BIOL 1800 Lecture 7 Skin and Thermoregulation 2024 PDF

Summary

These lecture notes cover skin structure, functions, and thermoregulation, including topics like skin color, vitamin D production, and the integumentary system. The document is presented as a slide presentation geared towards students in a BIOL 1800 course in 2024.

Full Transcript

Lecture 7:
Skin
Thermoregulation
BIOL 1800
Dr Marie Conway
Learning Outcomes
At the end of this lecture you will be able to:
Outline the functions of the skin

Outline the Histology and Physiology of the Skin

Explain the role of the Skin in:
skin colour
Vit D production
The Integument
The Integument system accounts for 16% of body weight
Is composed of the cutaneous membrane and accessory
structures
Skin - most accessible organ and the largest Psoriasis/
Dermatitis/
Hair Melanoma

Sweat glands Accessory structures
Nails and
Cutaneous membrane –Epidermis/Epithelium and Dermis/CT
Functions of Skin
Protection of underlying organs from dehydration, infection, abrasion, UV
damage and cold/heat
Maintenance of normal body temperature through insulation or
evaporative cooling
Synthesis of Vitamin D3 (when exposed to sun)
Excretion of water, salts and oils
Production of melanin to protect underlying tissue from UV radiation
Production of keratin which repels water and protects against abrasion
Sensory Perception at the tactile receptors and free nerve endings
Energy Storage (of lipid) in adipocytes in the dermis and in adipose tissue
in the subcutaneous layer
Coordination of immune response to pathogens and cancers in the skin
The Integumentary System
Skin Histology

- superficial
layer

= hypodermis
Cutaneous membrane
Is skin, surface of the body
Thick, relatively waterproof, and dry
Epithelium in epidermis and CT in the Dermis

CT connects epith to underlying
structures

Loose Aerolar first and then Dense irreg
CT proper

Copyright © 2009 Pearson Education, Inc.,
publishing as Pearson Benjamin Cummings
Skin Histology
3 Layers
1. Epidermis – keratinised
stratified squamous
epithelium, basement
membrane (supported by
areolar CT of dermis)
2. Dermis – composed of
loose areolar CT and
dense irregular CT proper
with accessory structures
3. Hypodermis or
subcutaneous layer (loose
CT proper). (aka Cutaneous membrane includes the Epidermis and Dermis.
superficial fascia) CT fibres are continuous between Dermis and Hypodermis
and between the hypodermis and the deep fascia.
Types of skin cells
There are 3 main types of cells in the epidermis:
Squamous cells: These are flat cells in the outer/superficial part of the epidermis that
are constantly shed as new ones form
Basal cells: These cells are in the lower/deeper part of the epidermis, called the basal
cell layer
Melanocytes: These cells make the brown pigment called melanin, which gives the
skin its tan or brown colour. Melanin acts as the body’s natural sunscreen

The epidermis is separated from the deeper layers of skin by the basement
membrane
When a skin cancer becomes more advanced, it generally grows through this barrier
and into the deeper layers

Epidermis may also have cells of the immune system and sensory nerve cells
Thick or Thin Skin
Skin is divided into:
Thick skin on the palms of the hand and soles of the feet (5 epidermal layers)
Thin skin on the rest of the body (4 epidermal layers)
Thick/Thin skin refers to the thickness of the epidermal layer.
Thin skin on most of body
(0.08mm)
Thick skin on soles of feet
and hands (0.5mm)
The Epidermis
Stratified squamous epithelium (keratinised)
Epithelial cells called Keratinocytes
4 or 5 layers
Difficult to distinguish with light microscope
Gives skin properties of water resistance; protection from microorganisms
and abrasion; gland secretions; support some sensory cells
Blister – water trapped between layers of epithermis
The fingerprint is a pattern of Epidermal ridges
These ridges increase the surface area for contact between the epidermis and dermis
and have a unique pattern
Layers of the Epidermis
The Epidermis has 4 (thin) or 5 (thick) layers:
1. Stratum Corneum
has 15 – 30 rows of flat, dead cells completely filled with
keratin. This layer is continually shed and replaced
2. Stratum Lucidu
only found in thick skin of the palms and soles. They are flat
densely packed cells - 5. layer of the thick skin Cover or Let’s
3. Stratum Granulosum Get
has 3 – 5 rows of flattened cells with degenerating nuclei. Sun
These cells produce keratin Burned
4. Stratum Spinosum
has 8 – 10 rows of polyhedral cells tightly packed
5. Stratum Basale or stratum germinativum There are tight connections between
the deepest layer; has stem cells that continually divide. Some the cells that leads to loss as sheets of
cells move to the surface – squamous cells. Others give rise to skin.
sweat or oil glands. Melanocytes may be found in this stratum
Layers of the Epidermis
The Dermis
Between epidermis and subcutaneous layer
A connective tissue layer containing collagen and elastin fibres to support:
blood vessels
nerves
glands
hair follicles
adipocytes
The dermis is subdivided into the outer Papillary region and the inner Reticular region

Papillary Region
Loose areolar CT (elastin)
Loops of capillaries (thermoregulation), lymphatic vessels, sensory nerve fibres
Meissner’s corpuscles (touch receptors)
Is ridged
The Dermis
Reticular Region
Dense irregular CT proper (collagen and elastin)
Thickness varies
Network of fibres
Spaces occupied by adipose tissue, hair follicles, nerves and oil glands and
ducts of sweat glands

This reticular region enables the skin to be:
Strong
Extensible (stretchy in pregnancy, oedema and obesity)
Elastic (return to original shape after stretch or contraction)
The reticular region is attached to the underlying organs, such as bone and
muscle, by the subcutaneous layer (superficial fascia)
The Skin and Water Loss
The outermost layer of skin is water-resistant (not waterproof)

0.5L of water migrate through the epidermis and is lost by evaporation 
This is called insensible perspiration

Sweating leads to additional fluid loss (and electrolyte loss). Sweating is
varied as required for core temperature regulation called sensible
perspiration.
Daily Loss of H20 (ml)
Normal Temp Hot weather Prolonged heavy exercise
Skin 350 350 350

Lungs 350 250 650

Urine 1400 1200 500

Sweat 100 1400 5000

Faeces 100 100 100

Total 2300 3300 6600
Subcutaneous Layer
Also called hypodermis – or superficial fascia
Lies deep to the dermis
Connects the skin to the underlying tissue
The CT of the dermis and subcutaneous layers are interwoven
Quite elastic, consists primarily of adipose tissue
Functions to allow independent movement, as an energy store and to
insulate the body
Subcutaneous layer has sensory nerve endings called lamellated or
Pacinian corpuscles that are sensitive to touch (pressure and vibration)
Subcutaneous fat deposition - changes as we grow

NB in babies for insulation - shock absorbtion, more brown adipocytes → thermoregulation

Hormone dependant (puberty) -- female-hips, thighs
male- neck arms
Varies in location; with:
None on backs of hand and top of feet
Pear or apple shape body - very little, temperature - more, → obesity

hip-female abdomen-male

Fat deposits in the body are:
Subcutaneous - we can pinch them
Visceral - around organs
Interscapular betweee shoulderblades
Adipose tissue may be white or brown AbdRaboh NR, Asif AM, Riaz S, Ahmed HA. Brown Adipose Tissue, Thermogenesis, and
Obesity: A Review of Literature. Glob J Med Therap. 2020;2(1):1-9
Exocrine Gland structure
Sweat (Sudoriferous) Glands
Skin contains two types of sweat glands:
- it was thought they
Apocrine Sweat Glands use apocrine secretion,
but they use merockne Merocrine/eccrine Sweat Glands
Simple branched tubular glands. Coiled tubular gland
Only found in axilla, pubic region distributed widely in body (NB
and areolae of breast. soles and palms)
Secretary portion in dermis or Secretary portion in subcutaneous
subcutaneous. layer
Excretory duct opens into hair Excrete onto surface
follicle. Functions include:
Begin to function at puberty Cooling surface of skin; excreting
Viscous secretion water and electrolytes; protection
from environmental hazards
Sweat (Sudoriferous) Glands
Sebaceous (oil) glands
Holocrine glands
Discharge oily lipid secretion into hair follicles
Produce sebum - protects skin from drying out
Other Integumentary Glands
Ceruminous glands
Modified sudoriferous (sweat) glands
Simple, coiled tubular glands
Present in the auditory canal (ear)
Secretory portion in subcutaneous layer
Excrete onto surface or into sebaceous glands.
Combined secretions of sebaceous and ceruminous glands give rise to ear wax (cerumen)
Function (along with hairs) to prevent entrance of foreign bodies, preventing them reaching
the ear drum

Mammary glands
Anatomically related to Apocrine glands
Development and secretion controlled by interaction between sex hormones and pituitary
hormone
Control of Secretion of Glands - Nervous control
Sebaceous and Apocrine → collectively turned on/off by Autonomic
Nervous System (e.g. in stressful situations)

Merocrine → areas of the body selectively turned on (sweaty hands) or all
activated by ANS (autonomic nervous system)

During thermoregulation to cool the body all merocrine glands switched on
Thermoregulation is the homeostatic process of maintaining temperature
Skin Colour
Skin colour is due to three factors:
Melanin in the epidermis
Carotene in the dermis and epidermis
Capillaries in the dermis
Melanin
Produced by melanocytes
Amount varies to give skin colour from pale
yellow to black
Found in basale and spinosum layers
Synthesised in melanocytes of stratum basale
Total absence of melanocyte activity results in
Albinism - cell are not capable of productions of melanin
Patchy absence of melanocyte activity results in
Vitilgo
Patchy production of melanocytes results in
freckles (after exposure to sun)
Carotene
Orange-yellow pigment that normally accumulates in epidermal cells
Found in stratum corneum and fatty areas of the deep dermis and subcutaneous layer
Together with melanin, carotene gives yellowish hue to their skin
Carotene also found in vegetables
Carotene → Vitamin A
Essential for maintenance of epithelia
Photoreceptor pigments in the eye

Capillaries
Caucasian Skin Colour Port wine stain – unusual dense
Due to blood capillaries in the dermis collection of blood vessels in the dermis
Redness not masked by pigments
The Epidermis and Vitamin D3
Limited exposure to sunlight is very beneficial
UV light on the stratum spinosum and basale
result in Vit D3 production
7-dehydrocholesterol is converted to Vit D3 or
cholecalciferol in the skin
In the Liver this is converted to 25-hydroxy-D3
This then is converted to calcitriol, the active
form of the vitamin, in the kidney
Calcitriol is essential for Ca++ and PO4-
absorption from the GIT
Deficiency in Vit D result in abnormal bone
development in children (Rickets) and
(Osteomalacia) in adults
Thermoregulation
Learning Outcomes
At the end of this lecture you will be able to:
Give an account of vascular and nervous supply of the skin

Explain the physiology and importance of thermoregulation:
Mechanism of heat gain
Mechanism of heat loss

Outline the physiology and importance of Pyrexia
Dermal Circulation and Innervation
2 major functions of blood in skin:
Nutrition of the skin tissues
Heat loss

Dermal circulation:
Cutaneous plexus
A network of capillaries
Located between subcutaneous layer and dermis
Supplies adipocytes, hair follicles and sweat glands
Papillary plexus
Formed from branches of the cutaneous plexus
Gives rise to papillary loops
 Skin Vascularity
Arteriovenous Shunts
Shunts blood between arteries and veins to conserve
heat
Have muscular walls innervated by the sympathetic
division of the ANS
2.
Activation of sympathetic division results in blood 1.

flow to plexus and heat loss.
Blood Flow to Skin and Metabolism is influenced by
To of surroundings.
temperature

Nervous Control nerves

2 Vasodilator control - reduce body tem.
1 Vasoconstrictor control - maintain core body tem.
when we're cold

https://www.science20.com/news_articles/fibromyalgia_not_all_head
_its_skin_paper_concludes-114985
Innervation and Skin
Epidermis contains sensory nerve endings that provide sensations of pain and
temperature
Sensory Nerves
From pain, temp, and touch receptors
Free nerve endings (dendrites of sensory nerve)
or sensory receptors:
Merkel Discs
Messiners Corpuscles – sensitive to light touch (in dermal papillae)
Pacinian corpuscles - sensitive to deep pressure and vibration (in reticular
layer)
Motor Nerves
To sweat glands
To erector pili muscle
To blood vessels
Nerves in Thermoregulation
Epidermis contains sensory nerve endings that provide sensations of pain
and temperature
Sensory Nerves
Detect increase or decrease in skin temperature
Carry the information to the hypothalamus of the brain for
thermoregulation
Motor nerves
Activation of Sweat glands and pili muscle
Contraction of skeletal muscle - shivering
Shunting of blood in skin and limbs
Metabolic Rate and Heat production
breaking down making
Metabolic rate is the sum of all the catabolic and anabolic processes
Rate at which heat is produced in the body
The heat is produced as food is oxidised
Energy from food = ATP + Heat
Significant amount of energy used to synthesise ATP, but much of it is lost to
environment as heat
The heat produced is carried in H2O (plasma) throughout the body
For body temperature to remain constant, heat must be lost to the
environment at same rate it is generated
Factors that Affect Metabolic Rate
Exercise may increase BMR x15% (20% in well trained athlete)
Nervous system, in stress ANS releases noradrenaline which increases BMR
Hormones; adrenaline, noradrenaline, hGH, testosterone and thyroid
hormones increase BMR
Body To; a 1oC rise in body To increases BMR X 10% (fever)
Digestion of food increases MR X 10-20% (diet induced thermogenesis)
Age; MR is higher in children
Other factors:
Sex (female MR is lower except in pregnancy)
Climate (↓ if hot)
malnutrition (↓ if malnourished)
Homeostasis of Body To Regulation
Core To is the body To below the skin
Shell To is the surface To
Usually the core To is higher
If the heat loosing mechanisms give off more heat than is produced the core
To ↓
If heat producing mechanisms generate more heat than is lost the core To ↑

Importance of temperature:
Too high core To kills by denaturing protein (it also causes convulsions)
Too low core To causes arrhythmias (it also causes disorientation)
Core Temperature kept between 36.7oC and 37.2oC by homeostatic control
 Physics of Heat Loss
Four processes of heat exchange with environment:
Evaporation
Radiation
Absorbs energy and cools surface where
Objects warmer than environment lose
evaporation occurs
heat as radiation
Insensible water loss – each hour 20-
Heat from sun is radiant heat
25ml of water crosses epithelia and
More than 50% of heat you lose indoors is
evaporates from alveolar surfaces and
lost through radiation
surface of skin (accounts for 20% of - object warms the environment
boy’s average indoor heat loss).
Sensible heat loss – evaporation of
sweat
- boiling water
Convection
Heat loss to cooler air that moves
Conduction
across the surface of your body. As
Direct transfer of heat through
body loses heat to air next to skin,
physical contact e.g. sitting on a
the air warms and rises away from
cold chair
skin surface, and is replaced by
Not effective way of gaining or
cooler air which is then warmed
losing heat – impact depends on the
Accounts for roughly 15% of
temperature of the object and the
body’s heat loss indoors
amount of skin surface area - two storage house- upstairs warmer
involved
- tuch
Heat loss
Hypothalamic Thermostat
Tries to keep heat production and
heat loss in balance – i.e. maintain Figure 14–10a The Hypothalamus in Sagittal Section
Temp range (slide 40)
Sensory thermoreceptors (in skin,
mucous membrane and in
hypothalamus) bring information to
hypothalamus of the brain
Hypothalamus has a special region
called the Preoptic area output that
has:
heat losing centre
heat production centre Copyright © 2014 Pearson Education, Inc.

Preoptic area - regulates body temperature
Heat Loss Centre (Heat loss)
Heat loss centre stimulated when temperature at pre-optic area rises above its set
point

Mechanisms for heat loss: example-being out on a hot day
1. Vasodilation, inhibition of the ANS vasomotor output. This increases blood flow to
the skin, warms the skin and increases heat transfer
2. Perspiration, activation of the sweat glands and evaporation of H2O cools the skin
3. Decreased Metabolic Rate and Decreased Shivering, mediated through hypothalamic
reflexes
4. Increased Respiration, depth of breathing increased and breathing through the mouth
will increase evaporation
5. Behavioural change – seek shade or remove clothing
Heat Promoting Centre (Heat gain)
Function of heat-promoting centre is to prevent hypothermia, or below-normal
body temperature
When temperature at pre-optic area drops below acceptable level, heat-loss
centre inhibited, and heat-gain centre activated
Mechanisms of heat gain: example-cold environment
1. Vasoconstriction → increase vasomotor output (decrease blood flow to skin
surface)
2. Skeletal muscle by shivering increases muscle tone and increases heat
production.
3. Sympathetic release from adrenal gland (adrenaline and noradrenaline
stimulate cellular metabolism, i.e. chemical thermogenesis)
4. Thyroxine increases cellular metabolism by increasing catabolic reaction
5. Behavioural responses – put on more clothing or move to a heated area
Thermogenesis
Shivering Thermogenesis
muscle metabolism in contraction/relaxation
Gradual increase in muscle tone increases energy consumption of skeletal muscle
tissue  more energy used the more heat produced
Heat produced warms deep vessels where blood has been shunted
Shivering can increase rate of heat generation as much as 400%

Non Shivering Thermogenesis /brown adipose tissue

increased metabolism (by liver) and BAT adipose breakdown
Involves release of hormones that increase tissue metabolic activity
Adrenal medulla – releases epinephrine, increasing glycogenolysis
Thyroid gland – releases thyroxine, increasing nutrient catabolism
Heat loss and heat gain
Abnormal Body Temperature - Pyrexia = FEVER

Fever
Usually bacterial or virus stimulated
Other causes are heart attack, tumour, surgery or trauma

Mechanism:
Phagocyte ingests bacteria
↓
Interleukin-1 secreted and circulated in the blood
↓
Prostaglandin production in the hypothalamus
↓
Resetting of To thermostat
Fever
Stages of fever
Core To thermostat ↑ 39.4oC, → activation of the heat production mechanism resulting
in vasoconstriction, increased metabolic rate and shivering → Chill
When skin To is increased to 39oC the chill disappears
When stress is removed the thermostat is reset → the heat losing mechanism goes into
operation. Resulting in Vasodilation and sweating. Crisis → To is falling - temperature breaks/ gets worse

Why is To increased? Complications of fever
The high To is beneficial: Dehydration
Inhibits growth of bacteria Acidosis – Blood pH
WBC delivered to site of infection faster
Permanent brain damage
Increases Ab production
Increases rate of repair Death of To rises to 44.5 – 45.5°C
Heat Cramp
Result of profuse sweating that removes NaCl from the body
Salt loss causes painful muscle contraction called heat cramp
Cramp in muscles used in working only felt when relaxed
Salted liquid relieves cramp.
Heat Exhaustion
Difficulty in maintaining blood volume
Normal or slightly low To.
Cool clammy skin due to loss of fluid and electrolytes as sweat.
Muscle cramps, dizziness, vomiting, fainting, low blood pressure and low
blood volume.
Body cannot compensate for low blood pressure.
Relieved by rest and salt tablets.
Heat Stroke (sunstroke)
Occurs when To and relative humidity are high.
Body heat cannot be lost by evaporation and radiation
Decreased blood flow to skin and decreased sweating → Core To rises.
May destroy brain cells.
Relieved by immersion of the body in cool water (increased conduction)
and rehydration.
 Response to Heat Gain: how to Response to Heat Loss: how to raise
lower body temp body temp
Vasomotor Center inhibited Vasomotor Center stimulated
Vasodilation occurs Vasoconstriction occurs
Skin Colour changes Skin cools
Heat lost through radiation and Heat not lost because blood shunted
convection away from skins surface
Sweat production increases Sweat production decreases
Heat lost through evaporation Shivering thermogenesis
Increased respiration and metabolism Generates heat
dec Non-shivering thermogenesis
Behaviour changes Generates heat
= Overall Loss of Heat = Overall Gain of Heat