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Inflammation and Wound
Healing
SCI1018-N PATHOLOGY
Dr. Ahmad Khundakar

Learning outcomes
• At the end of the lecture you should be able to:
• Understand causes and mechanisms behind
inflammation
• Identify types of inflammation
• Examine the main processes underlying wound
healing, including phases and factors delaying
wound healing
• Describe the causes and mechanisms behind
fibrosis

Inflammation
• Inflammation response of
vascularised tissues to infection and
damaged tissue
• Allocates cells and molecules of host
defence to sites where they are
needed to eliminate agents (e.g.
microbes, toxins)
• Protective response essential for
survival

Causes of Inflammation
•

Infection Different pathogens elicit variable
inflammatory response (e.g. staphylococcus
aureus usually acute inflammatory response,
mycobacterium leprae (leprosy) typically
persistent infection and chronic inflammation)

•

Tissue necrosis
•

Occurs regardless of cell death
•

•

Foreign bodies
•

•

Splinters, dirt, sutures

Immune reactions (hypersensitivity)
•

•

E.g. ischaemic damage

Autoimmune diseases (e.g. psoriasis, arthritis)

Fibrosis

Arrows: contiguous cells, cell swelling,
loss of detail, neutrophils and cell debris
(Elmore et al, 2014)

Clinical Signs of Inflammation?

Clinical Signs of Inflammation?

Clinical Signs of Inflammation?
• Heat: Increased chemical activity
and blood flow to skin surface
• Redness: Caused by dilatation of
arterioles/ increased blood flood
• Swelling: Caused by
accumulation of blood and
damaged tissue cells
• Pain: Injury of nerve fibres,
pressure of haematoma, also due
to chemical irritants
• Loss of function: Increased
pain/swelling

Types of
inflammation

Acute Inflammation
• Usually short duration (up to a few
days)
• Characterised by accumulation of
neutrophils (acute inflammatory
cell)
• Sometimes leads to formation of
pus (tissue fluid, dead neutrophils
and microorganisms)

Chronic Inflammation
• Longer duration (> 1 week)
• Accumulation of:
•
•

Specialised immune cells (e.g. B and T
lymphocytes)
Plasma cells that secrete
immunoglobulin and macrophages

• Repair of damaged tissue after cause
of inflammation removed
•

May produce new blood vessels
(angiogenesis) and fibrosis

Macrophage

Can you identify the
blood cells in the
film?

Chronic Inflammatory Diseases ⎼ Asthma
• Chronic inflammatory disease of
the airway leading to:
•
•
•
•

Airway hyperresponsiveness
Obstruction
Mucus hyper-production
Airway wall re-modelling
•
•

Characterised by thickening and
narrowing of the airway walls
Transition from epithelial to
mesenchymal tissue

Chronic Inflammatory Diseases ⎼ Asthma
• Chronic inflammatory disease of
the airway leading to:
•
•
•
•

Airway hyperresponsiveness
Obstruction
Mucus hyper-production
Airway wall re-modelling
•
•

Characterised by thickening and
narrowing of the airway walls
Transition from epithelial to
mesenchymal tissue (EMT)

Thinking back to last
week’s lecture what kind of
pathological adaptation is
this?

Chronic Inflammatory Diseases ⎼ Inflammatory
Arthritis

Chronic Inflammatory Diseases ⎼ Inflammatory
Arthritis
• Characterised by:
•
•
•
•
•
•
•

Pain
Swelling
Stiffness
Diurnal pattern
Erythema
‘Heat’
Systemically unwell

• Anti-inflammatories helpful
•

Ibuprofen, naproxen

Chronic Inflammatory Diseases ⎼ Rheumatoid Arthritis
•
•
•
•

Chronic
Inflammatory
Deforming
Polyarthritis: symmetrical in
proximal interphalangeal
(PIP)/metacarpophalangeal
(MCP)/wrist/elbow/
shoulder/knee/ankle/foot
• Disability
• Rheumatoid factor +ve

Rheumatoid Arthritis
Testing
• Physical testing of joints and limbs
• Blood tests
• Elevated erythrocyte sedimentation rate
(ESR, or sed rate)
• C-reactive protein (CRP)
• Rheumatoid factor
• Anti-cyclic citrullinated peptide (antiCCP) antibodies

The graphs below are taken from a patient with elevated C-reactive
protein (CRP) and erythrocyte sedimentation rate. Do you think this
could be an indication of osteoarthritis? Outline your reasoning

Wound Healing
• Refers to a living organism's replacement of
destroyed or damaged tissue by newly
produced tissue
•

Wound - break in the skin or an organ caused by
violence or surgical incision

• Complex biological process consisting of four
stages:
•
•
•
•

Haemostasis
Inflammation
Proliferation
Remodeling

Haemostasis
• Refers to the normal response of the
vessel to injury by forming a clot to
limit haemorrhage
• Occurs when blood is present
outside of the body or blood vessels
• innate response for the body to stop
bleeding and loss of blood
• Without the ability to stimulate
haemostasis the risk of haemorrhaging
increases

Haemostasis
• Refers to the normal response of the
vessel to injury by forming a clot to
limit haemorrhage
• Occurs when blood is present
outside of the body or blood vessels
• innate response for the body to stop
bleeding and loss of blood
• Without the ability to stimulate
haemostasis the risk of haemorrhaging
increases

Three stages of haemostasis:
1, Vascular spasm (vasoconstriction) produced by vascular smooth muscle cells
controlled by the vascular epithelium. In
initiated by sympathetic pain receptors.

Haemostasis
• Refers to the normal response of the
vessel to injury by forming a clot to
limit haemorrhage
• Occurs when blood is present
outside of the body or blood vessels
• innate response for the body to stop
bleeding and loss of blood
• Without the ability to stimulate
haemostasis the risk of haemorrhaging
increases

Three stages of haemostasis:
1, Vascular spasm (vasoconstriction) produced by vascular smooth muscle cells
controlled by the vascular epithelium. In
initiated by sympathetic pain receptors.
2, Platelet plug formation - Platelets
adhere to damaged endothelium to form a
platelet plug (primary haemostasis)

Haemostasis
• Refers to the normal response of the
vessel to injury by forming a clot to
limit haemorrhage
• Occurs when blood is present
outside of the body or blood vessels
• innate response for the body to stop
bleeding and loss of blood
• Without the ability to stimulate
haemostasis the risk of haemorrhaging
increases

Three stages of haemostasis:
1, Vascular spasm (vasoconstriction) produced by vascular smooth muscle cells
controlled by the vascular epithelium. In
initiated by sympathetic pain receptors.
2, Platelet plug formation - Platelets
adhere to damaged endothelium to form a
platelet plug (primary haemostasis).
3, Clot formation - clotting factors activated
in a sequence of events known as
'coagulation cascade’ - leads to the
formation of fibrin ‘mesh’ from inactive
fibrinogen plasma protein (holds platelet
plug in place)

Haemostasis
• Refers to the normal response of the
vessel to injury by forming a clot to
limit haemorrhage
• Occurs when blood is present
outside of the body or blood vessels
• innate response for the body to stop
bleeding and loss of blood
• Without the ability to stimulate
haemostasis the risk of haemorrhaging
increases

Inflammation
• ‘Clean-up- phase
• Damaged and dead cells are cleared
out, along with bacteria and other
pathogens or debris
• Phagocytosis - white blood cells engulfs
destroys debris and pathogens
• Platelet-derived growth factors released
into the wound
•

cause migration and division of platelets

Proliferation
• Angiogenesis, collagen deposition,
granulation tissue formation,
epithelialisation and wound
contraction
• Fibroblasts grow and form a new,
extracellular matrix by excreting
collagen and fibronectin
• Epithelial cells proliferate and move
to top of wound bed

Driskell lab, Washington State University

Remodelling (maturation)
• Collagen is realigned along tension lines
• Cells no longer needed are removed by apoptosis

The histology picture is taken from the left ventricle of patient with a history of heart disease.
Which of the following statements do you think is true?
He had a myocardial infarction (heart attack) yesterday
He had a myocardial infarction 5 days ago
He had a myocardial infarction 2 months ago
He hasn’t had a heart attack!

Acute versus Chronic Wounds

Factors Delaying Wound Healing
General factors:

Local factors:
•
•
•

Type, size, location of wound
Apposition, lack of movement
Infection: suppuration, gangrene, tetanus

•
•

chronic diseases (e.g. diabetes,
rheumatoid arthritis)

(secondary haemorrhage)

•
•
•

Blood supply: arterial, venous
Foreign material: debris, glass, sutures,
necrotic tissue
Radiation damage

Age
General state of health

•
•
•
•

Drugs (e.g. steroids)
General cardiovascular status
General dietary deficiencies (e.g. protein)
Specific dietary deficiencies
•
•

vitamin C
sulphur-containing amino acids

Chronic Wounds Linked to Infections

Chronic Wounds Diabetic
•
•

Hyperglcaemia can lead
to poor blood circulation
needed for wound healing
Incomplete wound
healing, increases the risk
of:
•
•
•
•

Fungal infections
Bacterial infections
Gangrene
Poor remodelling

Complications in Wound Repair
•

Insufficient fibrosis:
•
•
•

•

Excessive fibrosis:
•
•
•

•

Wound dehiscence
Hernia
Ulceration
Cosmetic scarring
Hypertrophic scars
Keloid

Excessive contraction:
•
•

Limitation of joint movement (contractures)
Obstruction of tubes & channels (strictures)

Wound dehiscence

Fibrosis
• Formation of excess fibrous connective
tissue in an organ or tissue in a reparative
or reactive process
• Replacement of normal ‘parenchymal’ tissue

• Occurs after severe or persistent tissue
injury
• Repair cannot be accomplished by
parenchymal regeneration alone
• Leads to formation of a permanent fibrotic scar

Fibrosis
• Forms granulation tissue
• ‘pink, soft, granular’ gross appearance
• Composed of fibroblasts and thin-walled
capillaries, in loose extracellular matrix
• Gradually accumulates connective tissue
matrix (collagen) resulting in dense fibrosis

Fibrosis – Cystic Fibrosis
• Cystic fibrosis disease of exocrine gland
function involving multiple organ systems
• Mainly results in chronic respiratory infections
(e.g. staphylococcus aureus, haemophilus
influenzae) and pancreatic enzyme
insufficiency

• Causes clogging of the airways due to
mucus build-up, decreased mucociliary
clearance, and resulting inflammation (e.g.
neutrophil recruitment)

Currently, no effective medicine is available to cure CF. But doctors can prescribe medicines that help
slow the progression of the disease. Which of these types of medicine can do this?
A. Bronchodilators
B. Antibiotics
C. Decongestants
D. Mucolytics
E. All of the above

Learning outcomes
• You should now be able to:
• Understand causes and mechanisms behind
inflammation
• Identify types of inflammation
• Examine the main processes underlying wound
healing, including phases and factors delaying
wound healing
• Describe the causes and mechanisms behind
fibrosis

Quiz Time!
Go to socrative.com

Room name:

Thank you

The Pathology of Ageing
SCI1018-N PATHOLOGY
Dr. Ahmad Khundakar

Learning outcomes
• At the end of the lecture you should be able to:
• Discuss the theories of ageing
• Analyse the impact of cellular senescence on the
ageing process
• Understand the roles of the ageing process in the
changes to connective, muscle, epithelial and
neuronal/neural tissue
• Discuss age-associated conditions, such as agerelated macular degeneration, hearing loss and
GI tract disorders

Ageing: Key Terminology
•

Ageing (aging U.S.):
•

•

Senescence:
•

•

‘The scientific study of the biological, psychological, and sociological
phenomena associated with old age and ageing’

Geriatrics:
•

•

‘The decline of fitness components of an individual with increasing
age, owing to internal deterioration’

Gerontology:
•

•

‘The process of becoming older’, particularly applies to humans but
can also apply to other animals'

‘The branch of medicine that deals with the diagnosis and treatment
of diseases and problems specific to the aged’

Biogerontology:
•

‘The study of the biology of ageing and longevity’

Theories of Ageing - History
•

Ancient Greece (~5th Century BC)
•

•

Galen (129–199 AD)
•
•

•

Ageing was due to changes in body humours that
began in early life
These changes caused a slow increase in dryness
and coldness of the body

Roger Bacon (c. 1220–1292)
•
•
•

•

Old age consequence of gradual consumption of
‘innate heat and inevitable loss of body moisture’,
according to Hippocrates’ system of four-humours

One of the first to suggest a “wear and tear” theory
Ageing is the result of abuses and insults to the
body system
Good hygiene might slow the ageing process

Charles Darwin (1809–1892)
•

Attributed ageing to the loss of irritability in the
nervous and muscular tissue

Theories of Ageing
• Programmed theories
•

Ageing has a biological timetable or
internal biological clock

• Error (or ‘random/stochastic’)
theories
•

Ageing is a result of internal or external
assaults that damage cells or organs so
they can no longer function properly

Error
theories

Programmed
theories
•
•
•
•

Evolutionary
Programmed
Senescence
Endocrine
Immunology

Unified
theories

•
•
•
•
•
•

Wear and Tear
Rate-of-Living
Free Radical
Cross-linking
Error
Catastrophe
Somatic
Mutation
Theory

The Ageing Cell

López-Otín, 2013

Cellular Senescence
•
•

•
•
•

Phenomenon characterised by cessation of
cell division
“Hayflick’s Limit” (reproductive senescence)
• Fibroblasts removed from umbilical cord
& cultured
• Fibroblasts divide and repeated until ~
50 divisions
• Will not divide past this point
Can be initiated by wide variety of stress
inducing factors
Include both environmental and internal
damaging events, abnormal cellular growth,
oxidative stress, autophagy factors
Thought to involve telomere shortening

Telomeres
• Repetitive DNA sequences at the ends
of all human chromosomes containing
thousands of repeats of the sixnucleotide sequence, TTAGGG
•

Humans have 46 chromosomes, thus 92
telomeres (one at each end)

• Protect and separate chromosomes from
others in DNA sequence
•

Act like a ‘cap’ to prevent unravelling

Cellular Senescence – Telomeres
• When human cell divides, DNA splits
into two strands – one with a gap at
the end
• End gets shorter with each division
• Cell can no longer divide
• Could explain Hayflick’s limit!

Programmed Senescence – Telomerase
•

When human cell divides, DNA splits into
two strands – one with a gap at the end
•
•
•

•
•

•

End gets shorter with each division
Cell can no longer divide
Could explain Hayflick’s limit!

Telomerase fills the gap by attaching bases
to the end of the chromosomes
While cells have enough telomerase,
telomeres kept long enough to prevent
information from being lost through each
replication
However, telomerase levels decrease over
time
•

With decreasing telomerase levels, the
telomeres become shorter

Programmed Senescence – Telomerase
• Telomerase changes found in patients
with:
•
•
•
•
•

Heart disease
Atherosclerosis
Hepatitis
Cirrhosis
Cancer

• Thus, a target for treatments!

Programmed Senescence – Telomerase
Question:
You are a researcher who has discovered a treatment that enhances telomerase levels in
cells.
Why would this be viewed as a positive statement in particular diseases (e.g. Parkinson’s
disease) but not in cancer?

Telomeres and Cancer
•

90% of cancer cells have been found to
possess telomerase
•
•

•

Telomerase prevents the telomere from
shortening
Allows the cancer cells to reproduce, resulting
in tumour growth

Possible interventions in cancer
•
•
•

Measuring telomerase in the detection of
cancer
Stopping telomerase may fight cancer by
causing death of cancer cells
Telomerase in wound healing or immune
response

Ageing and Disease
• Physical changes related to ‘normal’
ageing are NOT disease-related
• We all experience ‘natural’ physical changes
in old age
• Changes have a deleterious effect on
the individual

• However, age is the main risk
factor for many diseases!

Physiological changes with Age
• 75 vs. 30 years
•
•
•
•

92% of brain weight
84% of basal metabolism
70% kidney filtration rate
43% of maximal breathing capacity (Evans
et al, 2001)

• However, interventions can improve
function
•
•

Active lifestyle results in less muscle mass
loss and greater flexibility with age
Steps taken to prevent illness and injury
can maximise independence

Ageing and Homeostasis
• Homeostatic response altered and
maintained at a level of decreased
function in ageing

Ageing and Homeostasis
• Homeostatic response altered and
maintained at a level of decreased
function in ageing
• Ageing of tissue in homeostatic
control centres (e.g. hypothalamuspituitary complex)
• Also in target glands and organs

Menopause
•
•
•

•

Natural biological process marking end of
menstrual cycle in females (last egg
produced)
Can happen in 40s (or earlier) but average
age 51
Perimenopause (period leading up to
menopause) - ovaries gradually produce less
oestrogen (and progesterone) until
insufficient to ovulate
Symptoms – hot flushes (sweating, feeling of
warmth), changes in membrane lining the
vagina, emotional changes (mood, anxiety)

Menopause – treatment
• Hormone therapy (HRT) – most
widely used and effective treatment
• HRT a combination of oestrogen and
progestin (synthetic progesterone), or
oestrogen alone (after hysterectomy)

Santen et al, 2010

Question: study the graph, which is taken
from a meta-analysis of data on the efficacy
and side effects of hormone replacement
therapy (HRT).
Using the graph, determine the main
benefits and risks of different the
combinations of HRT.
Santen et al, 2010

Levels of Cellular Organisation

Levels of Cellular Organisation

AGEING
AND
DISEASE
PROCESS

Types of Tissue
• Four main types of tissue
•
•
•
•

Connective tissue
Epithelial tissue
Neural/neuronal tissue
Muscle tissue

• All undergo changes in ageing process

Types of Tissue
• Four main types of tissue
•
•
•
•

Connective tissue
Epithelial tissue
Neural/neuronal tissue
Muscle tissue

• All undergo changes in ageing process

Connective Tissue
•
•

Tissue that connects, supports, binds, or
separates other tissues or organ
Characteristics of connective tissues
(CT):
•
•
•
•

Fibres – vary in tissue type (not present in
blood or adipose tissue
Ground substance – clear, colourless,
viscous fluid containing glycosaminoglycans
and proteoglycans
Ground substance and fibres create the CT
matrix
Cells – usually infrequently spread through
matrix

Connective Tissue Changes in Ageing
• Fibres
• Collagen – decreased solubility,
reducible cross linkages stabilise,
increased rigidity
• Elastin – decreased production,
increased fragmentation, rupture,
loss of ‘rebound’

Connective Tissue Changes in Ageing
• In ageing – non-oxidative
reactions between glucose and
collagen
• lead to the formation of so-called
advanced glycation end-products
(AGEs)
• Leads to Schiff base ‘cross link’
formation between a carbohydrate
and a protein amino group
• AGEs most abundant in collagen
tissues
• Causes ‘stiffening’ of tissue

Types of Tissue
• Four main types of tissue
•
•
•
•

Connective tissue
Epithelial tissue
Muscle tissue
Neural/neuronal tissue

• All undergo changes in ageing process

Epithelial Tissue
• Plays fundamental role in
establishing tissue barriers
• Separates internal from external
environment
• Maintains nutrient, fluid, electrolyte
and metabolic waste balance in
multiple organs

Epithelial Tissue
• Epithelial cells tightly held together
by junctions, adhering junctions
and desmosomes
• Epithelium attached to basal
lamina comprised of mixture of
glycoproteins and collagen
• Reticular lamina attached to basal
lamina, underlying connective
tissue forms basement membrane

Epithelial Tissue Changes in Ageing
• Cell adhesion complexes critical
regulators of permeability
• Cells lose adhesion in ageing or
disease conditions
• Impacts on organ function
• Skin - more susceptible to maceration,
which may lead to development of
lesions

Epithelial Tissue Changes in Ageing
• Cell adhesion complexes critical
regulators of permeability
• Cells lose adhesion in ageing or
disease conditions
• Impacts on organ function
• Lung (alveoli) - single cell structure is
highly susceptible to damage

Epithelial Tissue Changes in Ageing
• Cell adhesion complexes critical
regulators of permeability
• Cells lose adhesion in ageing or
disease conditions
• Impacts on organ function
• Gastrointestinal - decreased intestinal
barrier function associated with
systemic inflammation, absorption of
certain nutrients (e.g. lipids) affected

Types of Tissue
• Four main types of tissue
•
•
•
•

Connective tissue
Epithelial tissue
Neural/neuronal tissue
Muscle tissue

• All undergo changes in ageing process

The Brain
• Made up of three parts:
• Forebrain
•

Cerebrum, thalamus, and hypothalamus

• Midbrain
•

Midbrain structures (e.g. substantia
nigra, superior colliculus)

• Hindbrain
•
•

Cerebellum
Brain stem structures (e.g. medulla
oblongata, neurotransmitter nuclei)

Cerebrum (cerebral cortex)
•

The largest part of the human brain is the
cerebral cortex (bark in Latin)
•

•
•
•

All information processing on six surface layers of
cortex

The cortex sheet folded into fissures inside
the (sulci) and ridges (gyri)
The brain is split into the left and right
hemispheres by the corpus callosum
White matter underneath the cortex contains
axons connecting brain areas

Cerebrum (cerebral cortex)
•

The largest part of the human brain is the
cerebral cortex (bark in Latin)
•

•
•
•

All information processing on six surface layers of
cortex

The cortex sheet folded into fissures inside
the (sulci) and ridges (gyri)
The brain is split into the left and right
hemispheres by the corpus callosum
White matter underneath the cortex contains
axons connecting brain areas

Cerebral Cortex Lobes
• Four lobes
• Frontal (inc. motor cortex)
• Parietal (inc. primary somatosensory
region)
• Occipital
• Temporal
• (+ allocortex)

The Neuron(e)

Cell body (soma)

• Basic signalling unit of the nervous
system
• Polarised cell
• Can receive, process and transmit electrical
information through the action potential

• Communicate electrochemically

Axon

• Specialised connections - synapses
• Allow chemical communication between
neurones
Dendrites

Synapse

Cellular Structure
•

•

Neuron(e) basic function unit
• Sensory neurones - receptor cells
receiving external stimulus (afferent
neurones) e.g. light receptors in retina
• Motor neurones – effector cells respond
to sensory information (efferent
neurones)
Glial cells
• Astrocytes
• Oligodendrocytes
• Microglia

The Ageing Brain
• Ageing affects molecules, cells,
vasculature, gross morphology in brain
• Changes to vasculature and increases in
blood pressure
• Raises possibility of stroke and ischaemia
• Development of white matter lesions
(hyperintensities)

Human brain vasculature

MRI image of 80 year old patient
with minor white matter hyperintensities
Debette and Markus (2010)

The Ageing Brain
•

Atrophic changes, particularly in frontal cortex

•

Volume of the brain declines around 5% per
decade after age 40 (Svennerholm et al, 1997)
•

•

Increases over 70 years of age

Thought to be a result of cell death
•

Compensatory changes in dentritic arbour,
spines, and synapses

•

Help re-establish synaptic connections lost from
cell death

The Ageing Brain – Neurodegenerative Disease
• Age-related diseases of the brain (e.g.
Alzheimer’s disease, Parkinson’s disease)
are NOT a consequence of ageing
• Age main risk factor
• Ageing process may leave neuronal/tissue
liable to disease
• Proteins associated with neurodegenerative
diseases (e.g. β-amyloid) naturally
accumulate with ageing
•

Not to levels sufficient to cause significant
pathology effect

Types of Tissue
• Four main types of tissue
•
•
•
•

Connective tissue
Epithelial tissue
Neural/neuronal tissue
Muscle tissue

• All undergo changes in ageing process

Skeletal Muscle
Striated (‘striped’) muscle
Responsible for voluntary movement
650 muscles in humans
Stretching and contracting in of cells in
orderly manner
• Adapt to use (or non-use!)
•
•
•
•

• Muscular atrophy in injury and ageing

Skeletal Muscle Changes in Ageing
• Sarcopoenia - involuntary loss of
muscle mass, strength and function
• Muscle mass decreases
approximately 3–8% per decade after
the age of 30 (Volpi et al, 2004)
•

Rate of decline higher after the age of
60

• Loss of muscle mass, strength, and
function major contributor to disability
in older people
• Sarcopoenia increases fall risk,
vulnerability to injury (Wolfson et al,
1995)
•

May lead to functional dependence and
disability

Sarcopoenia – Treatment
• Primarily exercise-based
• Specifically resistance training or
strength training

• Drug therapies not preferred option:
• Urocortin II stimulates pituitary gland
adrenocorticotropic hormone (ACTH)
release
• HRT can increase lean body mass,
reduce abdominal fat and prevent
bone loss in the short-term
•

Long term effects – breast cancer?

Ageing and Disease in Organ Systems

Skin Changes in Ageing

Skin Changes in Ageing
• Skin generally divided into three main
parts:
•
•

•

Epidermis – outer part contains skin
cells, pigment, and proteins
Dermis – middle part contains blood
vessels, nerves, hair follicles, and oil
glands; provides nutrients to the
epidermis
Subcutaneous layer – inner layer under
the dermis, contains sweat glands,
some hair follicles, blood vessels, and
fat

Skin Changes in Ageing
•
•
•
•
•

Wrinkling, as a result of loss of elasticity
and decline in cell replacement
Loss of dermal thickness (20%),
especially in sun-damaged skin
Chance of skin neoplasms (benign and
malignant) increase
Vitamin D production declines
Decline in Meissner’s (touch), Pacinian
(pressure), Krause’s (temperature),
corpuscles

Eye Changes in Ageing

Eye Changes in Ageing
• Lens grows during life span,
increasing in density and weight
• Ptosis – wrinkling and loss of orbital
fat
• Presbyopia (‘long sightedness’) –
progressive decrease in lens
elasticity
• Glaucoma increased intraocular
pressure in aqueous humour

Eye Changes in Ageing – Age-related macular
degeneration
• Age-related macular degeneration
(AMD)
•
•

Blurred or no vision in the centre of the
visual field
Characterised by progressive
accumulation of characteristic yellow
deposits, drusen
•

•

build-up of extracellular proteins and
lipids, in the macula (a part of the
retina)

Reading and recognising faces difficult

Ear Changes in Ageing

Ear Changes in Ageing
•

Hearing loss accompanies aging
•
•
•

•

Presbycusis – ageing of middle ear
•

•
•
•
•

10% of population (US) has hearing loss
65–75 years – 33% of population have
hearing loss
>75 – 50% of population have hearing loss
Ear drum loses elasticity

Decreased 8th (vestibulocochlear) nerve
sensitivity due to noise exposure
Decline in hair cells of the cochlea
Joints of the bones of the ear become stiff
Mechanical blockage – earwax, effusion

Gastrointestinal (GI) Changes in Ageing
• GI symptoms are common in older
people
• Prevalence, mortality and
morbidity of GI diseases increase
with advancing age
• Ageing affects absorption and
metabolism of foods, vitamins and
medications

Gastro-Oesophageal Reflux Disease (GORD/GERD)
•
•
•
•

GORD becomes more prevalent with
increasing age (Howard et al, 1992)
Prevalence in primary care may be >20%
although many older people do not report
heartburn (Mold et al, 1991)
Many do not present to clinicians but self
medicate in the community (Corder et al,
1996)
Most effective treatment is currently
regarded as proton-pump inhibitor (PPI;
NICE)
•
•
•

Proton pump terminal stage in gastric acid
secretion
Responsible for secreting H+ ions into the
gastric lumen
Thus, target for inhibiting acid secretion

Gastro-Oesophageal Reflux Disease (GORD/GERD)
•
•
•
•

GORD becomes more prevalent with
increasing age (Howard et al, 1992)
Prevalence in primary care may be >20%
although many older people do not report
heartburn (Mold et al, 1991)
Many do not present to clinicians but self
medicate in the community (Corder et al,
1996)
Most effective treatment is currently
regarded as proton-pump inhibitor (PPI;
NICE)
•
•
•

Proton pump terminal stage in gastric acid
secretion
Responsible for secreting H+ ions into the
gastric lumen
Thus, target for inhibiting acid secretion

Peptic Ulcer Disease (PUD)
•
•

Peptic ulcer disease – duodenal or
stomach ulceration
Affects 4 million people around the world
•

•

Major cause of dyspepsia
•
•

•

2%-14% of the ulcers will perforate
Episodic or persistent pain or discomfort
localised to the upper abdomen
Symptoms including gas, bloating, nausea,
vomiting, and early satiety

Age-related, though peak incidence is in
the 40s for men and in the 50s/60s for
women

Peptic Ulcer Disease (PUD)
• Peptic ulcer disease – duodenal or
stomach ulceration
• Initially thought to be caused by
stress, spicy foods, and too much
acid
• Barry Marshall discovered the
bacterium Helicobacter pylori (H.
pylori) plays a major role in causing
many peptic ulcers
• Now treated with antibiotics, often in
combination with PPIs

Learning outcomes
• You should now be able to:
• Discuss the theories of ageing
• Analyse the impact of cellular senescence on the
ageing process
• Understand the roles of the ageing process in the
changes to connective, muscle, epithelial and
neuronal/neural tissue
• Discuss age-associated conditions, such as agerelated macular degeneration, hearing loss and
GI tract disorders

Quiz Time!
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