Tissues, Glands, and Membranes PDF

Summary

This chapter explains various types of tissues, glands, and membranes, including simple columnar epithelium, epithelial tissue, and connective tissue. It details their functions and structural components. It also covers the concept of inflammation and tissue repair.

Full Transcript

Chapter 4
Tissues,
Glands, and
Membranes

Simple Columnar Epithelium
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 Tissues and Histology
Tissues are collections of similar cells and
the extracellular matrix surrounding them
Histology is the study of tissues
The four primary tissue types are
– Epithelial tissue
– Connective tissue
– Muscle tissue
– Nervous tissue
 Embryonic Tissue
Primary tissue types are derived from the
embryonic germ layers
– Endoderm
Forms the lining of the digestive tract and its
derivatives
– Mesoderm
Forms tissues such as muscle, bone, and blood
vessels
– Ectoderm
Forms the outermost layer of skin and the nervous
system
Gives rise to all tissues of the body
 Epithelial Tissue
Epithelial tissue
– Covers surfaces
– Has little extracellular material
– Usually has a basement membrane
– Has no blood vessels
Epithelial cells
– Have a free, or apical, surface (not attached to
other cells)
– A lateral surface (attached to other cells)
– A basal surface (attached to the basement
membrane)
Fig. 4.1
 Epithelial Tissue Functions
1. Protecting underlying structures
– Example: outer layer of skin and oral mucosa
2. Acting as barriers
– Example: outer layer of skin
3. Permitting the passage of substances
– Example: epithelium in the lungs
4. Secreting substances
– Example: mucous glands and sweat glands
5. Absorbing substances
– Example: epithelial cells of the intestine
 Epithelial Tissue Classification
Epithelia are classified according to the number
of cell layers and the shape of the cells
– Cell layers
Simple epithelium has one layer of cells
Stratified epithelium has more than one cell layer
Pseudostratified epithelium has one layer, but appears
to have two or more layers
Transitional epithelium is stratified epithelium that can
be greatly stretched
– Cell shape
Squamous are flat and thin
Cuboidal are cubelike
Columnar are tall and thin
Tab. 4.1a
Tab. 4.1b
Tab. 4.1c
Tab. 4.1d
Tab. 4.2a
Tab. 4.2b
Tab. 4.2c
Tab. 4.2d
 Epithelial Tissue
Structural and Functional Relationships
Cell Layers and Cell Shapes
– Simple epithelium is involved with
Diffusion
Secretion
Absorption
– Stratified epithelium serves a protective role
– Squamous cells function in
Diffusion
Filtration
– Cuboidal or columnar cells, which contain cellular
organelles
Secrete
Absorb
 Epithelial Tissue
Structural and Functional Relationships
Structural and Functional Relationships
– Free Cell Surfaces
A smooth, free surface reduces friction
– Example: Lining of blood vessels
Microvilli are cylindrical extensions of the cell
membrane that increase surface area (cells
involved in absorption of secretion)
– Example: Lining of the small intestines
Cilia propel materials over the cell surface
– Example: Lining of the nasal cavity and trachea
 Epithelial Tissue
Structural and Functional Relationships
Cell connections
– Tight junctions bind adjacent
cells together and form a
permeability barrier
– Desmosomes mechanically
bind cells together
– Hemidesmosomes
mechanically bind cells to the
basement membrane
– Gap junctions allow
intercellular communication

Fig. 4.2
 Epithelial Tissue Glands
A gland is a single cell or a multicellular
structure that secretes
– Endocrine glands do not have ducts
Secrete hormones directly into the blood
– Exocrine glands have ducts
Secretions are released onto a surface or into
a cavity
– Sweat glands and mammary glands
Classified by
– Structure
– How products leave the cell
 Epithelial Tissue Glands
Structure of Exocrine Glands
– Simple: have one duct
– Compound: have ducts that branch repeatedly
– Tubules: ducts end in small tubes
– Acini: ducts end in saclike structures
– Alveoli: ducts end in hollow sacs

Fig. 4.3
 Epithelial Tissue Glands
Exocrine Glands and Secretion Types
– Merocrine – no loss of cellular material (Ex. sweat
glands)
– Apocrine – part of the cell pinches off (Ex. mammary
glands)
– Holocrine – entire cell is shed (Ex. sebaceous glands)

Fig. 4.4
 Connective Tissue
Consist of cells seperated from each other by
abundant extracellular matrix
Functions
1. Enclosing and separating
2. Connecting tissues to one another (Ex. Ligaments
and Tendons)
3. Supporting and moving (Ex. Bones and cartilage)
4. Storing (Ex. Adipose tissue and Bones)
5. Cushioning and insulating (Ex. Adipose tissue)
6. Transporting (Ex. Blood)
7. Protecting (Ex. Blood and Bones)
 Connective Tissue Cells
Specialized cells of various connective
tissues produce the extra cellular matrix
– End in suffixes that identify the cell functions
Blast (germ) cells form the matrix
Cyte (cell) cells maintain it
Clast (break) cells break it down
 Connective Tissue
Extracellular matrix contains
– Protein fibers
Collagen fibers are flexible but resist
stretching
Reticular fibers form a fiber network
Elastic fibers recoil
– Ground substance
Proteoglycans in ground substance hold
water, enabling connective tissues to return to
their original shape after being compressed
– Fluid
 Connective Tissue Classification

Mesenchyme:
– embryonic connective
tissue that gives rise to six
major categories of
connective tissue
 Connective Tissue Classification
Loose, or areolar, connective tissue is the “loose
packing” material of the body
– Fills the spaces between organs
– Holds organs in place
Adipose tissue (fat)
– Stores energy
– Pads and protects parts of the body
– Acts as a thermal insulator
Dense connective tissue consists of a matrix
containing densely packed fibers
– Collagen fibers (Ex. tendons, ligaments, and dermis of
the skin)
– Elastic fibers (Ex. elastic ligaments and in the walls of
arteries)
 Connective Tissue Classification
Cartilage provides support
– Hyaline cartilage (Ex. covers ends of bones and forms
costal cartilages)
– Fibrocartilage (Ex. disks between vertebrae)
– Elastic cartilage (Ex. external ear)
Bone has a mineralized matrix
– forms most of the skeleton of the body
Compact bone has more matrix than spaces
Cancellous bone has more spaces then matrix
Blood has a liquid matrix
– Found in blood vessels
– Produced in hemopoietic tissue (red bone marrow)
Tab. 4.4
Tab. 4.5a
Tab. 4.5b
Tab. 4.5c
Tab. 4.5d
Tab. 4.6a
Tab. 4.6b
Tab. 4.7a
Tab. 4.7b
Tab. 4.7c
Tab. 4.8
Tab. 4.9
 Muscle Tissue
Specialized to contract, or shorten, making movement
possible
– Length of muscle cells is greater than the diameter
– Sometimes called muscle fibers because they often resemble tiny threads
Three types of muscle tissue
– Skeletal
Meat of animals
Constitutes ~40% of a person’s body weight
Attaches to the skeleton and allows for movement
Voluntary, multinucleated, and striated (banded)
– Cardiac
Muscle of the heart
Connected to one another by intercalated disks (contain gap junctions)
Involuntary, striated, and usually have one nucleus per cell
– Smooth
Forms the walls of hollow organs (except the heart) and also is found
in the skin and the eyes
Involuntary, not striated, and have a single nucleus
Tab.
4.10a
Tab.
4.10b
Tab.
4.10c
 Nervous Tissue
Nervous tissue is specialized to conduct
action potentials (electrical signals)
Neurons conduct action potentials
Neuroglia support the neurons
Tab. 4.11
 Membranes
Mucous membranes line cavities that open to
the outside of the body
– Digestive, respiratory, urinary, and reproductive tracts
– Contain glands
– Secrete mucus
Serous membranes line trunk cavities that do not
open to the outside of the body
– pleural, pericardial, and peritoneal cavities
– Do Not contain glands
– Secrete serous fluid
Synovial membranes line freely movable joints
Fig. 4.5
 Inflammation
Function of the inflammatory response is to
isolate and destroy harmful agents
Five symptoms
– Redness
– Heat
– Swelling
– Pain
– Disturbance of function
Chronic inflammation results when the agent
causing injury is not removed or something else
interferes with the healing process
Fig. 4.6
 Tissue Repair
Tissue repair is the substitution of viable cells for
dead cells
– Labile cells divide throughout life and can undergo
regeneration
– Stable cells do not ordinarily divide but can
regenerate if necessary
– Permanent cells have little or no ability to divide
If killed, repair is by replacement
Tissue repair involves
– Clot formation
– Inflammation
– Formation of granulation tissue
– Regeneration or replacement of tissues
In severe wounds, wound contracture can occur
Fig. 4.7
 Tissues and Aging
Cells divide more slowly as people age
Injuries heal more slowly
Extracellular matrix containing collagen
and elastic fibers becomes less flexible
and less elastic
Consequently
– Skin wrinkles
– Elasticity in arteries is reduced
– Bones break more easily