chapter 4 the tissue level of organization
TRANSCRIPT
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What is a Tissue?
A tissue is a group of cells
Common embryonic origin
Function together to carry out specialized
activities
Hard (bone), semisolid (fat), or liquid (blood)
Histology is the science that deals with the
study of tissues.
Pathologist specialized in laboratory studies
of cells and tissue for diagnoses
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4 Types of Tissues Epithelial
Covers body surfaces and lines hollow organs,
body cavities, duct, and forms glands
Connective
Protects, supports, and binds organs.
Stores energy as fat, provides immunity
Muscular
Generates the physical force needed to make body
structures move and generate body heat
Nervous
Detect changes in body and responds by
generating nerve impulses
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Development of Tissues
Tissues of the body develop from three primary
germ layers:
Ectoderm, Endoderm, and Mesoderm
Epithelial tissues develop from all three germ
layers
All connective tissue and most muscle tissues
drive from mesoderm
Nervous tissue develops from ectoderm
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Cell Junctions
Contact points between the
plasma membranes of
tissue cells
5 most common types:
Tight junctions
Adherens junctions
Desmosomes
Hemidesmosomes
Gap junctions
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Tight Junctions
Web-like strands of
transmembrane proteins
Fuse cells together
Seal off passageways
between adjacent cells
Common in epithelial
tissues of the stomach,
intestines, and urinary
bladder
Help to retard the passage
of substances between
cells and leaking into the
blood or surrounding
tissues
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Adherens Junctions
Dense layer of proteins called plaque
Resist separation of cells during contractile activities
Located inside of the plasma membrane attached to both membrane proteins and microfilaments of the cytoskeleton
Transmembrane glycoproteins called cadherins insert into the plaque and join cells
In epithelial cells, adhesion belts encircle the cell
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Desmosomes
Contain plaque and cadherins that extends into the intercellular space to attach adjacent cells together
Desmosome plaque attaches to intermediate filaments that contain protein keratin
Prevent epidermal cells from separating under tension and cardiac muscles cells from pulling apart during contraction
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Hemidesmosomes
Resemble half of a
desmosome
Do not link adjacent cells
but anchor cells to the
basement membrane
Contains transmembrane
glycoprotein integrin
Integrins attach to
intermediate filaments
and the protein laminin
present in the basement
membrane
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Gap Junctions
Connect neighboring cells via tiny fluid-filled tunnels called connexons Contain membrane proteins
called connexins
Plasma membranes of gap junctions are separated by a very narrow intercellular gap (space) Communication of cells
within a tissue
Ions, nutrients, waste, chemical and electrical signals travel through the connexons from one cell to another
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Epithelial Tissues
Epithelial tissue consists of cells arranged in
continuous sheets, in either single or multiple layers
Closely packed and held tightly together
Covering and lining of the body
Free surface
3 major functions:
Selective barrier that regulates the movement of materials
in and out of the body
Secretory surfaces that release products onto the free
surface
Protective surfaces against the environment
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General Features of Epithelial Cells
Surfaces of epithelial cells differ in structure and
have specialized functions
Apical (free) surface
Faces the body surface, body cavity, lumen, or duct
Lateral surfaces
Faces adjacent cells
Basal surface
Opposite of apical layer and adhere to extracellular
materials
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General Features of Epithelial Cells
Basement membrane
Thin double extracellular layer that serves as the point of
attachment and support for overlying epithelial tissue
Basal lamina
Closer to and secreted by the epithelial cells
Contains laminin, collagen, glycoproteins, and proteoglycans
Reticular lamina
Closer to the underlying connective tissue
Contains collagen secreted by the connective tissue cells
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Epithelial Tissues
Own nerve supply
Avascular or lacks its own blood supply
Blood vessels in the connective tissue bring in nutrients and eliminate waste
High rate of cell division for renew and repair
Numerous roles in the body (i.e. protection and filtration)
Covering and lining epithelium Outer covering of skin and some internal organs
Glandular epithelium Secreting portion of glands (thyroid, adrenal, and sweat
glands)
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Covering and Lining Epithelium
Normally classified according to:
Arrangement of cells into layers
Shapes of cells
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Covering and Lining Epithelium
Arrangement of cells in layers
Consist of one or more layers depending on function
Simple epithelium
Single layer of cells that function in diffusion, osmosis,
filtration, secretion, or absorption
Pseudostratified epithelium
Appear to have multiple layers because cell nuclei at different
levels
All cells do not reach the apical surface
Stratified epithelium
Two or more layers of cells that protect underlying tissues in
areas of wear and tear
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Different Types of Covering and Lining
Epithelium
Cells vary in shape depending on their
function
Squamous
Thin cells, arranged like floor tiles
Allows for rapid passage of substances
Cuboidal
As tall as they are wide, shaped like cubes or hexagons
May have microvilli
Function in secretion or absorption
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Different Types of Covering and Lining
Epithelium
Columnar
Much taller than they are wide, like columns
May have cilia or microvilli
Specialized function for secretion and absorption
Transitional
Cells change shape, transition for flat to cuboidal
Organs such as urinary bladder stretch to larger size
and collapse to a smaller size
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Simple Epithelium
Simple squamous epithelium
Simple cuboidal epithelium
Simple columnar epithelium (nonciliated and
ciliated)
Pseudostratified columnar epithelium (nonciliated
and cilated)
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Simple squamous epithelium
Single layer of cells that resembles a tiled floor on the
surface
Nucleus is centrally located and appears flattened oval or
sphere
Found at sites for filtration or diffusion
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Covering and Lining Epithelium
Endothelium
The type of simple squamous that lines the heart,
blood vessels, and lymphatic vessels
Mesothelium
The type of epithelial layer of serous membranes
such as the pericardium, pleura, or peritoneum
Unlike other epithelial tissue, Both are
derived from embryonic mesoderm
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Simple cuboidal epithelium
Cuboidal shaped cells
Cell nuclei round and centrally located
Found in thyroid gland and kidneys
Functions in secretion and absorption
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Simple columnar epithelium
Column shaped cells
Oval nuclei at near base
Nonciliated and ciliated
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Nonciliated simple columnar epithelium
Contains columnar cells
with microvilli at their
apical surface and goblet
cells
Secreted mucus serves
as lubricant for the lining
of digestive, respiratory,
reproductive and urinary
tracts
Also prevents the
destruction of the
stomach lining by acidic
gastric juices
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Ciliated simple columnar epithelium
Columnar epithelial cells with cilia at the apical surface
In respiratory tract, goblet cells are interspersed among ciliated columnar epithelia
Secreted mucus on the surface traps inhaled foreign particles. Beating cilia moves particles to the throat for removal by coughing, swallowing, or sneezing
Cilia also moves oocytes to the uterine tubes
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Covering and Lining Epithelium
Pseudostratified columnar epithelium
Appears to have several layers due to nuclei are
various depths
All cells are attached to the basement membrane
in a single layer but some do not extend to the
apical surface
Ciliated cells secrete mucus and bear cilia
Nonciliated cells lack cilia and goblet cells
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Stratified Epithelium
Two or more layers of cells
Specific kind of stratified epithelium depends
on the shape of cells in the apical layer
Stratified squamous epithelium
Stratified cuboidal epithelium
Stratified columunar epithelium
Transitional epithelium
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Stratified Squamous Epithelium
Several layers of cells that are flat in the apical layer
New cells are pushed up toward apical layer
As cells move further from the blood supply they dehydrate, harden, and die
Keratinized form contain the fibrous protein keratin
Found in superficial layers of the skin
Nonkeratinized form does not contain keratin
Found in mouth and esophagus
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Stratified Cuboidal Epithelium
Fairly rare type of epithelium
Apical layers are cuboidal
Functions in protection
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Stratified columnar epithelium
Also very uncommon
Columnar cells in apical layer only
Basal layers has shorten, irregular shaped cells
Functions in protection and secretion
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Transitional Epithelium
Found only in the urinary system
Variable appearance
In relaxed state, cells appear cuboidal
Upon stretching, cells become flattened and appear
squamous
Ideal for hollow structure subjected to expansion
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Glandular Epithelium: Endocrine
Glands
Secretions, called hormones, diffuse directly into the
bloodstream
Function in maintaining homeostasis
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Glandular Epithelium: Exocrine Glands
Secrete products into ducts that empty onto the surfaces of
epithelium
Skin surface or lumen of a hollow organ
Secretions of the exocrine gland include mucus, sweat, oil, earwax, saliva, and digestive enzymes
Examples of glands include sudoriferous (sweat) glands
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Structural Classification of Exocrine
Glands
Multicellular glands are categorized
according to two criteria:
Ducts are branched or unbranched
Shape of the secretory portion of the gland
Simple gland duct does not branch
Compound gland duct branches
Tubular glands have tubular secretory parts
Acinar glands have rounded secretory parts
Tubuloacinar glands have both tubular and rounded
secretory parts
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Connective Tissue
Most abundant and widely distributed tissues
in the body
Numerous functions
Binds tissues together
Supports and strengthen tissue
Protects and insulates internal organs
Compartmentalize and transport
Energy reserves and immune responses
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Extracellular matrix of Connective
Tissue
Extracellular matrix is the material located
between the cells
Consist of protein fibers and ground substance
Connective tissue is highly vascular
Supplied with nerves
Exception is cartilage and tendon. Both have little
or no blood supply and no nerves
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Connective Tissue Cells Fibroblasts
Secrete fibers and components of ground substance
Adipocytes (fat cells)
Store triglycerides (fat)
Mast cells
Produce histamine
White blood cells
Immune response
Neutrophil and Eosinophils
Macrophages
Engulf bacteria and cellular debris by phagocytosis
Plasma cells
Secrete antibodies
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Connective Tissue Extracellular Matrix
Ground substance
Between cells and fibers
Fluid, semifluid, gelatinous, or calcified
Functions to support and bind cells, store water, and allow
exchange between blood and cells
Complex combination of proteins and polysaccharides
Fibers
Collagen fibers
Elastic fibers
Reticular fibers
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Classification of Connective Tissues
Embryonic connective tissue Mesenchyme and mucous connective tissue
Mature connective tissue Loose connective tissue
Areolar, adipose, and reticular
Dense connective tissue
Dense regular, dense irregular, and elastic
Cartilage
Hyaline, fibrocartilage, and elastic cartilage
Bone tissue
Liquid connective tissue
Blood and lymph
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Embryonic Connective Tissue
Mesenchyme
Gives rise to all other connective tissues
Mucous (Wharton’s Jelly)
Found in umbilical cord of the fetus
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Loose Connective Tissue: Areolar
Connective Tissue
Most widely distributed in the body
Contains several types of cells and all three fibers
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Loose Connective Tissue: Adipose Tissue
Contains adipocytes
Good for insulation and energy reserves
White (common) and brown adipose tissue
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Loose Connective Tissue: Reticular
Connective Tissue
Fine interlacing reticular fibers and cells
Forms the stroma of liver, spleen, and lymph nodes
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Dense Connective Tissue
Dense connective tissue
Contains numerous, thicker, and denser fibers
Packed closely with fewer cells than loose connective tissue
Dense regular connective tissue
Bundles of collagen fibers are regularly arranged in parallel
patterns for strength
Tendons and most ligaments
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Types of Mature Connective Tissue:
Dense Irregular Connective Tissue
Collagen fibers are usually irregularly arranged
Found where pulling forces are exerted in many directions
Dermis of skin and heart
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Dense Connective Tissue: Elastic
Connective Tissue
Contain branching elastic fibers
Strong and can recoil to original shape after stretching
Lung tissue and arteries
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Types of Mature Connective Tissue:
Cartilage
Cartilage is a dense network of collagen fibers and elastic fibers firmly embedded in chondroitin sulfate
Chrondrocytes Cartilage cells found in the spaces called lucunae
Pericondrium Covering of dense irregular connective tissue that
surrounds the cartilage
Two layers: outer fibrous layer and inner cellular layer
No blood vessels or nerves, except pericondrium
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Hyaline cartilage
Most abundant cartilage in the body
Surrounding by perichondrium (some exceptions like
articular cartilage)
Provide flexibility and support. Reduces friction
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Fibrocartilage
Chondrocytes are scattered among bundles of collagen
fibers within the extracellular matrix
Lack a perchondrium
Strongest type of cartilage
Found in intervertebral disc (between vertebrae)
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Elastic Cartilage
Chrondrocytes are located within a threadlike network of
elastic fibers
Pericondrium is present
Provides strength and elasticity
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Repair and Growth of Cartilage
Cartilage grows slowly
When injured or inflamed, repairs is slow due
to its avascular nature.
Two patterns of cartilage growth:
Interstitial growth
Growth from within the tissue
Appositional growth
Growth at the outer surface of the tissue
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Bone tissue Bones are organs composed of several different
connective tissues: bone (osseous) tissue,
periosteum, and endosteum.
Compact or spongy
Osteon or haversian system
Spongy bone lacks osteons. They have columns called
trabeculae
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Liquid Connective Tissue
Blood tissue
Connective tissue with liquid extracellular matrix called blood
plasma
Lymph
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Epithelial Membranes
Mucous membranes
Lines a body cavity that opens directly to the
exterior
Epithelial layer is important for the body’s defense
against pathogens
Connective tissue layer is areolar connective
tissue and is called lamina propria
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Epithelial Membranes
Serous membranes or serosa
Lines a body cavity that does not open directly to
the exterior. Also covers the organs that lie within
the cavity
Consist of areolar connective tissue covered by
mesothelium (simple squamous epithelium) that
secrete a serous fluid for lubrication
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Epithelial membranes: Mucous
Membranes
Membranes are flat sheets of pliable tissue
that cover or line a part of the body
Epithelial membranes are a combination of
an epithelial layer and an underlying
connective tissue layer
Mucous, Serous, and Cutaneous membranes
Synovial membranes
Lines joints and contains connective tissue but not
epithelium
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Muscular Tissue
Consists of elongated cells called muscle
fibers or myocytes
Cells use ATP to generate force
Several functions of muscle tissue
Classified into 3 types: skeletal, cardiac, and
smooth muscular tissue
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Skeletal Muscle Tissue
Attached to bones of the skeleton
Have striations
Voluntary movement or contractions by conscious control
Vary in length (up to 40 cm) and are roughly cylindrical in
shape
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Muscular Tissue
Cardiac muscle tissue
Have striations
Involuntary movement or contraction is not consciously
controlled
Intercalated disc unique to cardiac muscle tissue
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Smooth Muscle Tissue
Walls of hollow internal structures
Blood vessels, airways of lungs, stomach, and intestines
Nonstriated
Usually involuntary control
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Nervous Tissue
Consists of two principle types of cells
Neurons or nerve cells
Neuroglia
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Excitable Cells
Neurons and muscle fibers
Exhibit electrical excitability
The ability to respond to certain stimuli by
producing electrical signals such as action
potentials
Actions potentials propagate along a nerve or
muscle plasma membrane to cause a response
Release of neurotransmitters
Muscle contraction
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Tissue Repair: Restoring Homeostasis
When tissue damage is extensive both
stroma and parenchymal cells are active in
repair
Fibroblast divide rapidly
New collagen fibers are manufactured
New blood capillaries supply materials for healing
All of these process create an actively
growing connective tissue called granulation
tissue
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Aging and Tissues
Tissue heal faster in young adults
Surgery of a fetus normally leaves no scars
Young tissues have a better nutritional state, blood supply, and higher metabolic rate
Extracellular components also changes with age
Changes in the body’s use of glucose, collagen, and elastic fibers contribute to the aging process
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End of Chapter 4
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