphocytes may resemble monocytes, but the lymphocyte
TEM appearance: The cytoplasm doesn't appear to be very nucleus is usually more dense.
active, containing mainly mitochondria and free ribosomes.
TEM appearance: Cytoplasm contains mitochondria and
Function: Cellular and humoral immunity. In general: some small lysosomes.
B-lymphocytes (B-cells): may differentiate into tissue
plasma cells which make antibodies. Some B-cells Function
become memory cells. Migrate into tissues and constitute mononuclear
T-lymphocytes (T-cells): cytotoxic T cells and helper T phagocyte system that help destroy foreign bodies and
cells. maintain or remodel tissues
Tissue macrophages
Small 6-7; medium 7-9; large 9-11 (up to 15) µm Kupfer cells (liver)
Osteoclasts (bone)
Dust cells (lungs)
Microglia (brain)
Mediate inflammatory response
Antigen presenting cells: Dendritic Cells, Langerhans
cells

fig. small lymphocyte

fig. large lymphocyte

5/7
BLOOD CELL DEVELOPMENT
(hematopoiesis = hemopoiesis)

Normally occurs in red bone marrow in adult (also spleen &
liver, if necessary)
Phases: mesoblastic (yolk sac, 2 wks)* → hepatic (6
wks)* → splenic (12 wks) → myeloid (marrow, 24 wks)
* Erythrocytes still have nuclei; leukocytes do not appear
until 8 wks

Mitotic stem and progenitor cells undergo increasing lineage
restriction to produce committed precursors.

Precursors undergo cell division and differentiation into mature
cells.

Maturation involves (note exceptions for megakaryocytes
below):
decrease in cell size**
shutting down transcription (nucleoli disappear and
chromatin condenses)**
adoption of morphological characteristics specific to that
lineage.
Future granulocytes produce specific and non-specific
granules, and then shape their nucleus.
Future monocytes produce non-specific granules and
shape their nucleus.
Future small lymphocytes decrease their size and enter
the blood, but then undergo extensive further maturation
at another site (T-cells in the thymus, and B-cells in the
"bursa equivalent").
Future erythrocytes fill cytoplasm with hemoglobin,
synthesized on free polysomes (ribosomes on mRNA),
and eventually extrude their nucleus. RETICULOCYTES
are slightly-immature red blood cells, in which the last remnants
Mature cells enter marrow sinus; immature cells in peripheral of cytoplasmic ribosomes, mitochondria and other organelles
blood typically indicates disease. still persist in what is otherwise a concentrated solution of
hemoglobin.
**Megakaryocytes develop into large polyploid cells that Reticulocytes are released into the blood, and become mature
remain transcriptionally active and extrude platelets as erythrocytes in about 24 hours.
cytoplasmic fragments directly into marrow sinus. A count of reticulocytes in a blood smear is a measure of new
RBC production.
It is often difficult to distinguish reticulocytes from mature
erythrocytes in ordinary blood smears. However, the blood
that was to be used for this smear was treated with a basic
dye, brilliant cresyl blue, which stains the RNA blue in clumps
of ribosomes, and then the smear was made. The staining
pattern in the cells looks a little bit like a net, giving the cell its
name (Latin, reticulum=fishing net; Greek, cyte=cell).

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DIAGRAM OF BONE MARROW
Marrow sinuses are sinusoidal, discontinuous capillaries.
Mature cells enter the sinuses and are conveyed to the
systemic circulation via nutrient veins.

MEGAKARYOCYTES
in bone marrow produce blood platelets
LM appearance: A huge cell, up to 50 µm in diameter. Its
long nucleus has several lobes (the nucleus is polyploid and
can be up to 64N). The cytoplasm is pale pink/red, without
visible granules. In bone marrow, megakaryocytes are
situated adjacent to a marrow sinus (large capillary), although
this may not be obvious in tissue sections.
TEM appearance: Particularly striking in the cytoplasm are
many curved white lines that are the platelet demarcation
channels, membrane-bound spaces forming the boundaries
between future platelets. The cytoplasm also contains
granules of various sizes, that will be in the platelets.
Function: Megakaryocytes produce blood platelets by
fragmentation of their cytoplasm, extending cell processes
through the endothelium of a marrow sinus, and releasing
clusters of immature platelets into the blood, to become
mature platelets.

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HISTOLOGY COLLOQUIUM II PRIMARY LYMPHOID ORGANS

The bone marrow and the thymus and the Gut-Associated
6 - LYMPHATIC SYSTEM Lymphoid Tissue (e.g. appendix, terminal ileum) are the initial
“education centers” of the immune system

In these organs, lymphocytes (T cells in the thymus, B cells in
Lymphatic System consists of:
bone marrow and gut) differentiate into immunocompetent cells
(i.e. they can recognize “self” vs. “nonself”). This differentiation is
Cells
said to be antigen-independent.
Lymphocytes (B,T, natural killer)
Antigen-presenting cells (dendritic cells, Langerhans’
The lymphocytes then enter the blood and lymph to populate:
cells & macrophages)
epidermis and mucosae
Lymphatic “tissue” – diffuse and nodular
connective tissue
Lymphatic “organs” (lymph nodes, spleen, thymus)
secondary lymphoid organs
Lymphatic vessels that carry the cells and fluid

SECONDARY LYMPHOID ORGANS
FUNCTIONS
Monitor body surfaces and fluid compartments (e.g.
The lymph nodes, lymphatic nodules, tonsils, spleen are the
epidermis, mucosae, interstitium)
secondary “education centers” of the immune system
React to the presence of potentially harmful antigens
recognized as “non-self”
In these organs, immunocompetent lymphocytes differentiate
Autoimmune diseases (rheumatoid arthritis, type I diabetes,
into immune effector and memory cells that undergo antigen-
etc.)
dependent activation and proliferation in these organs.
Lymphoid organs are classified as:
These lymphocytes then carry out their functions in the:
Primary lymphoid organs: connective tissue
secondary lymphoid organs
Thymus
mucosal surfaces lining epithelia
Bone marrow
They participate in:
Lymphatic nodules of the distal intestinal tract (e.g. ileum and
appendix) Cell mediated immunity (mostly “cytotoxic” T cells)
Humoral responses (production of antibody) (B cells, also
requires “helper” T cells)
Secondary (effector) lymphoid organs/tissue:
Spleen & lymph nodes (organs)
The thymus and bone marrow, where immature lymphocytes
Mucosal associated lymphoid tissue (MALT), e.g. lymphocytes
acquire the receptors to recognise antigen, are known as
and lymphatic nodules in the lamina propria
primary lymphoid tissues.

The spleen, lymph nodes and organised lymphoid tissues of
MALT where lymphocytes are activated in response to antigen
are the secondary lymphoid tissues.

MAJOR LYMPHOID ORGANS
The thymus is the site of maturation of immature T
lymphocytes.
The bone marrow is not only the home of lymphocyte stem
cells but is also the site of B lymphocyte maturation.
The lymph nodes are the sites where both T and B
lymphocytes may interact with antigen and antigen presenting
cells from the circulating lymph and undergo activation and cell
division.
The spleen is the location where T and B lymphocytes may
interact with blood-borne antigen and undergo stimulation and
cell division.

ROLE OF T AND B Ly
Both T and B cells are derived from stem cells in the bone
marrow. Immature T lymphocytes migrate from the bone
marrow to the thymus where they develop into mature T
lymphocytes. Mature T cells then populate the secondary
lymphoid tissues and from there continuously recirculate via
the bloodstream in the quest for antigen.
B lymphocytes are derived from precursors in the bone
marrow and also mature there. Stimulated B cells mature into
plasma cells that synthesise large amounts of antibody
(immunoglobulin gamma).

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THYMUS Each lobule is composed o