Disease Processes Notes PDF

Summary

This document provides learning objectives and detailed information on disease processes, including cell death (apoptosis and necrosis), atrophy, infarction, and the differences between labile, stable, and permanent cells. It also outlines neoplasia, tumorigenesis, and the risk factors associated with mutation and tumor development.

Full Transcript

Disease Processes- Learning objectives

Week 0 Cell death and adaptation

e List the main differences between apoptosis & necrosis. 33yAt42JnkxG5z

Apoptosis Necrosis
- Active form of cell death - Passive form ofcell death
- Part of normal physiology and pathology Only occurs in pathology
- Acell can die by apoptosis and notkill One cell dying can kill neighbouring cells
neighbouring cells causing an infarct
- Does NOTstimulate an inflammatory Stimulates acute inflammation response
response

@ What determines whether a stimulus causes atrophy or infarction?

An infarction is an area of necrosis which is considered to be pathological, whereas atrophy (decrease
in cell size/number) occursat tissue level and can be either be a part of physiology or pathology. In a
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young person atrophy could arise due from autophagy or apoptosis but in an older person it’s mainly
caused by apoptosis. The speed at which a stressor is applied sudden or slow, as well as how severe
the stressor is. If the stressor occurs at a slow rate, it might give the cells some time to recover and
result in atrophy. If the stressor is sudden, the cells die by necrosis which stimulate an acute
inflammatory responseand lead to an infarction

@ What effect does ageing have on cells & organs?

Atrophy in an older person is considered to be apoptosis, since old cells have lost the ability to
regenerate and undergo autophagy. Atrophy in a young person can be either autophagyor apoptosis

@ What is meant bylabile, stable & permanent cells, give some examples. 33yAt42JnkxG5z

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Labile — cells are continuously dividing
- Epithelial cells e.g. skin, GIT, reproductive, urinary tracts, lining of endocrine ducts
- Haemopoietic stem cells

Stable — can divide when stimulated
- Epithelial cells e.g. liver, kidney, pancreas, lung
- Smooth muscle cells, fibroblasts, endothelial

Permanent — cells do not divide
- Cardiac and skeletal myocytes
- CNS neurons

e@ Define ischaemia, hypoxia/hypoxemia, necrosis, infarction, autophagy, apoptosis, atrophy,
hypertrophy, hyperplasia & metaplasia.

Ischaemia — reduced/lack of blood supply
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Hypoxia/hypoxemia — lack of oxygen/lack of oxygen in the blood
Necrosis — catastrophic cell death
Infarction — area of necrotic tissue
Autophagy— cells shrink but still alive
Apoptosis — programmedcell death
Atrophy — decreasein tissue/cell size/number leads to shrinking through autophagy or apoptosis
Hypertrophy — increasein cell size
Hyperplasia — increase in cell number
Metaplasia — The change from one normal, well-differentiated cell type to a different normal well-
differentiated cell type typically in response to a change in the cellular environment or the application
of stress. It’s reversible if the environment changes back or the stressor is removed

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 @ Give some examples of cell types that are considered epithelial, connective & ‘other’

Epithelial - Forms the covering and lining of body cavities, organs, vessels (surface) and makes up the
secreting portions of glands (glandular)

Connective - most abundant and widely distributed tissues in body. Supports and strengthens other
tissues, protects and insulates organs, main source of immune functions. Includes macrophages,
fibroblasts, adipocytes, leukocytes. Loose, dense, cartilage, bone, and blood
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Muscular - produces movement. Skeletal - attaches tendon to bone,voluntary control. Cardiac -
pumps blood, involuntary control. Smooth - Found in hollow organs and vessels, involuntary control

Nervous - Neurons and neuroglia (protects and supports neurons)

Others — peritoneum, pleura, mesothelial lining of organs
- germ cells, haemopoietic cell
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- neutrophils, lymphocytes, macrophages

Week 1 Neoplasia
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@ Define neoplasia, tumour, malignancy, dysplasia, -in-situ & metastasis/metastasize.

Neoplasia - new abnormal growth; also called a tumour could be benign or malignant

Malignancy - malignant tumour = cancer. Can invade and destroy adjacent structures and spread to
distant sites (metastasize) to cause death

Dysplasia - not a cell adaptation but a pre-cancer exchange. A disordered abnormal growth, a loss in
uniformity of individual cells (mutation). Encountered mainly in metaplastic epithelia. Dysplasia may
be a precursor to a malignant transformation, but it does not always progress to cancer
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Carcinoma in-situ - pre-invasive neoplasm in the epithelium. Dysplasia within the epithelium but does
not penetrate the basement membrane (better prognosis if caught at this point). Once the tumour
cells breach the basement membrane, the tumour becomes invasive

Metastasis/metastasize - the next step of invasion, the spread of a tumour cells to distant sites and
set up for secondary growth
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e@ Nomenclature of tumours (construct/deconstruct the name based upon the cell of origin & the
nature of the growth).

Cancers only form in dividing cells and if cells are forced to divide more frequently, they are most
likely to make.a mistake or their daughter cells mutate which can become dysplastic. In addition,
there is increased level of oxidants and other chemical mediators capable of damaging DNA at sites of
chronic inflammation

-oma = benign
-carc- = malignant, epithelial origin - increase in incidence with age
-sarc- = malignant, connective tissue origin 33yAt42JnkxG5z

Adenoma - benign glandular epithelial tumours
Cyst - growing a fluid-filled sack, secretary epithelium e.g. in the ovaries
Leio - smooth
Myo - muscle
Chondro- cartilatge

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 Hemangio - blood vessel/endothelial cell - connective tissue
Meningioma - meningeal cell/meninges (benign)
Blastoma - a type of cancer caused by malignancies in precursor cells during fetal development, which
are commonly referred to as blasts

e List the basic risk factors for the development of mutation & tumourgenesis.

The ability for cells to divide like labile or stable cells. Epithelial cells are most vulnerable as they are
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labile (constantly dividing) or stable (able to divide) and are on the interface between the body and
potential stressors. While metaplasia and hyperplasia are normal cellular adaptations, they can
increase the risk of dysplasia which can then mutate into benign or malignant tumours.
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Carcinomas are morelikely to occur at sites of chronic inflammation. When chronic inflammation
occursat sites whereepithelial cells are present, the epithelial cells will also respond to growth
factors and repeatedly divide in a futile attempt to repair. This increased proliferation (cell division) of
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epithelial cells puts them at risk of making mistakes when copying their DNA and passing on
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mutations.

@ Understand the 8 behavioural changesthat occur in cancer cells as a result of multiple mutations

Essential alterations for malignant transformation:
- Proliferation without external stimuli
- Insensitivity to growth-inhibitory signals
- Evasion of apoptosis;
- Defects in DNA repair (malignant tumours have more unstable DNA)
- Limitless replicative potential
- Sustained angiogenesis
- Ability to invade and metastasize (cancer cells produce enzyme that can breakdown connective
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tissue and invade through the layers of an organ)
- Predilection for aerobic glycolysis produces less ATP but more lactate which can contribute to
making building blocks for more cancer cells (Warburg Effect)

e List the main differences between benign & malignant tumours.

Benign Malignant
- localised and do not metastasize - Can metastasize (usually die from secondary
- encapsulate cancer rather than primary)
- homogenous - infiltrative growth pattern
- well-differentiated - heterogenous, sub-populations with differing
- generally slower growth, but many exceptions degrees of differentiation, proliferation and
(e.g. in the brain whereit can be lethal) aggression
- Some populations within the malignancy will
grow quickly sometimes outstripping the growth
of their blood supply and thus undergoing
necrosis in areas.
Both benign & malignant tumours can undergo necrosis if they outgrow their bloody supply or there
is bleeding within the tumour, it is more common in malignancies that are fast growing. Some
apoptotic pathways have been switchedoff in tumour cells. 33yAt42JnkxG5z

Both benign and malignant tumours are composed of mutated cells, however in benign tumours, the
cells have not got the mutations that allow cells to invade & metastasize

e List the 3 main routes of metastasis & common sites affected.

Blood - arterial spread travels throughout the system and can give rise to tumour emboli. Venous
invasion follows the venous flow of blood and usually end up in the lungs

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 Lymph - transport through lymphatics is the most common pathway for the initial dissemination of
carcinomas. Sarcomas may also usethis route

Direct seeding - seeding of body cavities and surfaces may occur whenever malignant tumours
penetrate through membrane. Most often involved is the peritoneal cavity but also, pleural, pericarial,
subarachnoid cavities, and joint spaces

Most common sites: lungs and liver (only other organ with venous blood supply, comes from GIT)
from the flow of venous blood, bone and brain 33yAt42JnkxG5z

The lungs are the most commonly affected organ as all venous blood returns to them & cancers
usually spread first in the lymphatic & venous systems.

The liver is our largest visceral organ & thus gets a large amount ofarterial blood but it is also the
metabolic organ of drugs, hormones & the macronutrients from food absorbed by the GIT, which are
carried to the liver via the portal venous system for processing. Many cancersfirst enter the blood at
capillary beds or through thin-walled venules and get carried in venous blood to the liver and lungs.
Once we have more haematogenous mets (clumps or emboli of cancer cells travelling in the blood)
they go to areas that get a lot of arterial blood like the brain & bones.

@ What must take place before cancer develops?

Mutations during hyperplasia and metaplasia may lead to dysplasia. Dysplasia can progress into
carcinoma-in-situ, which is the epithelial malignancy that has yet to penetrate through the basement
membrane that sits beneath the epithelial layer. Once the cancer cells start to secrete enzymes that
breakthrough the connective tissue, it allows the cancer to invade and metastasize.

@ Understand the importance of early detection/the significance of metastatic disease

The state of metastasis is key to prognosis. If tumour is identified early before metastasis, the
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localised tumour may be removed and person may be cured. However,if the malignant tumour has
infiltrated and metastasised to other areas of the body, it becomes moredifficult to remove

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Week 2 Inflammation and Repair

e@ Define hyperaemia, oedema (exudate vs transudate), effusion, resolution, organisation, ulcer &
abscess.

Hyperaemia - increase in blood flow

Oedema - excessfluid in the interstitial fluid
- Exudate: formed in acute inflammation - increased hydrostatic pressure and inflammatory
mediators make vascular walls more permeable = high protein oedema: fluid which has plasma
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proteins (act as signalling molecules in repair process once leaked out), cellular debris/necrotic cells,
white blood cells and sometimes microorganisms.

- Transudate: formed when fluid leaks out due to increased hydrostatic pressure (venous outflow
production e.g congestive heart failure) or decreased colloidal osmotic pressure (decreased protein
synthesis e.g. liver failing/increased protein loss e.g kidneysfailing)

Effusion - build up of excess fluid between the membrane layers of body cavities
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Ulcer - occurs in necrotic tissue and resultant inflammation exists on or near a surface

Abscess- are localised collections of purulent inflammatory tissue

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 @ What form of cell death causes an inflammatory response?

Necrosis causes an acute inflammatory response. Necrosis can occur from a complete blockage
(occlusion) of a blood vessel; ruptured blood vessel & haemorrhaging; burns (chemical, electrical,
thermal); some infections, severe trauma like a crush injury; direct cell injury through surgery or
foreign object including a blade, bullet etc.

@ What are the 3 features of acute inflammation?

Hyperaemia - increased blood flow to the site of inflammation due to vasodilation (induced by
chemical mediators on the smooth muscle)

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Oedema -chemical mediators act on vessel wall and increase the interendothelial space causing high
protein plasma and fluid to leak out leading to exudates

Recruitment of neutrophils (blood leukocytes) - accumulate along the vascular endothelium and then
migrate throught the vascular wall into the interstitial tissue

After a transient reflexive period of vasoconstriction, vasodilation leads to hyperaemia. The increased
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permeability of the vessels allows serum & proteins to enter the affected tissue forming oedema
which because ofits high protein content can be referred to as exudate. Neutrophils are activated
and are attracted to the acutely inflamed tissue, migrating through the vessel walls. Neutrophils are
phagocytic and the primary cell to associate with acute inflammation, however they have a short
lifespan and will be aided my macrophagesthat will finish the job of neutrophils as well as remove
apoptotic neutrophils. Acute inflammation can result in resolution, organization or chronic
inflammation.

@ What are the 3 possible outcomes of acute inflammation?

Healing by resolution - healing without scarring. Permanent tissueslike the brain and heart will never
heal by resolution as neurons, skeletal and cardiac myocytes do notdivide. In labile/stable tissues
resolution is not possible when a lot of tissue has been lost or when thereis overlying infection, poor
immunity, poor nutrition or interruption of healing.

Healing by organisation - with scarring = loss of functional tissue, if fibrosis develops in a tissue space
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occupied by an inflammatory exudate.

Both typesof healing involve proliferation of various cells, and close interactions between cells and
the ECM

Chronic inflammation - if the stressor is persistent and not removed

@ What are the 3 main components of granulation tissue & their role/purpose in repair?

Granulation tissue is the immaturescar, the tissue that forms the scar and so will occur in acute
inflammation that heals through organization and it will always be present in chronic inflammation as
part of the repeated attempts at repair.

Granulation tissue is composed of:

1. Fibroblasts secreting collagen protein.
Macrophages coordinating events & cleaning up debris
Ss

3. Angiogenesis, the formation of new blood vessels to provide nutrients and blood gases
during the repair process.

The formation of granulation tissue involves macrophages moving into the necrotic tissue and
continue to removeit along with the increasingly apoptotic population of neutrophils. Fibroblasts
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 would migrate into the area and secrete collagen fibres tofill in the space once occupied by dead
myocytes and newcapillaries (angiogenesis) would sprout into the area to provide growth factors,
oxygen and nutrients for the granulation tissue.

Oncethe dead tissue is removed and the space filled with collagen, the fibroblasts and macrophages
migrate away leaving the largely acellular protein (collagen) scar. Because of the avascular nature of
the scar, the new vessels regress through apoptosis and the collagen fibers contract as it matures.

@ What are the consequences of healing through organisation?

While healing through organisation and scarring does allow repair and fills in tissue deficit so the body
can survive, it lacks the functions of the tissue it replaces. Over time, scar tissue contracts and pulls
surrounding tissue with it causing a distortion. If organisation were to happen in myocytes (that are
permanent cells), the scar represents a weak point that can form an aneurysm and predisposes
thrombus formation. Scar tissue lacks the strength of the normal cardiac muscle & will not relay
electrical impulses in the same way as the normal heart muscle.
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@ What are the 3 main causes of chronic inflammation?

- Unresolved acute - for example when the stimulus causing the acute response remains.
- Repeated acute
- “Special” cases such as infections and auto-immune reactions, where thereis little/no acute
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response preceding the chronic inflammation

e@ Define the 3 general features of chronic inflammation?

1. Ongoing tissue injury and destruction
2. Infiltration of lymphocytes
3. Repeated attempts at repair through the formation of granulation tissue and, when occurring in
stable/labile tissues, proliferation of parenchymal cells.

Chronic inflammation occurs when a stimulus causing cellular injury remains or is repeatedly applied
or when our immune system attacks something that it shouldn’t. In chronic inflammation we get
ongoing cellular injury, either caused by the stimulus or our body’s immune cells (lymphocytes) and
repeated attempts at repair. The attempts at repair include the formation of granulation tissue
(immature scar tissue composed of macrophages,collagen secreting fibroblasts and angiogenesis
which is the growth of newcapillaries that supply the area with oxygen, glucose and growth factors).

e@ Describe the possible negative consequencesof chronic inflammation

When chronic inflammation occursin stable or labile tissues that contain epithelial cells, surrounding
epithelial cells will proliferate (undergo hyperplasia) in a futile attempt to repair. This increase in
proliferation & the presence offree radicals increases the chance of mutation. However,it is not the
granulation tissue that causes cancer & repair does not necessarily involve cell division.
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In addition, there is increased level of oxidants and other chemical mediators capable of damaging
DNA at sites of chronic inflammation
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@ What is meant by sterile & non-sterile sites in the human body?
Sterile — free from bacteria and micro-organisms
Non-sterile — may contain bacteria and micro-organisms

@ Understand the main differences between the innate & adaptive system

Innate system - non-specific (e.g. acute inflammation), non-specific reinforcement. E.g neutrophils,
macrophages,cytokines
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 Adaptive system - specific responses (slower), memory. E.g. lymphocytes

@ ~=Have a basic understanding of what autoimmune & hypersensitivity responses are.

Autoimmune disorders - immune system attacking something that is normally functioning

Hypersensitivity disorders - immune system over reacts to stimulus

@ Have a basic understanding of what is meant by the term immune-compromised & the patients
at risk

Immune-compromised patients are those whose acquired/innate immune systems are not working
effectively; they have genetic predispositions to certain diseases; are receiving drugs/treatments; or 33yAt42JnkxG5z

have comorbid conditions

Week 3 Haemodynamics

@ Define congestion, oedema, effusion, transudate, ischaemia, haemorrhage, thrombus, embolus,
aneurysm, atheroma, atherosclerosis, hypertension, stasis & hypercoagulability.

Congestion - Passive build-up/increase of blood within a vessel. (It generally occurs in low pressure
33yAt42JnkxG5z circuits like the hepatic portal system, pulmonary circuit & systemic venous circuit and leads to
increased hydrostatic pressure & a tendency towards transudate formation).
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Transudate: forms when fluid leaks out of the vessel due to increased hydrostatic pressure (venous
outflow obstruction or systemic increases in venous pressure e.g congestive heart failure) or
decreased colloidal osmotic pressure (decreased protein synthesis e.g. liver failing/increased protein
loss e.g kidneysfailing)

Ischaemia — lack of blood supply

Haemorrhage — damageto a vessel, all constituents leaking out

Thrombus — attached blood clot. In the arteries it starts as an endothelial injury from turbulent blood
(abnormal blood flow from systemic hypertension) and hypercoaguability may promote thrombosis.
In the venous circuit, it is usually caused bystasis

Embolus — anything undissolved travelling in the blood from its point of origin to a distant site, where
it often causes tissue dysfunction or infarction
- Pulmonary emboli: derive primarily from lower extremity deep vein thrombi. May lead to 33yAt42JnkxG5z

right-sided heart failure, pulmonary haemorrhage, pulmonary infarction or sudden death
- Systemic emboli: derive primarily from heart valves, aortic aneurysms, atherosclerotic
plaques. 33yAt42JnkxG5z

Aneurysm — localized abnormal dilation of artery or ventricle of the heart. They form in areas of high
pressure where there are weakened areas. In arteries, they can form in areas of artherosclerosis and
in the heart ventricles in areas of scarring - altered tissue is weaker and bulges out in response to the
high pressure

Atheroma — a sclerotic plaque representing an area of chronic inflammation within the intima wall of
an artery
= infiltration of lymphocytes, ongoing tissue injury and destruction, and repeated attempts at repair
through granulation tissue and proliferation of surrounding cells e.g. in the smooth muscle cells of the
tunica media. Oxidised lipids (which are eaten by macrophages and smooth muscle cells turning them
into foam cells) including cholesterol and calcium (calcium often gets deposited at sites of necrosis
and chronic inflammation = calcifies artery wall) will also be found at the injury site

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 Atherosclerosis — the process of atheroma. An arterial disease, chronic inflammation within the intima
lining of the artery. Reduced vascular elasticity = increased vascular resistance = swelling/bleeding in
plaque

Artherosclerosis encourages turbulent blood flow which causes platelets and cells to form thrombi in
the arterial circuit due to endothelial injuries. When the endothelium is lost there is decreased nitric
oxide and prostacyclin synthesised in the region and more pro-coagulative factors released which
encourages morefibrin, platelets and RBCs to adhere to the growing clot/thrombus. Aneurysms
frequently form in areas of atherosclerosis and so the same reasoning applies. In addition, the
aneurysm being a blind-ended sack can entrap cells and proteins.

Hypertension — high blood pressure. Systemic hypertension is a result of increased cardiac output (e.g.
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hypervolemia) and increased systemic vascular resistance (e.g. atherosclerosis, renal disease)
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Stasis — blood not flowing/flowing slowly. Generally seen in low pressurecircuits like venous circuit

Hypercoaguability — increased tendency of blood to coagulate/clot abnormally and produce thrombi

e Identify blood flow & pressure differences in the systemic, pulmonary & (systemic) venous
circuits

Systemic circuit: the movement of oxygenated blood from the heart through the body to provide
oxygen and nutrients to the tissues while bringing deoxygenated blood back to the heart. Blood
travels through arteries at high pressure to reach organs around the body. Arteries have a smaller
lumen but thicker muscle walls to pump blood.
Systemic veins and venules contain more blood than systemic arteries and arterioles.

Pulmonarycircuit: is the movement of blood from the heart to the lungs for oxygenation, then back
to the heart again. Oxygen-depleted blood from the body leaves the systemic circulation when it
enters the right atrium through the superior and inferior venae cavae. Veins have a bigger lumen but
thinner muscle wall blood flows through them at low pressure. Hypertension in the pulmonarycircuit
= increased pulmonary blood flow = leads to congestion and an increase in hydrostatic pressure =
oedema

Portal hypertension in venous circuit = congestion in the portal system, which leads to increased
hydrostatic pressure = oedema and ascites

Anything that increases blood flow in the systemic circuit (hypertension) can lead to an increasein
hydrostatic pressure e.g. overactivation of RAAS, increased vasoconstriction = blood volume increases,
venous obstruction = blood passively builds up

@ How do the normal functions of the kidneys impact upon blood pressure and composition?

Kidneys directly regulate blood pressure - when blood volume/pressurerises, the kidneys respond by
allowing more water to flush from the body in urine. When blood volume/pressureis low, the kidneys
conserve water (and sodium chloride) and returned to the bloodstream.

The kidneys produce erythropoietin which acts on the red bone marrowto stimulate the synthesis of
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RBCs. Blood is mainly water and the levels of water are regulated by the kidney through the renin —
angiotensin — aldosterone system (RAAS). Aldosterone acts at the distal convoluted tubules to retain
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sodium and reabsorb water from the filtrate, so instead of being lost in urine it is retained in the
blood thus increasing blood volume. The kidneys also regulate the levels of various ions and blood pH
by reabsorption from the filtrate and secretion intoit.

In addition to controlling blood volume, the kidneysare able to control vascular resistance through
the release of renin and the activation of angiotensin 2, which as the name suggests causes vascular

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 constriction thus increasing blood pressure. Thereis cross stimulation between the sympathetic
nervous system and RAASso that stimulation of RAASwill also result in an increase in SNS stimulation.

@ Compare superficial with deep vein thrombi (DVT)

Superficial venous thrombi do not usually embolise. Deep vein thrombi (DVT) frequently embolise.

Superficial thrombi frequently give symptoms including DVTs may be asymptomatic or give mild symptoms
pain and swelling/oedema, ulceration of overlying skin33yAt42JnkxG5z

like swelling distal to the clot.
DVTsare often very large and not strongly
attached to the wall of the vein and so they can
embolise as a very large mass causing catastrophic
outcomes. 33yAt42JnkxG5z

e@ List the risk factors for DVT & track their path if they embolise

Risk factors for DVT: hypertension, atherosclerosis

DVT that forms an embolus: Femoral or Iliac vein > Inferior vena cava > Right atria > right ventricle
> Pulmonary arteries > LUNGS = pulmonary emboli

Fragmented thrombi from DVTsare carried through progressively larger veins and the right side of
the heart before slamming into the pulmonaryarterial vasculature.

e@ List the main risk factors for the development of atherosclerosis?

Being male, increasing age, being of Aboriginal or Torres Strait Islander descent.
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Smoking, diabetes, systemic hypertension, hyperlipidaemia (increased LDL & reduced HDL), visceral
adiposity, etc

@ How do the kidneys contribute to systemic hypertension?
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In responseto a real or perceived fall in blood pressure/cardiac output the kidneys activate the renin-
angiotensin Il-aldosterone system (RAAS), which results in:

Aldosterone induces the kidneys to increase sodium and water retention > increasing blood volume
Angiotensin II leads to vasoconstriction > increased vascular resistance > increased blood pressure

@ What vascular pathologies does atherosclerosis predispose towards?

Atherosclerosis is a major cause of arterial thrombi becauseit is associated with loss of endothelial
integrity and abnormal blood flow (turbulence) which leads to emboli and aneurysms

@ What are 4 waysin which atherosclerosis can cause death?

- Bleeding and swelling within the atherosclerotic lesion can block/occlude the vessel leading to
ischemia of downstream tissue, which leads to an infarct

- Thrombus formation can lead to occlusion of the vessel and infarction.

- Emboli may break off a thrombus and travel until stopped when it occludes a smaller vessel, which
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leads to an infarction 33yAt42JnkxG5z

- Atherosclerosis is a risk factor for aneurysm formation which can burstor give rise to thrombi and
emboli, which can lead to hypovolemic shock (if major artery in the body) or haemorrhagic stroke(if
in the brain) and death

pH

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 In addition, atherosclerosis can lead to slow chronic reductions in blood supply causing tissue atrophy,
which while notlife-threatening reduce the functional reserve of organs and in the brain predispose
us towards further pathologies.

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@ What are the possible consequences of having atherosclerosis in the abdominal aorta, coronary
arteries, carotid & cerebral arteries?

In abdominal aorta - embolous will travel down towards lower limbs and cause gangrene
In aorta - if atherosclerosis causes aneurysm = bleed to death; aneurysm could cause hypovolemic
shock
In coronary arteries - myocardial infarction, ischaemic heart disease
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In carotid & cerebral arteries - thrombus embolus = ischaemic stroke, aneurysm = haemorrhagic
stroke, cerebral atrophy, cerebral vascular disease

Week 4 Cardiac Pathology

Congestive Heart Failure — a clinical syndrome that can result from any structural or functional cardiac
disorder that impairs the ability of the ventricle(s) to fill with or eject blood thus resulting in
congestion of blood trying to enter the failing ventricle and reducing the amount of blood being
ejected with each contraction. E.g. from ischaemic heart disease
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@ What is the difference between angina & a myocardial infarction (MI)

Both are caused by ischaemia but in angina is transient myocardial ischaemia and blood is restored to
the tissue before necrosis occurs. Necrosis is seen in a myocardial infarction because thereis a
complete obstruction of blood flow in the coronary arteries, and this will trigger an acute
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inflammatory response and repair process.

e@ Describe the inflammation & repair that occurs following an MI

The infarcted tissue would stimulate the acute inflammatory response so there would be hyperaemia,
oedema and the infiltration of the tissue by neutrophils. Hyperaemia increases hydrostatic pressure
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causing fluid to leak from the vessels into the damagedtissue. In addition, increased vascular
permeability allows plasma proteins to also enter the damaged tissue hence the oedema is an
exudate.

Becausethe heart is a permanent tissue, the formation of granulation tissue would follow;
macrophageswill move into the necrotic tissue and continue to removeit along with the increasingly
apoptotic population of neutrophils. Fibroblasts would migrate into the area and secrete collagen 33yAt42JnkxG5z

fibres tofill in the space once occupied by dead myocytes and newcapillaries (angiogenesis) would
sprout into the area to provide growth factors, oxygen and nutrients for the granulation tissue.
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Oncethe dead cells are removed and the tissue deficit filled with collagen, the macrophages and
fibroblasts migrate away and the new capillaries regress (die of by apoptosis). As this is a case of
organization as part of acute inflammation, the granulation tissue would mature into a collagen scar
which contracts over time pulling the edges of parenchymal tissue together

e@ Briefly describe what complications can occur following an MI
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The adult human myocardial cells are permanent and so incapable ofproliferation thus healing is
through organisation. It is good that this can occur so that it is possible to survive following a heart
attack. However, the scar tissue is weaker than the original myocardium and this area of weakness
may form an aneurysm and rupture. In addition, the scar tissue can encourage a thrombus or blood
clot to form over it which can shed emboli into the circulation. The scar tissue will also not relay
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electrical impulses in the same way as the original tissue and overall the remaining myocytes will have
to take on a greater workload.

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 @ Describe the causesofleft- versus right-sided heart failure (HF).

Left sided Heart Failure Right sided Heart Failure
Most often caused by: ischaemic heart disease, Most often caused by: left-sided heart failure as
systemic hypertension from atherosclerosis, any increase in the pulmonarycirculation from
aortic/mitral valvular disease left-sided failure inevitably burdens the right;
valve disease, pulmonary hypertension caused by
Due to passive congestion of blood backing up in COPDs or pulmonary emboli
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the pulmonarycirculation; stasis of blood in the
left-sided chambers; and inadequateperfusion of Due to pulmonary hypertension — high blood
downstream tissues leading to organ dysfunction pressurethat affects arteries in lungs and the
right side of the heart

@ What are the ‘backward’ effects of left- versus right sided HF & what symptoms do they cause.
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Left sided Heart Failure Right sided Heart Failure
- reduced venous return of oxygentated blood - congestion in the systemic venouscircuit = fluid
from pulmonarycircuit buildup in lower limbs and veins (jugular) =
- Fails to receive enough blood, blood builds up in increase venous pressure = oedema in venous
lower pressure circuits = pulmonary congestion system
= increased hydrostatic pressure = pulmonary - congestion and necrosis in organs (liverand
oedema kidneys) with a large outflow into the vena cava

Symptoms: Dyspnea- shortness of breath/cough Symptoms: peripheral oedema - swollen legs and
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with blood-tinged phlegm from microscopic ascites
haemorrhaging in lungs

First organ to be affected: lungs First organ to be affected: liver 33yAt42JnkxG5z

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@ What are the ‘forward’ effects of HF i.e. what compensatory mechanisms are triggered from a
reduction in cardiac output?

Left sided Heart Failure Right sided Heart Failure
- blood builds up in lower pressurecircuits
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- can’t pump blood into lungs (pulmonary
- reduced cardiac output = renal compensation congestion) = reduced gas exchange = less
via RAAS: reduced renal perfusion, increased oxygen, more carbon dioxide in body
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vascular resistance, salt/water retention, - decreased cardiac output = renal compensation
increased blood volume via RAAS
Angiotensin II = increased vasoconstriction =
increased vascular resistance
Aldosterone = increase retention of
sodium/water = increase in blood volume
Blood pressure will appear normal due to the loss of cardiac output, even though kidneys are
compensating

e@ Describe some of the common causes & possible consequences of endocarditis.

Endocarditis is inflammation of the inner lining of the heart, typically in the valves. Endocardial cells
are stable, and will proliferate if stimulated to. However, valves are mainly connective tissue and are
avascular so will take longer to heal following an acute inflammatory response.

If valves are infected by micro-organisms and infective endocarditis occurs, bacteria could colonise
the platelet thrombus and eventually embolise to spread the infection to distant sites

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Stenosis = valve does not open properly = vascular resistance = heart has to work harder to pump =
predisposing to congestive heartfailure
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 Incompetence= valve does not close properly = backflow of blood = chamber of heart affected is
moreprone to fluid overload = predisposing to congestive heart failure

@ Describe some of the common causes & possible consequences of pericarditis.
33yAt42JnkxG5z

Pericarditis is inflammation of the membranous sac surrounding the heart. Pericardial disease can be
causedby infection, autoimmune disease, secondary cancer or spread of an inflammatory response
caused by a myocardial infarction. An acute inflammatory response could lead to haemorrhage due to
weakened areas. Some possible consequences are pain, constrictive pericarditis and cardiac
tamponade, which reduces diastole, stroke volume and cardiac output potentially leading to failure.

@ What impact does ageing have on the cardiovascular system?

As we age, welose functional cells due to increased senescence. Cells become less efficient as there
are less mitochondria to help power them. Since there are fewer cells, hypertrophy can be seen in
myocytes as the heart has to work harder

Aging also increasesthe stiffness of large arteries and atheroscelerosis
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Week 5 Resipratory Pathology 33yAt42JnkxG5z

Atelectasis - incomplete expansion of the lungs, collapsed lung, producing areas ofrelatively airless
pulmonary parenchyma. 33yAt42JnkxG5z

- Compression atelectasis results whenever significant volumes offluid (transudate, exudate or blood),
tumour or air (pneumothorax) accumulate within the pleural cavity
- Resorption atelectasis stems from complete obstruction of the airway e.g. from a tumour, mucosal
plug
- Contraction atelectasis occurs when focal or generalised pulmonary or pleural fibrosis (tissue
becomes damaged/scarred - organisation) preventsfull lung expansion

@ Define the 4 main COPDs(asthma, chronic bronchitis, bronchiectasis & emphysema), their
causes & possible consequences, pay particular attention to atopic asthma.

Chronic Obstructive Pulmonary Diseases (COPDs) - caused by impaired (increased resistance) airflow
due to partial or complete obsrtuction at any level of the bronchial tree (trachea -> bronchi ->
terminal and respiratory bronchioles). Decreased max airflow rates during forced expiration measure
via FEV;, FEV,/FVC (less than 80%)
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Chronic Bronchitis - persistent productive cough that lasts for at least 3 months in at least 2
consecutive years, in the absence of any other identifiable cause. Common in habitual smokers and
inhabitants of air polluted cities. Those with asthma or cystic fibrosis are also at risk as they have
increased mucous secretion in the airways as well.
chronically inflamed airways: accelerates decline of lung function, lead to cor
pulmonale/heart failure, cause atypical metaplasia, hyperplasia, and dysplasia of
respiratory epithelium which could transform into cancer
: Cigarette smoke/pollutants damageciliary action of the respiratory epithelium and
thickening of bronchial walls, preventing clearance of mucous (formation of mucous plug)
and increasing risk of infection

Bronchiectasis - Irrerversible and progressive dilation of bronchi and bronchioles due to destruction of
smooth muscle and elastic tissue caused by chronic necrotizing infections (from bacterial infections
33yAt42JnkxG5z

like pneumonia), bronchial obstruction (from tumour, foreign bodies, mucous), cystic fibrosis, COPDs.

Emphysema - Irreversible and progressive (ongoing acculmulation of inflammatorycells) destruction
of alveolar walls without obvious firbrosis. Airspaces become abnormally enlarged from the
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destruction of alveolar wall, which leads to oxidative stress, apoptosis, and less surface area

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 (capillaries) for gas exchange. Inflammation and loss of elasticity means lungs can expand but deflate
poorly = difficultly exhaling carbon dioxide.
Causes: chronic bronchitis. Asthma, coal dust exposure, smoking, genetics (congential a-1-anti-trypsin
deficiency)

Asthma - chronic inflammatory disorder of the conducting airways caused by hyper-reactive airways.
Marked by episodic bronchospasm due to increased airway sensitivity to a variety of stimuli,
inflammation of the bronchial walls, and increased mucous secretion.

@ What is pneumoconiosis, which particles are commonly implicated in Australia & what can they
cause.

A restrictive pulmonary disease. Chronic interstitial lung disease caused by inhalation of mineral
dust/particles encountered in the workplace e.g. coal - anthracosis, silica - silicosis, asbestos -
asbestosis. (The disease is chronic as the stimulus remains, the repeated attempts at repair increase
the risk of cancer in these patients)

In pneumoconiosis the lung may heal through organisation, which distorts the normal structure of the
lung making it hard to breath, which can result in weight loss, respiratory failure & Cor pulmonale,

Prognosis depends on: amount inhaled, shape/size of particles, solubility of particles, toxicity of
particles, additional irritants (smoking)
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@ Describe the innate defenses present in the conductive & respiratory portions of the lungs.
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Ciliated epithelium & mucous, cough/sneeze reflex, macrophages, gobletcells, anything that is not a
lymphocyte (adaptive immunity). Conditions that can reduce these innate defenses

@ What is pneumonia & what are the major differences between lobar & bronchopneumonia.

Pneumonia is a bacterial/viral/fungal pulmonary infection of the alveoli. Bronchopneumonia common,
mainly affecting immune-compromised individuals and involving an opportunistic infection (less
virulent). Whereas, lobar pneumonia involves bacteria of high virulence, which are either breathed in
or travel to the lungs during septicaemia/sepsis. It may affect anyone who encounters the pathogen
(previously healthy people) and results in a strong acute inflammatory response that affects the
entire lung or lobe oflung.

Possible complications: necrosis - abscess, fibrosis, supparative fluid in the pleural cavity,
haematological dissemination of bacteria (endocaritis, meningitis, osteomyelitis, glomerulonephritis)

e Using a diagram, describe the pathogenesis of the 2 most common primary cancers affecting the 33yAt42JnkxG5z

lungs.
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Metaplasia:
‘Change from 1 well-
differentiated/mature cell type
into another well-differentiated
cell type 33yAt42JnkxG5z

qo |, Phenotype abnormal inechelerdnans

Increase cell number

@ Why are the lungs a common site for secondary cancers?

33yAt42JnkxG5z

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 Cancers that enter the blood usually do so from lymph, capillaries or venules and since all venous
blood returns to the lungs for re-oxygenation, they are commonly affected by secondaries

@ Howare the lungsaffected by left ventricular failure?

Pulmonary congestion is the passive accumulation of blood within the vessels of the lung that may be
caused by obstruction of blood flow through the lungs or through the left side of the heart, which
may be caused byleft-ventricular heart failure or mitral and aortic valve disease.

@ How do lung diseases contribute to right ventricular failure?

Pulmonary congestion leads to pulmonary hypertension (there is increased resistance to blood
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entering the lungs) & therefore the right ventricle will work harder & thus hypertrophy.
Pulmonary congestion is a consequence ofleft ventricular failure.

Week 6 Renal Pathology

¢ renalbody, pay particular
33yAt42JnkxG5z

attention to the cardiovascular, haematological & skeletal systems.

Causes: systemic hypertension, diabetes, heart diseases, obesity, smokers, over 60
33yAt42JnkxG5z

Cardiovascular
- leads to the over-activation of the renin-angiotensin Il-aldosterone system. Angiotensin II stimulates
vasoconstriction which increases vascular resistance
- aldosterone initiates the retention of sodium and which retains water and increases blood volume
- increased blood volume = increased hydrostatic pressure = oedema which can be worsenedif the
patient suffers from proteinuria = loss of proteins in urine = reduced plasma proteins and oncotic
pressure
- an overactivated RAASleads to systemic hypertension
- systemic hypertension is a risk factor of atheroscelrosis which can cause left ventricular hypertrophy
and ischaemic heart disease. Cross activation with sympathetic nervous system = increased heart
rate and force of contraction

Skeletal
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- reduced activation of vitamin D, which decreases the absorption of calcium in the small intestine.
- decreased levels of calcium stimulates the thyroid gland to secrete more parathyroid hormone,
which the kidneys no longer respond to,but still signals to osteoclasts to release calcium and
phosphate from bonesinto the blood
- calcium is unable to be absorbed, so is mostly excreted in urine, however excess phosphate remains
in the blood and causes soft-tissue calcification leading to renal osteodystrophy. Calcium building up
in arteries can lead to stenosis and eventually atherosclerosis

Haematological
- reduced erythropoietin = reduced synthesis of erythropoiesis leading to anaemia and lethargy.
Worsenedif patient suffers from haematuria
- metabolic acidosis from kidneysinability to remove H+ from the blood and synthesis of bicarbonate
ions. As a result, the tissues take up excess H+ in exchange for K+ which leads to hyperkalaemia -
excess potassium in the blood. Hyperkalaemia can cause muscle stiffness or potentially life
threatening cardiac arrhythmias
- increased nitrogenous wastes due to kidney’s inability to remove urea contributes to chronic
posining due to uraemia which leads to poor immunity (increased infections), anorexia, neuropathy,
abnormal platelet functions

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 @ What are the main malignancies that affect the male & female urinary systems?

Renal Cell Carcinoma - kidney epithelial cell; invades through the renal capsule
Causes: smoking, obesity, radiation, acquired cystic disease, genetics (rare)
Early stages are asymptomatic but tumour is large at the time of diagnosis and patients present with
haematurai, mild flank pain, abdominal mass

Transitional Cell (Urothelial) Carcinomas

Patients with urinary cancers often present with blood in the urine, mild flank pain, an abdominal
33yAt42JnkxG5z

mass or obstruction late in the progression of the disease, the early stages are asymptomatic.

Nephroblastoma - a malignant tumour originating in nephrons

Males - Benign prostatic hyperplasia (adenoma) and Carcinoma of the prostrate (adenocarcinoma)

@ What are common causes of glomerulonephritis & possible consequences? 33yAt42JnkxG5z

Acute Glomerulonephritis - inflammation of the glomeruli (where blood is filtered in each of the
nephrons). Often leads to chronic condition and renal failure

Common causesare blood-born stimuli (frequently immune mediated) and affect all the glomeruli in
both kidneys (inflammation) which leads to renal failure. Inflammation can lead to swelling of the
endothelium, lowering blood flow, and necrosis. Inflammation alters the permeability.

Results in: lowered urinary output (from lowered glomerular filtration rate as kidneys lose function),
proteinuria, haematuria, hypertension, persistent headache

Chronic glomerulonephritis leads to chronic kidney failure by progression of the disease process
(usually an immunologically- stimulated inflammation) from its origin in the glomeruli to the tubulo- 33yAt42JnkxG5z

interstitial area and to the blood vessels. The arterial vessels in the glomerulus also provide blood
supply to other areas of the kidney. All areas of the kidney can become involved leading to reduction
in function. Both kidneys are commonlyinvolved and as the function of both kidneys reduces, the
clinical state of end-stage renal failure follows.

@ Why is the renal papilla susceptible to toxic injury & ascending infections?
33yAt42JnkxG5z

The renal papilla is the apex of the renal pyramid which projects into the minor calyx. At this point,
urine is at it’s most concentrated so anytoxins will highly affect the area.
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Papillary necrosis occurs in analgesic nephropathy (chronic renal disease caused by excessive intake of
analgesic mixtures) and in acute pyelonephritis mainly in diabetics and in those with urinary tract
obstruction & ascending infections, as the renal papilla is more delicate. 33yAt42JnkxG5z

Pylonephritis is an ascending infection that effects the pelvis tubules and medulla (including renal
papillae) and is unilateral. Acute inflammation is caused by a bacterial infection (like UTI) that reaches
by blood or by spreading to the kidney from the lower urinary tract. Chronic is formed by repeated
infections or obstruction in the lower urinary tract e.g. urinary stones

@ What are the major differences between ascending & descending infections & why are the
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former more common in females versus males?

Routes of entry for microbes infecting the kidney include haematogenous (descending) and urinary
(ascending) spread.

Descending infections are likely to be blood-borne and affect both kidneys diffusely (both males and
females), which leads to renal failure.

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 Ascending infections are morelikely to affect 1 kidney and usually only a segment of that kidney
(females at higher risk). Ascending infections start as inflammation in the bladder (cystitis) and ascend
through the urinary tract (ureters) to the kidneys where they develop into pyelonephritis.

Ascending infections are more common in females due to their shorter urethras, which shortens the33yAt42JnkxG5z

distance that bacteria must travel to reach the urinary bladder, as well as the close proximity of the
urethra to the gastrointestinal tract/anus which is non-sterile. Menopausecan lead to more UTIs in
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women as the decreased secretion of mucous makesit more prone to bacterial infections. Lack
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antibacterial function of prostrate fluid

@ What are the possible causes & consequences of urinary stones?

Causes:
Stasis of urine which may be caused by obstruction of urine flow
Infection which can contribute to obstruction and act as a nidus
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Pre-existing or previous incidence of stones
Dehydration due to excessive water loss (diarrhea, vomiting, excessive sweating, lack of food/fluid
intake)
Calcium metabolism disorders (rare) and gout which wewill cover in bone and joint week
33yAt42JnkxG5z

Consequences:
1. Pain - urinary/renal colic if stone is in muscular tube (ureter) and peristaltic wave compresses the
wall on the stone causing ischaemia and pain (colic pain comes and goes with each peristaltic wave)
2. Bleeding from damage tolining epithelium of renal pelvis or urinary tract (clinical summary: painful
haematuria - stoneslikely; painless haematuria - urinary tract cancer is possible);
3. Obstruction of urine flow - depends on the site (ureteric stone at high risk, bladder stone less risk of
obstruction) - obstruction leads to infection, stones and renal atrophy (hydronephrosis - where one or
both kidneys become stretched and swollen as a result of urine build-up); 33yAt42JnkxG5z

4. Predispose to infection - stone may damage lining epithelium reducing the defence against
microorganism invasion; obstruction also predisposes to infection;
5. May encourage morestone formation (nidus).
6. May causechronic irritation (metaplasia from transitional to stratified squamous epithelium) and
cancer.
7. Severe cases can result in loss of water (dehydration) and hyponatraemia (unlikely in Australia as
treatment administered).

Week 8 Boneand Joint Pathology
33yAt42JnkxG5z

Osteoarthritis Rheumatoid arthritis Gout
Wear & tear resulting in Chronic autoimmune destruction Common systemic metabolic
loss of cartilage. of joints that may affect any disorder - from the breakdown of
synovial joint (joints that have purines (found in meat and
Degenerative joint disease space between the adjoining alcohol) which creates uric acid
bones) in the body & causes
systemic inflammation.
Causes: Causes: Causes:
Aging, predisposing joint Genetic predisposition and Hyperuricaemia in vulnerable
deformity, underlying environmental influences. Affects people (not everyone with
systemic disease e.g. women more than men hyperuricaemia gets gout
diabete, affects both though), heavy alcohol
genders Can be diagnosed at any age but consumption, obesity, fructose-
Becauseit’s caused by typically it is first diagnosed in sweetened drinks. Affects more
wear & tear it is mostlikely middle age men than women (rare before
to occur in the elderly, menopause)
overweight or people who

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 have engaged in sports Increased incidence in age but
such as netball, AFL & can be diagnosed at any stage of
running life
Progression: Progression: Progression:
Thereis little inflammation Pannus formation around the joint Monosodium urate crystals form
compared to other forms space (extra growth/deformities = in joints & soft tissues causing
of arthritis but reactive pain, swelling, damage)
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severe pain & inflammation
bone growth & swelling to Persistent synovitis
surrounding soft tissues The joints are affected by chronic
inflammation (type IV cell
mediated response)
Consequence: Consequence: Consequence:
Tends to affect weight Affects multiple and smaller joints Often affects the big toe (tophi)
bearing joints (1 or 2) in hands and feet in men

Causes pain and impaired Bone erosion, cartilage & tendon In women, tends to affect joints
movement degradation > irreversible joint in the hands
deformation
Uric acid urinary stones can also
form in kidneys and increaserisk
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of kidney disease

@ List the main types of fractures & how healing may be impaired

Simple - closed, broken bone has not pierced skin
Greenstick - closed, small, slender crack in bone, can occur in children (bone notfully mineralised)
Impacted - 2 bones forced (compressed) against each other 33yAt42JnkxG5z

Compounded - open fractures lead to greater risk of bacterial infection (osteomyelitis in bone and
bone marrow) and mostdevastating
Comminuted - bone is shattered into small pieces, most devastating

Healing can be impaired if we move the bone while it’s repairing; if it becomes infected; poor
nutrition; or if it’s a pathological fracture (occurs in bones already weakened by disease)
Spiral haematoma > soft callous > hard callous > remodelling

Pathologic fractures - pre-existing bone diseases: osteoporosis, osteomalacia/rickets (under-
mineralised organic matrix and osteoid = softening of bones) , osteomyelitis, primary & secondary
malignancies, paget’s disease, renal osteodystrophy

e List the factors that contribute to attaining peak bone mass

Physical activity
Genetic factors
Good nutrition
Hormonal influences as we are growing and developing 33yAt42JnkxG5z

33yAt42JnkxG5z

Important to attain peak bone mass as bone atrophies with age

@ List the risk factors for the development of osteoporosis; the possible consequences of
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osteoporosis & how bone loss may be retarded/accelerated

Risk factors include: low starting bone mass (determined by genetics, diet & exercise), ageing,
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reduced physical activity, amenorrhea, loss of oestrogenic activity after the menopause, sarcopenia

Consequences: pathological fractures, reduced activity/independence, impacts on drug prescription
and other diseases
33yAt42JnkxG5z

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 Bone loss may be accelerated by: glucocorticoids, corticosteroids, chronic use of non-steroidal anti-
inflammatory drugs (e.g. ibuprofen, asprin), amenorrhea (loss of menstrual cycle - can be seen in
women with eating disorders), reduced muscle mass/sarcopenia

Bone loss may be retarded by: testosterone, oestrogen, resistance/weight training
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33yAt42JnkxG5z

33yAt42JnkxG5z
@ What are 2 complications of Paget's disease of bone and why might they occur?

Deformed bone (weight bearing in weak bones) and pathologic fractures (weak bone less resistant to
external forces). Also, pain and compression of cranial nerves which may cause deafnessor visual
disturbances as a result of bony foramina - acoustic and optic nerves becoming narrower due to
abnormal bone increasing in thickness, osteosarcoma, hydrocephalus resulting from narrowing of
foramina which obstructs cerebrospinal fluid flow.

Treatment: calcitonin and biophosphates

@ List the tumours that occur in the skeletal system (reviewing what was covered in neoplasia
week).

Benign tumours:
Chondroma, osteoma, fibroma, giant cell tumour

Malignant:
Osteosarcoma - will most likely be seen in children as their bones arestill continuously developing,
Chondroscarcoma, Ewing’s sarcoma (develops during embryogenesis)

Bone is actively growing in young people and most osteosarcomas occur in the actively growing 33yAt42JnkxG5z

33yAt42JnkxG5z
epiphyseal plates. Increased proliferation is a major risk factor in the development of cancer. Once
the active growth of bones has been completed the risk of developing osteosarcoma plummets.

@ Why are the bones frequently affected by metastatic/secondary cancer?

The boneshavea rich blood supply and contain many growth factors. Bone is very vascular, so arterial
metastases are easily distributed to this site plus it’s a good site for tumour cells to become trapped.
Bone metastases are found in more than 25% of people who die from cancer over all but 75% of
people who die from breast cancer.

@ What impact doesrenal failure have on the musculoskeletal system?

The healthy kidneys activate vitamin D which is required by the gut to absorb calcium and the kidneys
regulate the levels of calcium and phosphatein the blood. Under the influence of parathyroid
hormone (PTH), the healthy kidneys activate more vitamin D, secrete phosphate and reabsorb
calcium from the filtrate thus keeping it in the blood.
33yAt42JnkxG5z

Chronic renal failure can cause renal osteodystrophy (under mineralization of bone & soft tissue
calcification). In failure, the kidney may not be able to convert vitamin D into its active metabolite
(activated by chemical changes in the kidney) and without active vitamin D the gut cannot absorb
calcium from food, which results in low levels of serum/blood calcium. 33yAt42JnkxG5z

The control of the plasma concentration of calcium is finely controlled, PTH is released in response to
low serum calcium and promotesresorption of calcium from bonesby osteoclasts and induces the
kidney to retain calcium in blood, excrete phosphateand activate more vitamin D. In renal failure, less
vitamin D is activated and calcium is lost in urine so serum levels decline resulting in increased PTH
secretion. The result is liberation of calcium from bones which forms complexes with the high levels

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 of phosphatein the blood which can be depos