Week 1 Lecture Chapter 4 Student Copy Human Anatomy and Physiology PDF

Summary

This document is a lecture from a Human Anatomy and Physiology course (BIOL3306) Fall 2024, covering tissues, histology, integumentary system, and the extracellular matrix. It also discusses different types of tissues and their functions.

Full Transcript

Human Anatomy and Physiology
BIOL3306
Fall 2024

Week 1: Introduction to the course
Histology
The Integumentary System

Professor: Nour Nissan
 Your Professor
Nour Nissan, PhD
Plant (Soybean) molecular biology at AAFC
-omics studies

Contract Professor

Scientist

Email: [email protected]
send an email anytime and I will try to answer within 24-48 hours.
(weekends not included)
Include course code in the title
Course Expectations
Expectations
Respect to your peers, the professor, TAs, and yourself.
Value diverse perspectives
Refrain from discrimination of any kind
Harassment or disruptive behavior will not be tolerated
Participation and Attendance
Participation is encouraged ! Remember, this is how I get to know
you
Attendance will not be taken. You are university students!
Plagiarism Policies
All submitted work must be your own.
Any text that is not yours must be referenced.
Plagiarized work will immediately go to the Dean
Communication
Email communication (24-48 hours (weekdays only))
Course Expectations

Materials and Resources
Human Anatomy & Physiology, 3rd edition by Erin C. Amerman.

Office hours
By appointment

Accommodations
LOA’s should be sent to me ASAP
 Course Expectations

Assessments and Grading
3 TAs grading your work (possibly 4)
Aj Deneka (Full TA) (Assignment and exam grading, proctoring
& emails)
Myra Thapar (Full TA) (Assignment and exam grading,
proctoring & emails)
Acacia Frempong-Manso (1/2 TA) (Midterms & exam grading)

Course syllabus
Questions?
Let’s Begin
4.1 Introduction to Tissues
Tissue— A group of structurally and functionally related cells
and their external environment that together perform
common functions.
Histology—The study of the normal structure of tissues
All tissues share 2 basic components:
– A discrete population of cells that are related in
structure and function
– The surrounding material, called Extracellular Matrix
(EC M), which does differ in composition in each tissue
type
4.1 Types of Tissues
There are 4 Primary Tissue Types
1. Epithelial Tissues—Sheets of tightly packed cells with
little EC M; Covers and lines body surfaces and cavities
and form parts of glands
2. Connective Tissues—Connect all other tissues together;
Cells are scattered through the EC M; Bind, support,
protect, and allow transport of substances
3. Muscle Tissues—Cells contract and generate force;
Little EC M
4. Nervous Tissues—Cells (Neurons) generate, send, and
receive messages; Includes cells that support the
neurons with some EC M

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4.1 Extracellular Matrix (1 of 4)
Extracellular Matrix —Composed of substances
surrounding the cells in a tissue that function to:
Provide the tissue with strength to resist tensile (stretching)
and compressive forces
Direct cells to their proper places within a tissue
Regulate the development, mitotic activity, and survival of
cells
Hold cells in their proper positions
EC M has 2 main components: Ground Substance and
Protein Fibers

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4.1 Extracellular Matrix (2 of 4)
Ground Substance—Gel-like substance that contains
extracellular fluid (EC F) with water, ions, nutrients, and other
solutes, and 3 families of macromolecules:
Glycosaminoglycans (G AG s) —are carbohydrate
polymers that attract water and form a gel-like substance
in the ECM, providing hydration and cushioning (ex.
Hyaluronic Acid).
Proteoglycans—large molecules with GAG chains
attached to a core protein, contributing to tissue structure,
cell signaling, and ECM organization. Act as a barrier to
diffusion of substances through the EC M (ex. Aggrecan).
Glycoproteins—are proteins with carbohydrate chains
that play roles in cell adhesion, matrix formation, and
signaling (ex. Fibronectin).
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4.1 Extracellular Matrix (3 of 4)
Protein Fibers—Entwined fibrous protein subunits that
provide tensile strength; Three types are found in the EC M:
Collagen Fibers—At least 20 different types of collagen
fibers are made in the body; Make up 20-25% of all protein
in the body; Resemble entwined pieces of a steel cable;
Very resistant to tension and pressure
Elastic Fibers—Made of elastin protein surrounded by
glycoproteins; May stretch to ½ times their resting length
without breaking (distensibility) and then return to their
original length (elasticity)
Reticular Fibers—Type of collagen fiber that is thinner
and shorter than regular collagen; Interweaves to form a
scaffold that supports the cells and ground substance of
tissues; Form “webs” in some organs to trap foreign cells
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4.1 Extracellular Matrix (4 of 4)
Figure 4.1 Extracellular matrix.

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4.1 Marfan Syndrome

Marfan Syndrome results from defects in the gene that
codes for the glycoprotein fibrillin-1
With defective fibrillin-1, elastic fibers cannot function
properly because they are incorrectly anchored in the
EC M
Signs and symptoms include tall stature, long limbs and
fingers, multiple skeletal abnormalities, joint dislocations,
abnormalities of heart valves and lens of the eyes
Most lethal complication is dilation of the largest artery in
the body, the aorta, which may lead to aortic rupture and
fatal blood loss if not treated immediately

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4.1 Cell Junctions
Cell Junctions—Connections of neighboring cells in a tissue linked to one another by
integral proteins
Tight (Occluding) Junctions—Junctions composed of integral “locking” proteins in
adjacent plasma membranes; Prevents passage of macromolecules, although some are
leaky and don’t provide a complete seal
Desmosomes—Junctions composed of integral “linker” proteins in adjacent plasma
membranes; Distribute mechanical stress
Gap Junctions—Small pores made of protein channels in adjacent plasma membranes;
Allow small substances to pass freely

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4.2 Let’s Talk Tissues: Epithelial Tissues
Epithelial Tissue—Found on every external and internal
body surface, so acts as a barrier between the body and the
environment
Functions of Epithelial Tissue:
Protection—Continuous surface that shields underlying tissue from
mechanical and thermal injury; Produce hard protein keratin;
Undergoes mitosis rapidly and frequently
Immune Defenses—Cells of the immune system are scattered
throughout epithelial tissues
Secretion—Form glands that produce substances such as sweat, oil
and hormones
Transport into other Tissues—Selectively permeable barriers that
allow certain substances to pass by passive or active transport
Sensation—Most epithelia are supplied with nerves that detect
changes in the internal and external environments; Specialized
epithelial cells are responsible for some sensations
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 4.2 Components and Classification of
Epithelia (2 of 4)
Components of Epithelia:
Basement Membrane: anchors the
Figure 4.3 Structure
epithelial tissue to the underlying connective of epithelial tissue.
tissue and has 2 components:
Basal Lamina—This is the EC M of the
epithelial tissue; Consists of collagen fibers
and ground substance
Reticular Lamina—Manufactured by the
connective tissue deep to the epithelial
tissue; Consists of reticular fibers and ground
substance
Epithelial cells have 1 side in contact with the
extracellular space (Apical Surface), and 1 in
contact with deeper cells or the basal lamina (Basal
Surface)
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 4.2 Components and Classification of
Epithelia (3 of 4)
Classification of Epithelia:
Number of Cell Layers
– Simple Epithelia—Single layer of
cells
– Stratified Epithelia—More than
one layer of cells
– Pseudostratified Epithelia—Single
layer of cells that appears to be
multilayered
Shape of the Cells
– Squamous Cells—Flattened cells
– Cuboidal Cells—Short cells
– Columnar Cells—Tall and
elongated cells

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4.2 Covering and Lining Epithelia
(1 of 15)

Simple Epithelia—One cell layer thick, Does not work for
protection; Lines hollow organs and surfaces where
diffusion or transport occurs; Includes:
– Simple Squamous
– Simple Cuboidal
– Simple Columnar
– Pseudostratified Columnar

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4.2 Covering and Lining Epithelia
(2 of 15)
Simple Squamous Epithelia—Single layer of flat cells;
Resemble fried eggs that fit together like floor tiles; Diffusion
occurs quickly across cells; Found in air sacs of lungs,
serous membranes, and lining of blood vessels
Figure 4.5a Structure of simple epithelia.

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4.2 Covering and Lining Epithelia
(3 of 15)
Simple Cuboidal Epithelia—Single layer of roughly cube-
shaped cells; Appear square with a large, central nucleus;
Diffusion occurs and some secrete substances; Found in
kidney tubules and glands
Figure 4.5b Structure of simple epithelia.

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 4.2 Covering and Lining Epithelia
(4 of 15)
Simple Columnar Epithelia—Single layer of tall cells;
Appear rectangular in a section; Some have folds of the
apical surface (microvilli); Some have cilia, which move
something along the apical surface; Some produce
secretions; Found in small intestine, uterine tube, kidney
tubules and glands
Figure 4.5c Structure of simple epithelia.

Why is cilia
helpful in the
uterine tube?

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4.2 Covering and Lining Epithelia
(5 of 15)
Pseudostratified Columnar Epithelia—Single layer of cells
that appears to be stratified; Looks this way because nuclei
are at different heights and some cells are shorter; Most are
ciliated; Include goblet cells that secrete mucus; Found in
respiratory passages and nasal cavities for protection
Figure 4.5d Structure of simple epithelia.

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 4.2 Covering and Lining Epithelia
(8 of 15)

Stratified Epithelia—Thicker than simple epithelia; Effective
protective barriers, so common in areas of high stress; Cell
shape changes throughout the thickness of the tissue, so
named according to the shape in their apical layers; Includes:
– Stratified Squamous Epithelia (keratinized and
nonkeratinized); Keratinized
– Stratified Cuboidal Epithelia
– Stratified Columnar Epithelia
– Transitional Epithelia

What is Keratin?
atin is a protein that helps form hair, nails and your skin's outer layer (epidermis)
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4.2 Covering and Lining Epithelia
(9 of 15)
Stratified Squamous Epithelia—Nonkeratinized stratified
squamous epithelia has distinct nucleated cells on the apical
surface; Found in epithelium of mouth, pharynx, esophagus,
anus, and vagina
Figure 4.7a Structure of stratified epithelia.

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4.2 Covering and Lining Epithelia
(10 of 15)
Stratified Cuboidal Epithelia—Rare in the human body;
Two layers of cuboidal cells; Lines the ducts of sweat glands
Figure 4.7b Structure of stratified epithelia.

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4.2 Covering and Lining Epithelia
(11 of 15)
Stratified Columnar Epithelia—Rare in the human body;
Few layers of cells that are columnar in apical layers and
cuboidal in basal layers; Found in ducts of salivary glands;
parts of male urethra, and the conjunctiva (membrane lining
the surface of the eye)
Figure 4.7c Structure of stratified epithelia.

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4.2 Covering and Lining Epithelia
(12 of 15)
Transitional Epithelia—Cells in the basal layer are cuboidal
and apical cells are dome-shaped when the tissue is relaxed;
When stretched, apical cells appear squamous; Found in
lining of kidneys, ureters, urinary bladder, and urethra. Found
in organs that a lot of stretching happens.
Figure 4.7d Structure of stratified epithelia.

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4.2 Covering and Lining Epithelia
(14 of 15)
Figure 4.8 Summary of epithelial tissues.

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4.2 Covering and Lining Epithelia
(15 of 15)
Figure 4.8 Summary of epithelial tissues.

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4.3 Connective Tissues (1 of 2)
Connective Tissue Functions:
Connecting and Binding —Bind tissue layers together in
organs and anchor organs in place and to one another
Support—Certain connective tissues, such as bone and
cartilage, support the weight of the body
Protection—Bone protects internal organs; Cartilage and
fat tissue provide shock absorption; Elements of the
immune system are found within connective tissues
Transport—Blood, which is the main transport medium in
the body, is a type of connective tissue

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4.3 Connective Tissues (2 of 2)
Classification of Connective Tissue:
General Connective Tissue also known as Connective
Tissue Proper— Widely distributed in the body, where it
connects tissues and organs to one another and forms
part of the internal architecture; Includes:
– loose
– dense
– reticular
– adipose tissues
Specialized Connective Tissues—Class that includes
– cartilage
– bone
– blood
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4.3 Cells that form Connective Tissue
Proper (1 of 3)
Fibroblasts—Produce protein fibers, ground substance,
and other EC M elements; Usually lie close to collagen
fibers that they produce
Adipocytes—Fat cells with single large inclusion that
contains lipids with organelles pushed to the perimeter
Figure 4.12ab Cells of connective tissue proper.

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4.3 Cells of Connective Tissue
Proper (2 of 3)
Mast Cells—Cells of the immune system with cytosolic
inclusions (or granules) containing inflammatory mediators
such as histamine
Phagocytes—Immune cells that phagocytize foreign
substances, microorganisms, and dead and damaged
cells; Includes macrophages and neutrophils
Other Immune Cells—Other cells of the immune system
can move in and out of connective tissues depending on
the needs of the body

Figure 4.12cd Cells of connective tissue proper.
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4.3 Types of Connective Tissue
Proper (1 of 7)
Loose (Areolar) Connective Tissue—Ground substance
with all 3 types of protein fibers, fibroblasts, and other cells
including immune cells; Jelly-like consistency; Found deep to
the epithelium of the skin and in membranes; Supports and
houses blood vessels
Figure 4.13 Structure of loose connective tissue.

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4.3 Types of Connective Tissue
Proper (2 of 7)
Dense Irregular Connective Tissue—Composed of protein
fibers with mostly collagen fibers that are arranged
haphazardly; Strong tissue that resists tension in all 3 planes;
Found in dermis and around organs and joints
Figure 4.14a Structure of dense connective tissue.

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4.3 Types of Connective Tissue
Proper (3 of 7)
Dense Regular Collagenous Connective Tissue—
Contains thick collagen fibers arranged in parallel bundles;
Resist tension in one direction; Found in tendons (which join
muscle to bone) and ligaments (which join bone to bone)
Figure 4.14b Structure of dense connective tissue.

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4.3 Types of Connective Tissue
Proper (4 of 7)
Dense Regular Elastic Connective Tissue—Also known as
“elastic tissue;” Consists of mostly parallel elastic fibers with
randomly oriented collagen fibers; Allow organs to stretch;
Found in the lining of the large blood vessels and some
ligaments
Figure 4.14c Structure of dense connective tissue.

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4.3 Types of Connective Tissue
Proper (5 of 7)
Reticular Tissue—Includes numerous reticular
fibers(typically collagenous fibers) produced by surrounding
fibroblasts; Form fine, meshlike networks for support and
weblike nets that trap foreign cells; Forms part of basement
membrane
Figure 4.15 Structure of reticular tissue.

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4.3 Types of Connective Tissue
Proper (6 of 7)
Adipose Tissue—Fat tissue consisting of adipocytes and
surrounding fibroblasts and ECM; Adipocytes can increase in
size; Functions in insulation, warmth, shock absorption,
protection, and energy reserve

Figure 4.16 Structure of adipose tissue.

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4.3 Special Connective Tissues
Cartilage
Tough, flexible tissue that absorbs shock and is resistant
to tension, compression, and shearing forces
EC M is solid and gel-like with glycosaminoglycans,
proteoglycans, collagen fibers, and elastic fibers
Chondroblasts—Immature cartilage cells
Chondrocytes—Mature cartilage cells, which live in small
cavities called Lacunae
Surrounded by an outer sheath of dense irregular
connective tissue called the Perichondrium, which
supplies blood to the cartilage

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4.3 Special Connective Tissues
Bone
Supports the body, protects vital organs, provides
attachment sites for muscles, stores calcium salts, and
houses bone marrow, which produces our red blood cells
and stores fat
Bone Cells
– Osteoblasts—Carry out bone deposition
– Osteocytes—Mature osteoblasts that are surrounded
by EC M; Produce substances for bone maintenance
– Osteoclasts—Multinucleated cells that carry out bone
resorption (break down)
Bone Remodeling—Bone deposition and bone
resorption are constantly occurring in healthy bone
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4.3 Special Connective Tissues
Blood
EC M is fluid and is called Plasma, with water, dissolved
solutes, and globular proteins
Cells are Erythrocytes (red blood cells), which carry
oxygen, leukocyte (white blood cells), which function in
immunity, and cell fragments called platelets, which
function in blood clotting
Figure 4.19 Components of blood.

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4.4 Muscle Tissues
Muscle Cells (Myocytes)—Excitable cells that respond to
electrical or chemical stimulation; Cytoplasm is filled with
bundles of proteins called Myofilaments; Surrounded by a
small amount of EC M called Endomysium
Striated Muscle Cells—Myofilaments are organized into
regions that produce dark and light areas called “bands;”
Alternating light-dark bands are called Striations
Smooth Muscle Cells—Myofilaments are in irregular
bundles scattered in the cytoplasm so no striations are
visible

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4.4 Types of Muscle Tissue (1 of 4)
Skeletal Muscle—Found attached to the skeleton to produce
body movement; Controlled by the nervous system; Typically
voluntary movements; Formed by the fusion of embryonic
myoblasts resulting in large, multinucleate cells (also called
Muscle Fibers)
Figure 4.21a Structure of muscle tissues.

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4.4 Types of Muscle Tissue (2 of 4)
Cardiac Muscle—Found only in the heart; Involuntary
contractions; Shorter than skeletal muscle cells with
branches and a single nucleus; Intercalated discs, which
contain gap junctions and tight junctions, are found between
cells and permit heart muscle to contract as a unit
Figure 4.21b Structure of muscle tissues.

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4.4 Types of Muscle Tissue (3 of 4)
Smooth Muscle—Found in the walls of hollow organs, walls
of blood vessels, the eyes, the skin, and the ducts of some
glands; Involuntary contractions; Cells are flattened, with a
single nucleus; Gap junctions in the plasma membrane
connect cells to other smooth muscle cells
Figure 4.21c Structure of muscle tissues.

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4.5 Nervous Tissue (1 of 2)
Nervous Tissue—Makes up majority of the brain, spinal
cord, and nerves; EC M is different from other tissues and
contains few protein fibers but is mostly ground substance
with unique proteoglycans
Cells include Neurons and Neuroglial Cells
Neuroglial Cells—Supportive cells that anchor neurons and
blood vessels in place, speed up the rate of nerve impulse
transmission, and circulate fluid around the brain and spinal
cord
Neuroglial cells can divide by mitosis

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4.5 Nervous Tissue (2 of 2)
Neurons—Generate, Figure 4.22 Structure of
conduct, and receive nerve nervous tissue.
impulses (electrical
signals); Include 3 main
parts:
– Cell Body—Large
center with the nucleus
and organelles
– Axon—Moves impulse
to the target cell
– Dendrites—Arms that
receive messages
– Neurons are amitotic

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4.8 Tissue Repair (1 of 2)
Tissue Repair—Process of wound healing; Occurs
differently in different tissues and is dependent on the tissues
ability to regenerate
Regeneration—Damaged or dead cells are replaced with
cells of the same type
Fibrosis—Fibroblasts divide by mitosis and produce
collagen to fill in the defect left by the injury; Results in
Scar Tissue, which is dense irregular connective tissue

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 Conditions Favoring Regeneration: Conditions Leading to Fibrosis:

Cell Type: Tissues with high regenerative Severe Injury: Extensive damage to
capacity, such as epithelial tissues (skin, tissue structure and the ECM can
gastrointestinal lining) and some make regeneration difficult, leading to
connective tissues (liver, bone), are more fibrosis.
likely to regenerate.
Chronic Inflammation: Prolonged or
Extent of Damage: Regeneration is more chronic inflammation can lead to
likely when the damage is not extensive, excessive deposition of collagen and
and the tissue architecture is minimally other ECM components, resulting in
disrupted. fibrosis.
Presence of Stem Cells: Tissues with Lack of Regenerative
abundant stem cells or progenitor cells can Capacity: Some tissues, such as
regenerate effectively. For example, skin cardiac muscle or nervous tissue, have
and liver tissues have significant limited regenerative capacity and are
regenerative potential due to their stem cell more prone to fibrosis following injury.
populations.
Disruption of ECM: Significant
Minimal Scarring: When the underlying damage to the ECM can interfere with
extracellular matrix (ECM) is intact and not the ability of tissues to regenerate
excessively damaged, regeneration can normally, favoring scar formation
occur with less fibrosis. instead.

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4.8 Tissue Repair (2 of 2)
Figure 4.26 Tissue repair by regeneration or fibrosis.

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