Animal Histology PDF

Summary

This document provides a detailed explanation of animal histology, focusing on epithelial and connective tissues. It covers various types of tissues, their characteristics, cell types, functions, and classifications. The document also explores aspects of gland development, cellular polarity, and specializations.

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ANIMAL HISTOLOGY
THE EPITHELIAL
TISSUES
 GENERAL CHARACTERISTICS

1. Derived from 3 germ layers
2. Densely-packed cells
3. Little or no intercellular material in between cells
4. Cells with prominent nucleus.
5. Rests on a basement membrane
6. Cells are active in mitosis – high regeneration.
7. Avascular – nourished by underlying CT
8. Polarity and cell surface modifications
CLASSIFICATION
 CLASSIFICATION
A. SIMPLE EPITHELIA (one layer of cells)
1. Simple Squamous – flat, thin, and scale-like with
central spherical nucleus. Polygonal in surface
view.
Endothelium – lining of blood vessels
Mesothelium – lining of body cavities; pleura,
pericardium,peritoneum, Bowman’s
capsule.
2. Simple Cuboidal – rectangular, central spherical
nucleus. eg. kidney, ovary, thyroid, small ducts.
3. Simple Columnar – pillar-like, basal oval nucleus
e.g. GI tract, large ducts, uterus, oviduct
Simple Epithelia
 Simple Cuboidal

Simple Columnar
Simple Squamous
CLASSIFICATION
B. STRATIFIED EPITHELIA (2 or
more layers of cells, consist of
superficial, intermediate, and
basal layers.

1. Stratified Squamous –
keratinized – no nuclei on
the uppermost layer.
Found in the epidermis of
the skin (“dry epithelium”)
non-keratinized – nuclei
present on the uppermost
layer. e.g. oral cavity,
esophagus, vagina, anal canal
(“wet epithelia”)
 CLASSIFICATION
2. Stratified Cuboidal – two layers of cuboidal cells,
rare type. Ducts of sweat gland and salivary gland.
3. Stratified Columnar – large ducts, male urethra,
conjunctiva
4. Transitional – appearance varies according to
functional state of the organ. e.g. ureter and urinary
bladder.
- distended (2-4 with flattened superficial cells)
- contracted (4-6 with dome-shaped superficial cells.
5. Pseudostratified - seemingly multi-layered due to
unequal sizes of cells and nuclei at different levels; but
all cells rest on a basement membrane.
- ciliated ( e.g. trachea and respiratory tract)
- stereociliated ( e.g. epididymis)
POLARITY & SPECIALIZATION
OF EPITHELIAL TISSUE
A. APICAL/DISTAL – facing the
lumen/free surface.
1. Cilia – beat in waves to move mucus
and trapped materials; respiratory
tracts (PCCE) and oviducts
(SCCE).
2. Flagella – also for movement; one or
two per cell; sperm motility.
CILIA STRUCTURE (EM)
A. APICAL/DISTAL

3. Microvilli –
a. PM–covered
extensions of the cell surface;
cores with numerous parallel
actin microfilaments

b. resolvable only at
EM.
c. inc. surface area for
absorption
 4. Basal body – thin dense line at
the base of cilia e.g. trachea.

5. Stereocilia – long, thin cluster
of microvilli seen as wavy tapering
projections. e.g. epididymis and
ductus deferens (absorptive) ;
hair cells of the organ of Corti
(sensory function)
GLANDS
A. GLAND DEVELOPMENT
EXOCRINE – duct-gland
- Water containing enzymes
via duct system to surface
ENDOCRINE – duct-less
gland
- Hormones through
capillary networks to the
target cells or organs
 GLANDS
B. CLASSIFICATION OF EXOCRINE
GLANDS
1. Number of cells
a. Unicellular – e.g. goblet cells
b. Multicellular - e.g. salivary
gland
2. Arrangement of duct
a. Simple – unbranched to one
generation
b. Compound – branched
3. Shape of secretory unit
a. Tubular
b. Saccular/alveolar
PRINCIPAL TYPES OF EXOCRINE GLANDS
SPECIFIC TYPES BASED ON ARRANGEMENT OF DUCTS
AND SHAPE OF SECRETORY UNITS
1. SIMPLE – unbranched duct
a. Tubular – straight, U-shaped intestine
b. Coiled tubular – sweat gland
c. Alveolar – sac/flask-like – poison gland
d. Branched alveolar/acinar – sebaceous gland
e. Branched tubular – GIT glands, uterus

2. COMPOUND – branched duct
a. Tubular – cardiac gl, oral cavity
b. Tubulo-acinar – submandibular, mammary
c. Alveolar – exocrine pancreas
IV. GLANDS
B. CLASSIFICATION OF
EXOCRINE GLANDS

4. Nature of secretory
products
a. Serous gland – water
(often containing enzymes)
e.g. parotid gland)
b. Mucus gland – mucus
(viscous glycoprotein)
e.g. goblet
c. Mixed gland –
submaxillary gland
5. Mode of Secretion
a. Merocrine – no loss of cytoplasm. exocytosis. e.g.
b. Apocrine – loss of apical cytoplasm
+ secretory product e.g. ?
c. Holocrine – entire cell released together
with the secretion. e.g.?
EPITHELIUM TYPES BASED ON
FUNCTION

 Membrane Epithelium
 Glandular Epitheliun
 Myoepithelium
 Neuroepithelium
 MYOEPITHELIAL CELLS
(BASKET CELLS)
Present in some exocrine
glands
- Located between secretory
epithelial cells and basal
lamina
- Contain microfilaments and
are contractile
- Help eject secretion from
gland
NEUROEPITHELIUM

Specialized Epithelia:
-Olfactory epithelium
-3 Types of cells:
-Olfactory cells
-Sustentacular cells
-Basal cells
THE CONNECTIVE
TISSUES
Connective Tissue

 Characteristics
 Basic Components
 cells
 extracellular matrix
 fibers
 ground substance
 CLASSIFICATION OF
CONNECTIVE TISSUES

I. CT PROPER II. SPECIALIZED CT
A. Loose CT A. Cartilage
B. Dense CT 1. Hyaline
1. Dense Ireegular 2. Elastic
2. Dense Regular 3. Fibrocartilage
C. Modified “Loose” B. Bone
1. Adipose Tissue 1. Compact
2. Reticular Tissue 2. Spongy
3. Mucous CT C. Blood
4. Elastic CT 1. WBC
5. Pigment Tissue 2. RBC
6. Lamina Propria 3. Platelet
A. CONNECTIVE TISSUE PROPER
- predominance of fibers
- subtypes based on type, density, and orientation of
its fibers.

1. Loose Connective Tissue (areolar tissue)
- very disorganized
- cells >> fibers (loosely arranged)
- moderately viscous cytoplasm
 CONNECTIVE TISSUE
PROPER

Cell components: fibroblasts, fibrocytes, mast cells,
macrophage, adipocytes ,plasma cells, mesenchymal
cells)
Fiber components: collagen fiber, elastic fiber, reticular
fibers
Ground substance: proteoglycans, glycosaminoglycans
FEATURES COLLAGEN FIBER ELASTIC FIBER RETICULAR FIBER

Abundance Most Less Least

Thickness 1-15 μm 0.1-10 μm 0.1-1.5 μm

LM Appearance Straight, faintly Branched; net-like; Delicate network; silver
eosinophilic, impregnation;
argyrophilic

Mechanical Property Tensile strength: tough Pliable and elastic Pliable

Molecular Structure Procollagen; Elastin Type III collagen
tropocollagen

Location Type I –tendon dermis Hemopoietic organs,
Type II –cartilage etc sinusoids, liver, dermis
Loose Connective Tissue
Location and Functions:
- Underlies and supports most epithelia
- Fills spaces between other tissues
- Supports the serous membranes of (mesothelia) of the
pleura, pericardium, and peritoneum.
- Since well-vascularized : conveys oxygen and nutrients
to avascular epithelia.
 2.0 Dense Connective Tissue
Dense Irregular CT
- collagen bundles in a woven pattern that provides resistance
to tensile stress from any direction.
- LOCATION: reticular layer of the dermis

Dense Regular CT
- collagen fibers densely packed into parallel bundles
- little room for ground substance
- great tensile strength
- LOCATION: found in tendons, ligaments,
periosteum, perichondrium, deep fascia, and
some organ capsules.
3.0 Modified “Loose”
 Adipose Tissue
 Reticular Tissue (reticular fibers=Type III collagen; very little
ground substance; functions in support of motile cells;
hematopoietic tissues)
 Elastic CT (elastic fibers dominant; provides flexible support;
limited to ligamenta flava of the VC, and suspensory ligament of
the penis)
 Mucous Connective Tissue (small number of cells and fibers
in an abundant ground substance; jelly-like consistency; composed
chiefly of hyaluronic acid; predominant component of the
Wharton’s jelly of the umbilical cord, nucleus pulposus, and pulp
of young teeth.
 Pigment Tissue
 Lamina Propria
3.1. Specialized Connective Tissue (matrix is either
liquid, semisolid, or hard solid)

A. CARTILAGE (semisolid gel)

Cell component: chondrocytes
Ground substance: chondroitin-sulfate and hyaluronic acid
Fibers: collagen fiber, elastic fiber, reticular fiber

Types: hyaline cartilage (nose, trachea, larynx)
elastic cartilage (external ears, epiglottis)
fibrocartilage (intervertebral disk, pubic symphysis)
Terms: perichondrium, appositional and interstitial growth
 Mitosis → cellular Chondroblasts Chondrocytes
Mesenchyme tissue
D.Hyaline
GROWTH Cartilage
- newly-formed chondrocytes deposit matrix around
themselves; enhanced by GH, thyroxine, and testosterone;
inhibited by estradiol and excess cortisone.
1. INTERSTITIAL GROWTH
- division of existing chondrocytes giving rise to
isogenous groups
2. APPOSITIONAL GROWTH
- differentiation into chondrocytes by chondroblasts
and stem cells on the inner surface of the perichondrium;
responsible for girth increase of cartilage mass.
BONE (hard mineral matrix)

 Cell component: osteoblasts, osteocytes, osteoclasts
 Osteoblast – bone deposition (active)
 Osteoblast – mature bone cells
 Osteoclast – bone resorption
 Ground substance: calcium phosphate, chondroitin-
sulfate, keratin sulfate
 Fibers: “masked” collagen
 GENERAL FEATURES OF BONE
 Main constituent of the ADULT skeletal system (supportive and
protective function)
A. COMPOSITION
1. Bone cells (osteocytes, osteoblasts, and
osteoclasts)
o Osteoclasts: These are large, multinucleated cells responsible for bone resorption.
o Osteoblasts: These are bone-forming cells that synthesize bone matrix. They produce
collagen and other organic components of the extracellular matrix, which later mineralize
to form bone
o Osteocytes: These are mature bone cells embedded in the bone matrix. They are derived
from osteoblasts and function to maintain bone tissue by regulating mineral content and
responding to mechanical stresses.

2. Fibers (Type 1 collagen)
3. Ground Substance (inorganic salts)
B. FUNCTIONS
1. Supports and protects the more fragile tissues and
organs
2. Harbors the hematopoietic tissue (bone marrow)
3. Acts as leverage for muscle movement
4. Storage site for calcium and other minerals
LACUNA
OSTEOCYTES
CANALICULI
-Slender branching tunnels
(0.1-0.2 um) radiating from
lacuna of osteocytes
-Where the nutrients derived
from blood vessels flow
THE BLOOD (liquid matrix)

 Cell component: erythrocytes, leukocytes, thrombocytes
 Ground substance: liquid plasma
 Fibers: fibrin (collagen)
 Terms: erythrocytes, monocytes, lymphocytes, B-cells,T-cells,
neutrophils, eosinophils, basophils, thromobocytes,
megakaryocytes
 Functions of the Blood Tissue
 Transporting oxygen from the lungs to tissues and carbon dioxide from
tissues to the lungs.
 Delivering nutrients like glucose, amino acids, and lipids to cells for energy
and growth.
 Removing waste products such as urea and creatinine from cells to be
excreted by the kidneys.
 Regulating body temperature by distributing heat throughout the body.
 Maintaining pH balance by buffering acids and bases to keep the body’s
environment stable.
 Fighting infections through white blood cells that combat pathogens.
 Clotting to prevent excessive blood loss after injury by forming blood clots.
 Transporting hormones to help regulate various physiological processes.
EOSINOPHILS
 EM of a monocyte

MONOCYTE – with a kidney-shaped Golgi
nucleus with delicately-stained chromatin Mitochondria
CYTOPLASM – slightly basophilic Azurophilic granules
rER poorly-developed
A BASOPHIL WITH MANY
GRANULES COVERING THE CELL
NUCLEUS

EM OF A RABBIT BASOPHIL
LOBULATED NUCLEUS APPEARS
AS 3 SEPARATED PORTIONS
NOTE THE BASOPHILIC GRANULE
(B), MITOCHONDRIA (M), AND
GOLGI COMPLEX (G)
THE MUSCULAR
TISSUES
I. GENERAL FEATURES
 Composed of differentiated cells containing contractile
proteins (actin and myosin)
 Actin (thin myofilaments)
 Myosin (thick myofilaments)

 Mesenchymal cell → lengthening + synthesis of
myofibrillar proteins → muscle cells
 A muscle cell = muscle fiber (myofiber)
 THREE TYPES OF MUSCLE
TISSUE
 SKELETAL MUSCLE
 Attached to skeleton
 Bundles of long, cylindrical, multinucleated cells showing cross striations
 Contraction is quick, forceful, voluntary control
 CARDIAC MUSCLE
 Associated with heart and roots of large bv
 Elongated, branched individual cells separated by intercalated disks
 Contraction is involuntary, vigorous, and rhythmic.
 SMOOTH MUSCLE
 Visceral muscle
 Fusiform cells showing no striations under LM.
 Contraction weak, slow, and not subject to voluntary control
 TERMINOLOGY
 Prefix “sarco”
 Sarcolemma (plasma membrane)
 Sarcoplasm (cytoplasm)
 Sarcoplasmic reticulum (sER)

 Prefix “myo”
 myoglobin (hemoglobin)
COLLAGEN I AND III
 G
Nuclei seen at the periphery, just under theA
cell membrane G
A
G

Myotendinous region: The insertion of collagen
fibers of the tendon into the complex infoldings
of the sarcolemma
A BAND
I BAND
Z-LINE
Section of heart muscle, showing
central nuclei, cross striation, and
intercalated disks
THE NERVOUS
TISSUES
NERVOUS TISSUE
 NERVE CELLS (neurons)
 NEUROGLIAL CELLS (glial cells)
THE SUPPORTING CELLS
 Also called neuroglia “nerve glue”
 Vary greatly accdg to their functions
 Structural and nutritional support of neurons
 Electrical insulation
 Enhancement of the speed of impulse conduction along axons

NOTE: It is difficult to maintain neurons in tissue culture without
supporting cells.
THE NEURONS
 Performs all specialized functions attributed to
nerve tissue
 Receive and integrate stimuli from many sources
simultaneously
 Translate stimuli into action potentials
 Propagate this electrical message rapidly over long distances
and along specific pathways.
 Transform the electrical message into specific
neurotransmitters
 Delivers the message to the target cells
 PARTS OF A NEURON
 CELL BODY
 Nucleus
 Cytoplasm
 NERVE PROCESSES
 Axons
 Dendrites
 TERMINAL BOUTONS
A Typical Multipolar
Neuron
Ultrastructure of a Neuron