Integumentary system
(Integumentum commune)
=
Skin and accessory structures
Aleš Hampl
December 2021
Integumentum
commune
=
Body coverage
Tela subcutanea
=
Subcutis - Hypodermis
Cutis
=
Skin
Epidermis = keratinizing stratified
squamous epithelium
Dermis = fibrous connective tissue
Functional unit
Largest body system
16% of body weight
1,5 to 2 m2
• hairs and nails
• skin glands (sebaceous + sweat)
• mammary gland
Accessory structures
Skin – overall composition
• Epithelial – outer layer
• Connective – underlies dermis
• Smooth Muscle – goose bumps
• Nervous – sensory receptors
Skin = Combination of 4 main tissues
Functions of the skin
1. Regulation of body temperature
Cellular metabolism produces heat as a waste product .
High temperature
dilate surface blood vessels
sweating
Low temperature
surface vessels constrict
shivering
2. Protection
physical abrasion
dehydration
ultraviolet radiation
3. Sensation
touch
vibration
pain
temperature
4. Excretion
5. Immunity/ Resistance
6. Blood Reservoir
8-10 % in a resting adult
7. Synthesis of vitamin D
uv light
aids absorption of calcium
Epidermis - Layers
• dead, flat cells full of keratin (25 to 100 layers)
• corneodesmosomes
• polar lipids - ceramides
5. Stratum corneum
• more apparent in thick skin
• 3-5 layers of clear cells
• transitional state
4. Stratum lucidum
3. Stratum granulosum
2. Stratum spinosum
1. Stratum basale (germinativum)
Desquamation=Maturation(about25days)
• collumnar cells – one layer (keratines 5 and 14)
• stratum germinativum
• the only proliferating cells (stem, progenitor)
• hemidesmosomes
• polygonal cells (keratines 1 and 10)
• 8-10 layers of keratinocytes
• desmosomes – shrinkage - spines
Keratinizing squamous stratified epithelium
(keratinocytes – 4 or 5 layers)
• 3-5 layers
• tight junctions = zonulae accludentes
• keratohyalin found in granules
• cells beginning to die
• keratohyalin and lamellar granules
Easy to remember - Mnemonic
Cancel
Lab !!!
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Some
Beer !!!
Corneum
Basale
Spinosum
Lucidum
Granulosum
Epidermis - Thin x Thick skin
• entire body except thick skin areas
• typical rhomboid area organization
• stratum corneum – less than 25 layers of cells
• stratum lucidum is absent
• accessory struct.: sweat gl. + sebaceous gl. +
hairs (except on lips, glans penis, labia minora)
Thin skin
Epidermis 50 – 100 mm
Thick skin
Epidermis 500 – 1000 mm
• palms of hands and soles of feet = acral skin
• skin ridges
• stratum corneum – more than 100 layers of cells
• stratum granulosum – expanded
• accessory struct.: - eccrine glands only
Epidermis
Epidermis - Cell to Cell Adherence
Basement Membrane
Zonula adherens: Ca++ dependent
cadherins that connect to actin
Zonula occludens: tight junctions
prevent diffusion across cells
Macula adherens: made of
desmosomes
Gap junctions: communication for
electric / metabolic function
Hemidesmosomes: connect cells
to basal membrane
Junction: Dermis – Epidermis
Hemidesmosomes
Epidermolysis bullosa
Stratum basale
Stratum spinosum
Dermal papilla
(cross section)
Dermis
Epidermis – Stratum spinosum - Desmosomes
Epidermis - Cell to Cell Adherence
Epidermis – Non-keratinocyte cells
• Keratinocytes - 90%
– produce keratin
• Melanocytes - 8 %
– produces melanin pigment
– melanin transferred to
other cells with long cell
processes
• Langerhans cells
– from bone marrow
– provide immunity
• Merkel cells
– in deepest layer
– form touch receptor with
sensory neuron
Epidermis – Melanocytes 1
Melanocyte
Melanine
Melanocytes: clearish cells in
basal layer with dark nuclei ; ratio
of 1 : 40 – epidermal melanin unit.
Epidermis – Melanocytes 2
Epidermis – Melanocytes 3
Epidermis – Melanocytes 4 - Pigments
Three pigments contribute to skin color
Melanin – yellow to reddish-brown to black pigment, responsible
for dark skin colors
(Freckles and pigmented moles – result from local accumulations of
melanin)
Carotene – yellow to orange pigment, most obvious in the palms and
soles of the feet
Hemoglobin – reddish pigment responsible for the pinkish hue of
the skin
Do some people have more melanocytes than other people?
NO !!!!
Epidermis – Langerhans cells + Merkel cells
Langerhans cell
Merkel cell
combines with
disclike sensory
nerve endings
to make Merkel’s
discs
immune reaction that effects the skin
and may serve defense mechanism for the body
Migrate to lymph nodes
Dermis (Corium) 1
Everything below the dermal-epidermal junction / basement membrane
Connective tissue layer with contains blood vessels, nerves, sensory receptors, adnexal
structures
Dermis 2
= True skin – up to 4 mm on soles and palms
Papillary layer
(thin)
Reticular layer
(thick)
Papillary dermis 1
Papillary Dermis
Capillaries
• loose connective t. & elastic fibers
• dermal papillae which project into epidermis
• anchors epidermis to dermis
• contains Meissner’s corpuscles (touch)
& free nerve endings (pain&temp)
Papillary dermis 2
Two major types of fibers:
– Type I Collagen
– Elastic fibers: three types based on microfiber and elastin content
Papillary dermis 3
Epidermal ridges (palms + soles)
• reflect contours of the underlying dermal papillae
• form the basis for fingerprints (and footprints)
• increase firmness of grip by increasing friction
• Dermatoglyphics - the study of the pattern of epidermal ridges
Papillary dermis 4
Openings of sweat glands
Papilae after peeling off epidermis
Epidermal ridges
• Dense irregular connective tissue
• Sebaceous (oil) glands
• Hair follicles
• Ducts of sweat (sudoriferous) glands
• Striae or stretch marks
• Meissner’s corpuscles and Pacinian corpuscles (on lips, ext. genitalia, nipples)
Reticular dermis + Accessory structures (Dermal appendages)
Hair folliclePilar muscle
M. arrector pili
Sebaceous glands
Eccrine glands
Dermal glands
Sweat Eccrine Tubular
Apocrine Tubular to
tuboalveolar
Sebaceous Holocrine Branched
acinar
(alveolar)
Dermal glands – Eccrine sweat glands
(glandulae sudoriferae eccrinae)
• Secretory part:
Simple collumnar epithelium + myoepithelial cells
• Ductular part:
Two layered cuboidal epithelium
Release to adjust body temperature
Not on: red lips, glans penis, preputium, labia minora
Eccrine sweat glands
Three cell types
• Dark cells: pyramid shaped with secretory granules line lumen of tubule
• Clear cells: located toward basement membrane – secrete water and ions
• Myoepithelial cells: spindle shaped contractile cells
duct
secretory part
Eccrine sweat glands
duct
secretory part
Eccrine sweat glands
Dermal glands – Apocrine sweat glands
(glandulae sudoriferae apocrinae)
• Secretory part:
Simple squamous to collumnar epithelium
(depending on the secretoty cycle) + myoepithelial
cells
• Ductular part:
Two layered cuboidal epithelium
Always associated with hair follicle
Influenced by hormones (sexual scent
glands)
Only on: axilla, areola mammae, scrotum,
labia maiora, mons pubis, perianal area,
meatus acusticus, vestibulum nasi, eye lid
apocrine sweat gl.
eccrine sweat gl.
sebaceous gland.
Apocrine sweat glands
Apocrine sweat glands
myoepithelial cells
Dermal glands – Sebaceous glands
(glandulae sebaceae)
• Secretory part:
multi layered epithelium, slow adipous degeneration
(holocrine secretion)
• Ductular part:
multi layered squamous epithelium
Usually associated with hair follicles
Freely open on: red lips, glans penis, preputium, labia
minora, eye lid (Meiboms glands)
Not on: palms and soles
Simple branched acinar glands
Several acini empty into single duct
Sebaceous glands
sebaceous gland
m. arrector pili
hair follicle
Sebaceous glands
Sebaceous glands
Mammary gland
Modified and highly specialized type of apocrine sweat glands.
Parenchyma
• Ducts
• Budding surface ectoderm
• (since week 6)
Stroma
• Connective tissue
• From mesenchyme
axilo-inquinal line
Supernumerary Breasts and Nipples
• An extra breast (polymastia) or
nipple (polythelia) occurs in
approximately 1% of the female
population - inheritable.
• Supernumerary nipples are also
relatively common in males.
• Less commonly, supernumerary
breasts or nipples appear in the
axillary or abdominal regions of
females developing from extra
mammary buds that develop along
the mammary crests. They become
more obvious in women when
pregnancy occurs.
Development of the breast ductal tree
Occurs mainly after birth
At puberty changes in the hormonal secretions in females cause
further development and structural changes within the glands.
Secretions of estrogen and progesterone from the ovaries (and
later from the placenta) and prolactin from the acidophils of the
anterior pituitary gland initiate development of lobules and terminal
ductules.
Full development of the ductal portion of the breast requires
glucocorticoids and further activation by somatotropin.
Radial organization
Mammary gland - Anatomical organization
Lobe = 1 gland
• total of 15 to 20 lobes
• 1 lobe drained by 1 lactiferous duct
LACTIFEROUS DUCT
Lobule
• drained by terminal ductulus
=
Terminal ducto-lobular unit
Connective+Adipose
tissue
Sinuses (Cisterns)
Ducts
Mammary gland – After puberty – Nonlactating 1
• majority = connective tissue
• the same basic architecture as the
lactating (active) mammary gland
• Secretion parts - alveoli are not
developed, only small groups of cells at
the endings of ductuli
• Passages – branched + partly luminized
Mammary gland – After puberty – Nonlactating 2
Mammary Gland – Lactating 1
• majority = glands
• Ductuli: proliferate, branch, luminize
(estrogens)
• Secreting alveoli: proliferation, luminization
(progesterone, prolactin)
• connective tissue – only thin septa
Mammary Gland – Lactating 2
• Secretion parts: filled by secretion
(lipid droplets = apocrine, proteins =
eccrine - exocytosis)
• Passages:
Ducts at the nipple: stratified squamous
keratinizing ep.
Lactiferous sinus and the lactiferous ducts:
simple/stratified + cuboidal/collumnar ep.
Smaller ducts: simple cuboidal ep.
Mammary Gland – Lactating 3
Mammary Gland – Lactating 4
• The alveoli are composed of
cuboidal cells partially
surrounded by a meshwork of
myoepithelial cells.
• These secretory cells possess
abundant RER and mitochondria,
several Golgi complexes, many
lipid droplets, and numerous
vesicles containing caseins (milk
proteins) and lactose.
• Not all regions of the alveolus
are in the same stage of
production, because different
acini display varying degrees of
preparation for synthesis of
milk substances.
Electron micrograph of an acinar cell
Mammary Gland – Lactating 5
Mammary Gland – Involuting 1
• atrophy and degeneration of the
secretory cells
• milk biosynthesis ceases
• adipose cells occupy the empty space
• the duct system remains
• this process continues throughout
menopause
Mammary Gland – States of development
Hair – Overall compostition
Shaft: portion of hair above surface
Root: portion of hair below surface
Cuticle: outermost layer of hair
Hair follicle: invagination of epidermis
(to dermis / hypodermis)
Hair bulb: at the base of the follicle
(matrix - epithelial cells + melanocytes)
Hair papilla: projection of dermal
connective tissue into bulb - contains
blood vessels and nerves
Vellus x Terminal hairs
Hair structure 1
Garther and Hiatt, Color textbook of histology, Elsevier
ERS
IRS
CTS
cortex
Huxley + Henley layer
External root sheat
Hair structure 2
Cuticles
Internal root sheat
Hair bulb and papilla
Hair – Color and Shape
Hair growth cycle
Bulge
Active stem cells
Active papilla
Active papilla
Active papilla
Inactive papilla
Anagen AnagenAnagen Katagen Telogen
Anagen – months to years
Katagen – 3 weeks (involution)
Telogen – 3 months (resting)
Nail 1
Nail plate (body) – „str. corneum“
Nail root – proximal part of the nail plate
Nail matrix - str. basale + spinosum (dividing)
Nail bed – str. basale + spinosum
Nail 2
Area deep to the dermis
• Loose connective tissue
containing adipocytes, nerves,
sensory receptors, arteries and
veins (deep rete cutaneum)
• Provides a flexible attachment
to the underlying muscle and
fascia
Pacinian Corpuscle
Hair bulb in the
subcutis of the scalp
Adipocytes
Subcutis - Hypodermis
Skin development
Ectoderm
• Epidermis
• Accessory structures
Mesenchyme
(from mesoderm-dermatomes +
unsegmented mesoderm-somatopleura)
• Dermis
• Hypodermis
A – Month 1 – simple surface ektoderm
B – Month 2 – two layered epithelium:
basal layer + periderm (epitrichium)
C – Month 3 – basal + intermediary +
periderm layers
(week 10-17 – formation of dermal ridges)
D – Month 5 (end) – periderm replaced
by stratum corneum
Skin wound healing 1
Shallow cuts Deeper wounds
cell migration contact inhibition
Skin wound healing 2
Shallow cuts Deeper wounds
Blood clot
Inflammatory phase Migratory phase Maturation phase
+
Proliferative phase
Fibrin forms clot Fibroblasts make granulation tissue
hypertrophic scar = keloid
Thak you for your attention!
Questions and comments at:
ahampl@med.muni.cz