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INTEGUMENTARY SYSTEM
Chapter 6
Spring 2023

HUMAN ANATOMY & PHYSIOLOGY I – BIO 103
6.1 Layers of the Skin 1

Two or more types of tissues grouped together and
performing specialized functions constitute an
organ.
The skin and its accessory structures (hair, nails,
glands, sensory receptors) make up the
integumentary system.
The skin:
◦ Largest organ by weight
◦ Composed of several tissue types
◦ Also called the cutaneous membrane
◦ Contains 2 layers: epithelial tissue overlying connective
tissue
◦ Epidermis: Outer layer
◦ Dermis: Inner layer
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6.1 Layers of the Skin 2
Epidermis:
Outer layer, composed of stratified squamous
epithelium
Basement membrane between epidermis and
dermis
Dermis:
Inner layer, thicker than epidermis
Connective tissue, with collagenous and elastic
fibers, muscle, blood, nervous tissue
Subcutaneous layer (hypodermis):
Beneath dermis; insulating layer
Areolar and adipose connective tissue.
Not considered part of the skin
Contains blood vessels that supply skin
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Figure 6.1 Skin Is Composed of Several Tissues

Al Telser/McGraw-Hill Education

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 Figure 6.2 Skin and
Subcutaneous Layer

©McGraw-Hill Education b: © McGraw-Hill Education/Al Telser, photographer
Epidermis
Stratified squamous epithelium
Lacks blood vessels
Deepest layer, stratum basale, nourished by blood vessels in
dermis
As cells grow, they migrate toward free surface, away from
nutrient supply
As they migrate, older cells, keratinocytes, begin to flatten and
die
Keratinization: Process of hardening, dehydration, and keratin
accumulation that occurs in epidermal cells as they migrate
outward
Keratin: Tough, fibrous, waterproof protein made and stored in
the cells
As cells reach outer surface, become tightly packed, develop
desmosomes, form outermost layer, stratum corneum
Stratum corneum cells are eventually shed from skin surface
Thickest on palms and soles (0.8 through 1.4 mm)
Most of body has thinner epidermis, 0.07 through 0.12 mm
Functions: Protects against water loss, harmful chemicals,
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 Figure 6.3 Epidermis
5 Layers of Epidermis:
Stratum corneum: outermost layer; dead, keratinized cells.
Stratum lucidum: only in thick skin – palms, soles.
Stratum granulosum.
Stratum spinosum.
Stratum basale/germinativum: deepest, mitotic layer.

Functions of epidermis: Protects against water loss,
harmful chemicals, mechanical injury, pathogens.
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Table 6.1 Layers of the Epidermis

Layer Location Characteristics
Many layers of keratinized, dead
Stratum corneum Outermost layer epithelial cells that are flattened and non-
nucleated

The first
Stratum lucidum column
Between stratumshows Layer, the second
corneum and stratum Cells appear clear; nuclei, organelles, and
(only presentcolumn showsonLocation, cell and the third
in
granulosum soles membranes are no longer visible
thick skin)
column
and shows
palms Characteristics.
Three to five layers of flattened granular
Stratum Beneath the stratum
cells that contain shrunken fibers of
granulosum corneum
keratin and shriveled nuclei
Many layers of cells with centrally
Beneath the stratum
Stratum spinosum located, large, oval nuclei and developing
granulosum
fibers of keratin; cells becoming flattened
A single row of cuboidal or columnar cells
Stratum basale
Deepest layer that divide and grow; this layer also
(basal cell layer)
includes melanocytes

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Special Cells of the Epidermis
Dendritic (Langerhans) Cells:
Found in the stratum spinosum
Phagocytes; protect skin and underlying tissues from infection
Tactile (Merkel) Cells:
Found in stratum basale
Along with sensory nerve endings, for Tactile Discs in dermis
Act as sensory receptors for light touch
Melanocytes:
Found in stratum basale
Produce the pigment melanin
◦ Eumelanin: Brownish-black pigment of epidermis
◦ Pheomelanin: Reddish yellow pigment, found in certain
areas
Absorbs UV light from sunlight and provides skin color
Melanin is distributed to keratinocytes, to protect from UV
radiation (DNA damage, fibroblast damage, skin cancer)
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 Epidermis: Melanocytes

Access the long description slide.
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 Epidermis: Skin Color
Factors Affecting Skin Color:
Hereditary Factors:
All people have same number of melanocytes, but vary in
amount of melanin produced (this is under genetic control).
Varying distribution and size of melanin granules.
Albinism: inherited mutation in melanin genes; lack melanin
Environmental Factors
Sunlight.
UV light from sunlamps.
X-rays.
Physiological Factors:
Oxygenation in blood of dermal blood vessels: pinkish,
cyanosis.
Vasodilation/vasoconstriction of dermal blood vessels.
Accumulation of carotene pigment from diet.
Jaundice.
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Clinical Application 6.1

Indoor Tanning and Skin Cancer
Exposure to sunlight or a tanning bed causes
melanocytes to produce more melanin, and skin
darkens
Tanning bed uses doses of UV radiation that can
overwhelm body’s natural protective responses
against skin cancer
Basal cell carcinoma and squamous cell
carcinoma arise from epithelial cells in skin
Melanomas arise from melanocytes
Melanomas are least common (4%) skin cancers, but
cause 80% of skin cancer deaths

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 Dermis 1

Inner layer of skin
Average of 1 to 2 mm thick
Contains projections called
dermal papillae between
epidermal ridges
Binds epidermis to
underlying tissues
Connective tissue layer,
containing muscle fibers,
nerve cell processes
Dermal blood vessels supply
nutrients to all skin cells
Contains hair follicles, sweat
and sebaceous glands
Contains sensory receptors:
Lamellated (Pacinian)
©McGraw-Hill Education
 Dermis 2

The dermis consists of 2
layers:
Papillary layer:
Superficial layer
Areolar connective tissue
Thinner of the 2 layers
Location of dermal papillae,
which form fingerprints
Reticular layer:
Deeper layer
Dense irregular connective
tissue
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 Accessory Structures of the
Skin from the epidermis,
Accessory structures originate
extend into dermis or hypodermis
Accessory structures of the skin:
Hair follicles.
Nails.
Skin glands (sweat and sebaceous).

If accessory structures remain intact, injured/burned
dermis can regenerate.

©McGraw-Hill Education
 Nails
Nails: Protective coverings on ends of fingers and toes.
3 parts of a nail:
Nail plate: overlies nail bed.
Nail bed: surface of skin, under nail plate.
Lunula: most active growing region; pale, half-moon-shaped region
at base of nail plate.

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 Hair Follicles
Hair is present on all surfaces of skin
except palms, soles, lips, nipples, parts of
external reproductive organs
Hair follicle: Tube-like depression of
epidermal cells from which hair develops;
extends into dermis or the subcutaneous
layer
Parts of hair:
Hair root: Extends from skin surface
to dermis or hypodermis
Hair bulb: Deepest part of hair root;
contains dividing cells of hair matrix
Hair shaft: Portion of hair that
extend beyond skin surface;
composed of dead, epidermal cells
Hair papilla contains blood vessels to
nourish hair
Hair color is due to type and amount of
melanin
©McGraw-Hill Education b: © McGraw-Hill Education/Al Telser
Clinical Application 6.2

Hair Loss
Most common type of baldness is pattern baldness;
top of head loses hair (called androgenic
alopecia)
Associated with lowered level of testosterone (men)
or estrogen (women)
Progenitor cells are lacking in bald spots, but stem
cells are present
Alopecia areata: body produces antibodies that
attack hair follicles; autoimmune hair loss

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 Figure 6.9 Skin Glands:
Sebaceous
Sebaceous Glands:
Glands
Holocrine glands
Usually associated with
hair follicles
Produce sebum, which
consists of fatty
material and cellular
debris
Sebum keeps hair and
skin soft and
waterproof
Excess sebum can
result in acne
Absent on palms and
soles
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Clinical Application 6.3

Acne
Acne vulgaris is a disorder of sebaceous glands
Common at puberty, because sebaceous glands are
excessively responsive to androgens
Sebaceous glands become clogged with extra
sebum and epithelial cells
Clogged glands provide good environment for
anaerobic bacteria; infection results in inflammation
Affects 80% of people between 11 and 30 years of
age
Treated best with Vitamin A derivatives, systemic
antibiotics, salicylic acid, benzoyl peroxide

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 Skin Glands: Sweat Glands
Sweat (Sudoriferous) Glands:
Widespread in skin
Originate in deeper dermis or
hypodermis as ball-shaped coils
Types of sweat glands:
Eccrine (merocrine) glands:
Most numerous, consist mainly of water,
some salts, wastes
Respond to elevated body temperature
Open to body surface through pores
Apocrine sweat glands:
Axillary and groin areas; open into hair
follicles
Called apocrine, but secrete by exocytosis
Respond to emotions, pain
Specialized sweat glands:
Ceruminous glands—ear wax
Mammary glands—milk
©McGraw-Hill Education
©McGraw-Hill Education
Table 6.2 Glands of the Skin

Type Description Function Location
Sebaceous glands Groups of Keep hair soft, Near or connected to
specialized pliable, waterproof hair follicles,
epithelial cells everywhere but on
palms and soles
Merocrine sweat Abundant sweat Lower body Originate in deep
glands Thefirst column
glands with shows Type,
temperaturethe second
dermis or
column shows
odorless Description, the third column
secretion subcutaneous layer
shows Function, and the fourth column and open to surface
on forehead, neck,
shows Location. and back
Apocrine sweat Less numerous Wet skin during Near hair follicles in
glands sweat glands with pain, fear, armpit and groin
secretions that emotional upset,
develop odors and sexual arousal
Ceruminous glands Modified sweat Secrete ear wax External acoustic
glands meatus
Mammary glands Modified sweat Secrete milk Breasts
glands

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6.3 Skin Functions

Skin is versatile, and vital for homeostasis
Functions of the skin:
◦ Protective barrier: Protects against harmful
substances, UV radiation, microorganisms, water
loss
◦ Sensation: Contains sensory receptors for touch,
pressure, temperature changes, pain
◦ Excretion of some wastes
◦ Production of Vitamin D: Starts in skin; when
produced and activated, helps with calcium
absorption
◦ Regulation of body temperature: Helps cool
body by sweating and blood flow changes
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Heat Production and Loss

Important to regulate body temperature; slight shift
can disrupt rates of metabolic reactions
Set point is monitored by hypothalamus in brain
Deep body temperature stays close to set point of
37 degrees Celsius or 98.6 degrees Fahrenheit
Skin plays key role in homeostatic mechanisms that
regulate body temperature
Heat is product of cellular metabolism; mainly
produced by most active cells (liver, skeletal and
cardiac muscle)

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 Heat Production and Loss
Heat is a product of cellular metabolism.
The most active body cells are major heat producers:
skeletal muscle, cardiac muscle, cells of the liver.
When body is too warm, body responds with vasodilation of
dermal blood vessels and vasoconstriction of deep blood
vessels. Heat can escape through skin.
Methods of heat loss:
1. Radiation: Primary method, infrared heat rays escape.
2. Conduction: Heat moves from skin to cooler objects.
3. Convection: Heat loss into circulating air currents.
4. Evaporation: Sweat changes into a gas, carries heat
away.

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 Body Temperature Regulation
When body temperature rises:
Thermoreceptors signal
hypothalamus
Vasodilation of dermal blood
vessels
Vasoconstriction of deep blood
vessels
Sweat glands are activated
When body temperature falls:
Thermoreceptors signal
hypothalamus
Vasoconstriction of dermal blood
vessels
Vasodilation of deep blood
vessels
Sweat glands are inactive
Muscles contract involuntarily
(shivering)
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Problems in Temperature Regulation

Hyperthermia: abnormally high body temperature
Can occur on hot, humid day, when sweat cannot
evaporate
When air temperature is high, radiation is less effective
Body may gain heat from hotter air
Skin becomes dry, person gets weak, dizzy, nauseous,
with headache, rapid pulse
Hypothermia: abnormally low body temperature
Can result from prolonged exposure to cold, or illness
Shivering is involuntary skeletal muscle contraction,
caused by hypothalamus
Progresses to confusion, lethargy, loss of reflexes and
consciousness
Without treatment, organs shut down

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Clinical Application 6.4

Elevated Body Temperature
Loss of ability of homeostatic temperature control mechanism to
function in an extremely hot environment:
Exposure to very high heat can overwhelm temperature
control mechanisms, leading to hyperthermia
If body heat builds up faster than heat can be lost from body,
body temperature will rise, even when set point is normal
Extreme vasodilation can collapse cardiovascular system; can
be fatal
Fever:
Set point is elevated by the immune system, to fight infection
Phagocytes release pyrogens in response to presence of
bacteria, viruses; hypothalamus increases set point and raises
body temperature
Elevated body temperature helps destroy pathogens

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 Healing of Wounds and Burns
Inflammation:
A normal response to injury or stress
Body’s attempt to restrict spread of infection
Blood vessels in affected tissues dilate and
become more permeable, allowing fluids to leak
into the damaged tissues
Inflamed skin may become:
Reddened
Swollen
Warm
Painful

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Cuts

A shallow cut, which affects only the epidermis, results in
epidermal cells along its margin dividing more rapidly than
usual, to fill gap
A deep cut, reaching dermis or subcutaneous layer,
results in blood vessels breaking; released blood forms a
clot:
Clot consists of fibrin, blood cells, and platelets
Clot and dried tissue fluid form scab
Epithelial cells reproduce, fill in the wound
Fibroblasts secrete collagen fibers to bind wound
together
Growth factors stimulate new tissue formation
Phagocytic cells remove dead cells and debris, scab
sloughs off
Excess collagenous fibers may form elevated mass called
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 Figure 6.14 Healing of a
Wound

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 Burns 1
Burns are classified by extent of tissue damage:
Superficial, partial-thickness (first degree) burn:
Injures only epidermis, as in sunburn; redness, heat, inflammation
Healing takes days to weeks, no scarring
Deep, partial-thickness (second degree) burn:
Destroys epidermis and some dermis, as in burn from hot liquid
May blister, healing varies with severity of burn and stem cell survival
Stem cells in hair follicles and glands can help regenerate skin
Usually recovers completely, no scarring
Full-thickness (third degree) burn:
Destroys epidermis, dermis, accessory structures
Results from prolonged exposure to heat, flames, hot liquids
Some healing from margins
Often requires skin graft, skin substitutes

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 Figure 6.16 Rule of Nines for Burn
Patients
Rule of Nines:
Divides body
surface into
regions of 9% or
multiples of 9
Used to estimate
extent of injured
body surface from
a burn for
treatment
From this
estimate, plans to
replace fluids,
electrolytes, and
skin can be figured

©McGraw-Hill Education
Life-Span Changes

Cell cycle slows, skin becomes scaly, age spots appear
Epidermis and dermis become thinner
Loss of fat in subcutaneous layer; person feels cold
Wrinkling, sagging of skin occur
Sebaceous glands secrete less oil; skin becomes dry
Melanin production slows; hair whitens
Hair thins
Number of hair follicles decreases
Nail growth becomes impaired
Sensory receptors decline
Body temperature regulation becomes less effective
Diminished ability to produce Vitamin D

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