Human Anatomy and Physiology-Integumentary System Lec 4 PDF

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This document is a collection of lecture notes on the integumentary system, covering its structure, and cells of the epidermis. The notes are from a "Human Anatomy and Physiology" textbook.

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Human Anatomy and Physiology
Eleventh Edition

Chapter 05
The Integumentary System

PowerPoint® Lectures Slides prepared by Karen Dunbar Kareiva, Ivy Tech Community College

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Integumentary System
Integumentary system consists of:
– Skin
– Hair
– Nails
– Sweat glands
– Sebaceous (oil) glands

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5.1 Structure of Skin
Skin consists of two distinct regions:
– Epidermis: superficial region
 Consists of epithelial tissue and is avascular
– Dermis: underlies epidermis
 Mostly fibrous connective tissue, vascular

– Hypodermis (superficial fascia)
 Subcutaneous layer deep to skin
 Not part of skin but shares some functions
 Mostly adipose tissue that absorbs shock and insulates
 Anchors skin to underlying structures: mostly muscles

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Skin Structure

Hair shaft

Dermal papillae
Epidermis
Papillary
layer Sweat pore

Appendages of skin
Dermis
Reticular Eccrine sweat gland
layer Arrector pili muscle
Sebaceous (oil) gland
Hair follicle
Hair root

Subcutaneous
tissue(hypodermis;
not part of skin)

Dermal vascular plexus
Nervous structures
Sensory nerve fiber Adipose tissue
with free nerve
endings
Lamellar corpuscle
Hair follicle receptor
(root hair plexus)

Figure 5.1 Skin structure.
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5.2 Epidermis

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 Cells of the Epidermis
Epidermis consists mostly of
keratinized stratified squamous
epithelium
Four cell types found in epidermis:
1. Keratinocytes
 A specialized type of
epithelial cell
 Produce fibrous keratin
(protein that gives skin its
protective properties)
 Major cells of epidermis
 Tightly connected by
desmosomes
 Millions slough off every day

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 Cells of the Epidermis
Epidermis consists mostly of
keratinized stratified squamous
epithelium
Four cell types found in epidermis:
1. Keratinocytes
 Produce fibrous keratin
(protein that gives skin its
protective properties)

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Cells of the Epidermis
2. Melanocytes
 Spider-shaped cells located in
deepest epidermis
 Produce pigment melanin, which
is packaged into melanosomes
– Melanosomes are transferred
to keratinocytes, where they
protect nucleus from UV
damage
3. Dendritic (Langerhans) cells
 Star-shaped subset of
macrophages that patrol deep
epidermis
– Are key activators of immune
system
4. Tactile (Merkel) cells
 Sensory receptors that sense
touch

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Layers of the Epidermis
Epidermis is made up of four or five distinct layers
– Thick skin contains five layers (strata) and is found in high-abrasion areas (hands,
feet)
– Thin skin contains only four strata
Five layers of skin
1. Stratum basale
2. Stratum spinosum
3. Stratum granulosum
4. Stratum lucidum (only in thick skin)
5. Stratum corneum

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Layers of the Epidermis
1. Stratum basale (basal layer)
– Deepest of all epidermal layers (base layer)
– Layer that is firmly attached to dermis
– Consists of a single row of stem cells that
actively divide (mitotic), producing two
daughter cells each time
 One daughter cell journeys from basal
layer to surface, taking 25–45 days to
reach surface
– Cell dies as it moves toward
surface
 Other daughter cell remains in stratum
basale as stem cell
– Layer also known as stratum
germinativum because of active mitosis
– 10–25% of layer also composed of
melanocytes

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Layers of the Epidermis

2. Stratum spinosum (prickly layer)
– Several cell layers thick
– Cells contain weblike system of
intermediate prekeratin filaments
attached to desmosomes
 Allows them to resist tension and
pulling
– Keratinocytes in this layer appear
spikey, so they are called prickle cells
– Scattered among keratinocytes are
abundant melanosomes and dendritic
cells

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Layers of the Epidermis
3. Stratum granulosum (granular layer)
– Four to six cells thick, but cells are
flattened, so layer is thin
– Cell appearance changes
 Cells flatten, nuclei and organelles
disintegrate
 Keratinization begins
– Cells accumulate keratohyaline
granules that help form keratin
fibers in upper layers
 Cells also accumulate lamellar
granules, a water-resistant glycolipid
that slows water loss
– Cells above this layer die
 Too far from dermal capillaries to
survive

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 Layers of the Epidermis
4. Stratum lucidum (clear layer)
– Found only in thick skin
– Consists of thin, translucent band of two
to three rows of clear, flat, dead
keratinocytes
– Lies superficial to the stratum
granulosum

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Layers of the Epidermis
5. Stratum corneum (horny layer)
– 20–30 rows of flat, anucleated,
keratinized dead cells
– Accounts for three-quarters of epidermal
thickness
– Though dead, cells still function to:
 Protect deeper cells from the
environment
 Prevent water loss
 Protect from abrasion and
penetration
 Act as a barrier against biological,
chemical, and physical assaults

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Layers of the Epidermis
Cells change by going through apoptosis (controlled cell death)
– Dead cells slough off as dandruff and dander
– Humans can shed ~50,000 cells every minute

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Epidermal
Cells and
Layers of the
Epidermis Keratinocytes

Stratum corneum
Most superficial layer; 20–30 layers of dead
cells, essentially flat membranous sacs filled
with keratin. Glycolipids in extracellular space.

Stratum granulosum
One to five layers of flattened cells, organelles
deteriorating; cytoplasm full of lamellar
granules (release lipids) and keratohyaline
granules.
Stratum spinosum
Several layers of keratinocytes unified by
desmosomes. Cells contain thick bundles of
intermediate filaments made of pre-keratin.

Stratum basale
Deepest epidermal layer; one row of actively
mitotic stem cells; some newly formed cells
become part of the more superficial layers.
See occasional melanocytes and tactile Dermis
epithelial cells.

(a) Dermis Melanin Sensory Tactile
granule nerve epithelial
ending cell

Figure 5.2 Epidermal cells and layers of the epidermis. (b) Desmosomes Melanocyte Dendritic cell

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5.3 Dermis
Strong, flexible connective tissue

Cells include fibroblasts, macrophages, and occasionally mast cells and white blood
cells
Fibers in matrix bind body together
– Makes up the “hide” that is used to make leather

Contains nerves, blood vessels, and lymphatic vessels

Contains epidermal hair follicles, oil glands, and sweat glands

Two layers
– Papillary
– Reticular

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Light Micrograph of the Dermis

Epidermis

Dermis:
Papillary dermis
(areolar
connective
tissue)
Reticular dermis
(dense irregular
connective tissue)

Dermal papillae

Figure 5.3 Light micrograph of the dermis.
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Papillary Layer
Superficial layer of areolar connective tissue consisting of loose, interlacing collagen and
elastic fibers and blood vessels
Loose fibers allow phagocytes to patrol for microorganisms

Dermal papillae: superficial region of dermis that sends fingerlike projections up into
epidermis
– Projections contains capillary loops, free nerve endings, and touch receptors
(tactile corpuscles, also called Meissner’s corpuscles)

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Papillary Layer
In thick skin, dermal papillae lie on top of dermal ridges, which give rise to epidermal
ridges
– Collectively ridges are called friction ridges
 Enhance gripping ability
 Contribute to sense of touch
 Sweat pores in ridges leave unique fingerprint pattern

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Dermal Modifications Result in Characteristic Skin Markings
Friction ridges Sweat duct openings
consist of epidermal along the crests of
ridges that lie on top friction ridges help
of dermal ridges. make fingerprints.

Figure 5.4c Dermal modifications
result in characteristic skin markings. (c) Friction ridges of fingertip (SEM 12X)

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Reticular Layer
Makes up ~80% of dermal thickness

Consists of coarse, dense fibrous connective tissue
– Many elastic fibers provide stretch-recoil properties
– Collagen fibers provide strength and resiliency
 Bind water, keeping skin hydrated

Cutaneous plexus: network of blood vessels between reticular layer and hypodermis

Extracellular matrix contains pockets of adipose cells

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Reticular Layer
Cleavage (tension) lines in reticular layer are caused by many collagen fibers running
parallel to skin surface
– Externally invisible
– Important to surgeons because incisions parallel to cleavage lines heal more
readily

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Dermal Modifications Result in Characteristic Skin Markings
Cleavage lines
Represent separations between underyling
collagen fiber bundles in the reticular dermis.
Run circularly around the trunk and
longitudinally in the limbs.
Surgical incisions parallel to cleavage lines heal
better than those made across them.

(a) Cleavage lines

Figure 5.4a Dermal modifications result in characteristic skin markings.
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Reticular Layer
Flexure lines of reticular layer are dermal folds at or near joints
– Dermis is tightly secured to deeper structures
– Skin’s inability to slide easily for joint movement causes deep creases
– Visible on hands, wrists, fingers, soles, toes

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Dermal Modifications Result in Characteristic Skin Markings

Flexure lines form where the dermis is
closely attached to the underlying structures.

(b) Flexure lines

Figure 5.4b Dermal modifications result in characteristic skin markings.
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Clinical – Homeostatic Imbalance 5.1
Extreme stretching of skin can cause dermal tears, leaving silvery white scars called
striae
– Also known as “stretch marks”

Acute, short-term traumas to skin can cause blisters, fluid-filled pockets that separate
epidermal and dermal layers

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Stretch Marks (Striae)

Figure 5.5 Stretch marks (striae).
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 5.4 Skin Color
Three pigments contribute to skin color
1. Melanin
 Only pigment made in skin; made by melanocytes
 Made from amino acid tyrosine by tyrosinase
 Packaged into melanosomes that are sent to shield
DNA of keratinocytes from damaging UV sunlight
 The more sun, the more need for protective shield,
the more melanin will be produced
 Two forms: reddish yellow to brownish black
 Skin color differences are due to amount and form of
melanin
 Freckles and pigmented moles are local
accumulations of melanin

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5.4 Skin Color
2. Carotene
 Yellow to orange pigment
 Most obvious in palms and soles
 Accumulates in stratum corneum and hypodermis
 Can be converted to vitamin A for vision and epidermal health
3. Hemoglobin
 Pinkish hue of fair skin is due to lower levels of melanin
– Skin of Caucasians is more transparent, so color of hemoglobin shows
through

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Clinical – Homeostatic Imbalance 5.3
Alterations in skin color can indicate disease
– Cyanosis
 Blue skin color: low oxygenation of hemoglobin
– Pallor (blanching or pale color)
 Anemia, low blood pressure, fear, anger
– Erythema (redness)
 Fever, hypertension, inflammation, allergy
– Jaundice (yellow cast)
 Liver disorders, impaired removal of bilirubin

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Concept review
Which of the following layers of the epidermis is associated
with the presence of intermediate prekeratin filaments?
A) stratum basale
B) stratum spinosum
C) stratum granulosum
D) stratum lucidem
E) stratum corneum

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5.5 Hair
Consists of dead keratinized cells

None located on palms, soles, lips, nipples, and portions of external genitalia

Functions:
– Warn of insects on skin
– Hair on head guards against physical trauma
– Protect from heat loss
– Shield skin from sunlight

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Structure of a Hair
Hairs (also called pili): flexible strands of dead, keratinized cells

Produced by hair follicles

Contains hard keratin, not like soft keratin found in skin
– Hard keratin is tougher and more durable, and cells do not flake off

Regions:
– Shaft: area that extends above scalp, where keratinization is complete
– Root: area within scalp, where keratinization is still going on

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 Structure of a Hair
Three parts of hair shaft:
– Medulla: central core of
large cells and air spaces

– Cortex: several layers of
flattened cells surrounding
medulla

– Cuticle: outer layer
consisting of overlapping
layers of single cells

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Structure of a Hair
Hair pigments are made by melanocytes in hair follicles
– Combinations of different melanins (yellow, rust, brown, black) create all the hair
colors
 Red hair has additional pheomelanin pigment
 Gray/white hair results when melanin production decreases and air bubbles
replace melanin in shaft

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Skin Appendages: Structure of a Hair and
Hair Follicle

Follicle wall
Peripheral
connective
tissue
(fibrous)
Glassy sheath
membrane
Epithelial root sheath
External root sheath
Internal root sheath

Hair
Cuticle
Cortex
Medulla
(b) Photomicrograph of a cross
(a) Diagram of a cross section of a hair within its follicle section of a hair and hair
follicle (100×)

Figure 5.6a, b Structure of a hair and hair follicle.
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 Structure of a Hair Follicle
Extends from epidermal surface to dermis

Hair bulb: expanded area at deep end of follicle

Hair follicle receptor (or root hair plexus): sensory nerve endings that wrap around bulb
– Hair is considered a sensory touch receptor

Wall of follicle composed of:
– Peripheral connective tissue sheath
 Derived from dermis
 Also called fibrous sheath
– Glassy membrane: thickened basal lamina
– Epithelial root sheath Follicle wall
Peripheral
 Derived from epidermis connective
tissue
 Internal and external (fibrous)
Glassy sheath
membrane
Epithelial root sheath
External root sheath
Internal root sheath

Hair
Cuticle
Cortex
Medulla
(b) Photomicrograph of a cross
(a) Diagram of a cross section of a hair within its follicle section of a hair and hair
follicle (100×)
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Structure of a Hair Follicle
Hair matrix: actively dividing
area of bulb that produces hair
cells
– As matrix makes new
cells, it pushes older ones
upward
Arrector pili: small band of
smooth muscle attached to
follicle
– Responsible for “goose
bumps”
Hair papilla
– Dermal tissue containing a
knot of capillaries that
supplies nutrients to
growing hair

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Skin Appendages: Structure of a Hair and
Hair Follicle
Follicle wall
Peripheral
connective
tissue
(fibrous)
Glassy sheath
membrane
Epithelial root sheath
External root sheath
Internal root sheath

Hair root
Cuticle
Cortex
Medulla

Hair matrix
Hair papilla
Melanocyte

Subcutaneous
adipose tissue
(c) Diagram of a longitudinal view of the expanded hair (d) Photomicrograph of longitudinal view
bulb of the follicle, which encloses the matrix of the hair bulb in the follicle (150×)

Figure 5.6c, d Structure of a hair and hair follicle.
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Types and Growth of Hair
Vellus hair: pale, fine body hair of children and adult females

Terminal hair: coarse, long hair
– Found on scalp and eyebrows
– At puberty
 Appear in axillary and pubic regions of both sexes
 Also on face and neck of males

Nutrition and hormones affect hair growth

Follicles cycle between active and regressive phases
– Average 2.25 mm growth per week
– Lose 90 scalp hairs daily

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Hair Thinning and Baldness
Alopecia: hair thinning in both sexes after age 40

True (frank) baldness
– Genetically determined and sex-influenced condition
– Male pattern baldness caused by follicular response to DHT (dihydrotestosterone)
 Androgens cause shorter and shorter growth cycles

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5.6 Nails
Lunule Lateral
nail fold

Scale-like modifications of
epidermis that contain hard
keratin
Act as a protective cover for
distal, dorsal surface of fingers
and toes
Consist of free edge, nail plate, (a)
and root Free edge Nail Eponychium Nail root
of nail plate (cuticle)
Proximal Nail
Nail bed is epidermis underneath nail fold matrix
keratinized nail plate
Nail matrix: thickened portion of
bed responsible for nail growth

(b)

Hyponychium Nail bed Phalanx (bone of fingertip)

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5.6 Nails Lunule Lateral
nail fold

Nail folds: skin folds that overlap
border of nail
Eponychium: nail fold that
projects onto surface of nail body
– Also called cuticle
Hyponychium: area under free
edge of plate that accumulates dirt
Nails normally appear pink (a)
Free edge Nail Eponychium Nail root
because of underlying capillaries plate (cuticle)
of nail
– Lunule: thickened nail matrix, Proximal Nail
nail fold matrix
appears white
Abnormal color or shape can be an
indicator of disease

(b)

Hyponychium Nail bed Phalanx (bone of fingertip)

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Clinical - Homeostatic Imbalance 5.6
Nail appearance can help in diagnosing some diseases such as:
– Yellow-tinged may indicate respiratory or thyroid gland disorder
– Thickened yellow nails can be due to fungal infection of nail
– Koilonchya, also called “spoon nail” – an outward concavity of nail may signal iron
deficiency
– Beau’s lines – horizontal lines across nails may indicate severe illnesses such as
uncontrolled diabetes, heart attack or cancer chemotherapy

Koilonychia

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5.7 Sweat Glands
Also called sudoriferous glands

All skin surfaces except nipples and parts of external genitalia contain sweat glands
– About 3 million per person

Two main types
– Eccrine (merocrine - exocytosis) sweat glands
– Apocrine (actually merocrine - exocytosis) sweat glands

Contain myoepithelial cells
– Contract upon nervous system stimulation to force sweat into ducts

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Eccrine (Merocrine) Sweat Glands
Most numerous type

Abundant on palms, soles, and forehead

Ducts connect to pores

Function in thermoregulation
– Regulated by sympathetic nervous system

Their secretion is sweat
– 99% water, salts, vitamin C, antibodies, dermcidin (microbe-killing peptide),
metabolic wastes

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Skin Appendages: Cutaneous Glands
Sweat
Sebaceous pore
gland

Eccrine
gland

Duct
Dermal connective
tissue
Secretory cells

(b) Eccrine gland (140×)

Figure 5.9b Cutaneous glands.
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Apocrine Sweat Glands
Despite name, are also merocrine glands that use exocytosis

Confined to axillary and anogenital areas

Secrete viscous milky or yellowish sweat that contains fatty substances and proteins
– Bacteria break down sweat, leading to body odor

Larger than eccrine sweat glands with ducts emptying into hair follicles

Begin functioning at puberty
– Function unknown but may act as sexual scent gland

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Apocrine Sweat Glands
Modified apocrine glands
– Ceruminous glands: lining of external ear canal; secrete cerumen (earwax)
– Mammary glands: secrete milk

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Sebaceous (Oil) Glands
Widely distributed, except for thick skin of palms and soles

Most develop from hair follicles and secrete into hair follicles

Relatively inactive until puberty
– Stimulated by hormones, especially androgens

Secrete sebum
– Oily holocrine secretion
– Bactericidal (bacteria-killing) properties
– Softens hair and skin

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Skin Appendages: Cutaneous Glands
Sweat
pore
Sebaceous
gland
Dermal
connective Sebaceous Hair in
tissue gland duct hair follicle

Eccrine
gland

Secretory cells

(a) Sebaceous gland (90×)

Figure 5.9a Cutaneous glands.
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Table 5.1 Summary of Cutaneous Glands

Table 5.1 Summary of Cutaneous Glands.
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Clinical – Homeostatic Imbalance 5.7
Acne is usually an infectious inflammation of the sebaceous glands, resulting in pimples
(pustules or cysts)
– Associated with Propionibacterium acne infection

Whiteheads are blocked sebaceous glands
– If secretion is oxidized, whitehead becomes a blackhead

Overactive sebaceous glands in infants can lead to seborrhea, known as “cradle cap”
– Begins as pink, raised lesions on scalp that turn yellow/brown and flake off

Cradle Cap (Seborrhea) in a Newborn

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5.8 Functions of Skin
Skin is first and foremost a barrier

Its main functions include:
– Protection
– Body temperature regulation
– Cutaneous sensations
– Metabolic functions
– Blood reservoir
– Excretion of wastes

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Protection
Skin is exposed to microorganisms, abrasions, temperature extremes, and harmful
chemicals
Constitutes three barriers:
– Chemical barrier
– Physical barrier
– Biological barrier

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Protection
Chemical barrier
– Skin secretes many chemicals, such as:
 Sweat, which contains antimicrobial proteins
 Sebum and defensins, which kill bacteria
 Cells also secrete antimicrobial defensin
– Acid mantle: low pH of skin retards bacterial multiplication
– Melanin provides a chemical barrier against UV radiation damage

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Protection
Physical barrier
– Flat, dead, keratinized cells of stratum corneum, surrounded by glycolipids, block
most water and water-soluble substances
– Some chemicals have limited penetration of skin:
 Lipid-soluble substances
 Plant oleoresins (e.g., poison ivy)
 Organic solvents (acetone, paint thinner)
 Salts of heavy metals (lead, mercury)
 Some drugs (nitroglycerin)
 Drug agents (enhancers that help carry other drugs across skin)

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Protection
Biological barriers
– Epidermis contains phagocytic cells
 Dendritic cells of epidermis engulf foreign antigens (invaders) and present to
white blood cells, activating the immune response
– Dermis contains macrophages
 Macrophages also activate immune system by presenting foreign antigens to
white blood cells
– DNA can absorb harmful UV radiation, converting it to harmless heat

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Clinical – Homeostatic Imbalance 5.8
If organic solvents or heavy metals pass through skin and enter blood, multiple organ
systems can be devastated which can be lethal
– Examples:
 Kidneys can shut down
 Brain can be damaged
 Absorption of lead can result in anemia and neurological defects.

Care must always be used when handling organic solvents or heavy metals
– Should never be touched with bare hands

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Body Temperature Regulation
Under normal, resting body temperature, sweat glands produce about 500 ml/day of
unnoticeable sweat
– Called insensible perspiration

If body temperature rises, dilation of dermal vessels can increase sweat gland activity to
produce 12 L (3 gallons) of noticeable sweat
– Called sensible perspiration; designed to cool body

Cold external environment
– Dermal blood vessels constrict
– Skin temperature drops to slow passive heat loss

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Cutaneous Sensations
Cutaneous sensory receptors are
part of the nervous system
– Exteroreceptors respond to
stimuli outside body, such as
temperature and touch
– Free nerve endings sense
painful stimuli

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Cutaneous Sensations
Free nerve endings – sense pain,
temperature
Merkel disk – free nerve ending associated
with epidermal cell, sustained touch, skin
indentation e.g. reading Braille
Root hair plexus – wrapped around hair
follicles, sense movement on surface e.g.
insect crawling on skin
Lamellar (Pacinian) corpuscle – deep
pressure, fast vibrations
Bulbous (Ruffini) corpuscle – sensitive to
stretch e.g. pulling of skin

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Skin Structure

Hair shaft

Dermal papillae
Epidermis
Papillary
layer Sweat pore

Appendages of skin
Dermis
Reticular Eccrine sweat gland
layer Arrector pili muscle
Sebaceous (oil) gland
Hair follicle
Hair root

Subcutaneous
tissue(hypodermis;
not part of skin)

Dermal vascular plexus
Nervous structures
Sensory nerve fiber Adipose tissue
with free nerve
endings
Lamellar corpuscle
Hair follicle receptor
(root hair plexus)

Figure 5.1 Skin structure.
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Metabolic Functions
Skin can synthesize vitamin D needed for calcium absorption in intestine

Chemicals from keratinocytes can disarm some carcinogens

Keratinocytes can activate some hormones
– Example: convert cortisone into hydrocortisone

Skin makes collagenase, which aids in natural turnover of collagen to prevent wrinkles

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Blood Reservoir
Skin can hold up to 5% of the body’s total blood volume

Skin vessels can be constricted to shunt blood to other organs, such as an exercising
muscle

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Excretion
Skin can secrete limited amounts of nitrogenous wastes, such as ammonia, urea, and
uric acid
Sweating can cause salt and water loss

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5.9 Skin Cancer and Burns
Skin can develop over 1000 different conditions and ailments

Many internal diseases reveal themselves on skin

Most common disorders are infections

Less common, but more damaging, are:
– Skin cancer
– Burns

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Skin Cancer
Most skin tumors are benign (not cancerous) and do not spread (metastasize)
Risk factors
– Overexposure to UV radiation
– Frequent irritation of skin
UV radiation damages DNA, causing formation of thymine dimers
Three major types of skin cancer
– Basal cell carcinoma
– Squamous cell carcinoma
– Melanoma

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Skin Cancer
Basal cell carcinoma
– Least malignant and most common
– Stratum basale cells proliferate and slowly invade dermis and hypodermis
– Cured by surgical excision in 99% of cases

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Skin Cancer
Squamous cell carcinoma
– Second most common type; can metastasize
– Involves keratinocytes of stratum spinosum
– Usually is a scaly reddened papule on scalp, ears, lower lip, or hands
– Good prognosis if treated by radiation therapy or removed surgically

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Skin Cancer
Melanoma
– Cancer of melanocytes; is most dangerous type because it is highly metastatic and
resistant to chemotherapy
– Treated by wide surgical excision accompanied by immunotherapy
– Key to survival is early detection: ABCD rule
 A: asymmetry; the two sides of the pigmented area do not match
 B: border irregularity; exhibits indentations
 C: color; contains several colors (black, brown, tan, sometimes red or blue)
 D: diameter; larger than 6 mm (size of pencil eraser)
 E: evolution or evolving changes over time

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Photographs of Skin Cancers

(c) Melanoma

Figure 5.11c Photographs of skin cancers.
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Burns
Tissue damage caused by heat, electricity, radiation, or certain chemicals
– Damage caused by denaturation of proteins, which destroys cells

Immediate threat is dehydration and electrolyte imbalance
– Leads to renal shutdown and circulatory shock

To evaluate burns, the Rule of Nines is used
– Body is broken into 11 sections, with each section representing 9% of body surface
(except genitals, which account for 1%)
– Used to estimate volume of fluid loss

Add front and back for:
- Chest (9%) and upper back (9%)
- Abdomen (9%) and lower back (9%)

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Burns
Burns can be classified by severity
– First-degree
 Epidermal damage only
– Localized redness, edema (swelling), and pain
– Second-degree
 Epidermal and upper dermal damage
– Blisters appear
– First- and second-degree burns are referred to as partial-thickness burns
because only the epidermis and upper dermis are involved

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Burns
Burns can be classified by severity (cont.)
– Third-degree
 Entire thickness of skin involved (referred to as full-thickness burns)
 Skin color turns gray-white, cherry red, or blackened
 No edema is seen and area is not painful because nerve endings are
destroyed
 Skin grafting usually necessary

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Partial-Thickness and Full-Thickness Burns

1st-degree burn

2nd-degree burn

(a) Skin bearing partial-thickness
burn (1st- and 2nd-degree burns)

3rd-degree burn

(b) Skin bearing full-thickness
burn (3rd-degree burn)

Figure 5.12 Partial-thickness and full-thickness burns.
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Burns
Burns are considered critical if:
– >25% of body has second-degree burns
– >10% of body has third-degree burns
– Face, hands, or feet bear third-degree burns

Treatment includes:
– Debridement (removal) of burned skin
– Antibiotics
– Temporary covering
– Skin grafts

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Copyright

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