Mechanisms Of Disease

Question 0

Give four differences between the processes of oncosis+necrosis and apoptosis.

Answer 0

Oncosis - blebbing
Apoptosis - budding

Oncosis - inflammation
Apoptosis - no inflammation

Oncosis - swelling
Apoptosis - no swelling

Oncosis no membranes maintained
Apoptosis - membranes maintained

Question 1

Name four types of necrosis and give an example of where each might be found.

Answer 1

Coagulative - heart in MI. Caused by protein denaturation
Liquefactive - brain. Caused by enzyme digestion in areas of little stromal support

Caseous - lungs in TB
Fat - pancreas

Question 2

Which type of necrosis is associated with granulomas?

Answer 2

Caseous

Question 3

What happens to the nucleus after cell death (necrosis)?

Answer 3

Pyknosis - shrinks
Karyorrhexis - breaks apart
Karyolysis - completely dissipates

Question 4

Give one example of apoptosis occurring in a useful way and one example of it occurring in a pathological way.

Answer 4

Sculpting during embryogenesis eg the interdigitation of the fingers.

Graft vs host disease or cancer

Question 5

What is the difference between hypoxia and ischaemia?

Answer 5

Hypoxia is the lack of oxygen to the tissues due to a number of reasons eg anaemia, reduced respiration rate. Another reason for hypoxia might be ischaemia which is the blockage of the blood supply to the tissues. Ischaemic tissue is not only missing oxygen but the other plasma contents.

Question 6

What is the difference between blood plasma and serum?

Answer 6

Plasma contains platelets

Question 7

Describe 3 physiological processes which occur during reversible hypoxia injury.

Answer 7

1. Na/k ATPase stops working. Gradient no longer upheld and Ca+ and Na+ enter the cell. Water follows and it swells.
2. Glycolysis is unregulated to try to produce more ATP. This makes the pH more acidic and chromatin clumps together.
3. Without ATP ribosomes detach from the ER and protein production reduces.

Question 8

When hypoxic injury is irreversible, what happens to the cell?

Answer 8

The membrane becomes leaky and there is a huge influx of calcium. This activates a number of enzymes eg ATPase, phospholipase, protease, endonuclease which digest the cell. ATPase makes it happen even faster.

Question 9

What pigment builds up in the cell to form a bruise?

Answer 9

Haemosiderin

Question 10

What five classic symptoms are observable during acute inflammation?

Answer 10

Rubor, tumor, calor, dolor and loss of function.

Question 11

What is the mechanism of acute inflammation?

Answer 11

1. Changes in blood flow
   - (constrict) dilation
   - increase permeability
   - increase viscosity (rbcs)
2. Exudate
3. Infiltration of neutrophils and fibrin

Question 12

In acute inflammation what four changes occur to the blood flow?

Answer 12

1. Transient vasoconstriction
2. Vasodilation
3. Increased permeability
4. Increased viscosity/stasis

Question 13

What are the two key differences between an exudate and a transudate? When might each of them be found?

Answer 13

Exudate - 1. protein rich fluid loss 2. due to both osmotic pressure and oncotic pressure in the interstitium. Found in acute inflammation.

Transudate - 1. Low in protein 2. due to osmotic pressure only. Found in heart failure.

Question 14

Name four key chemical mediators of acute inflammation.

Answer 14

Histamine
Cytokines - bradykinin
Leukotrines
Complement - C3a, C5a, IL-1

Question 15

Give 4 systemic effects of acute inflammation.

Answer 15

Fever
Leukocytosis
Increase in c reactive protein
Possible shock

Question 16

What is the main white blood cell type involved in acute inflammation?

Answer 16

Neutrophils/polymorphs (same thing)

Question 17

Describe how neutrophils leave the blood vessel and enter the tissue. Is it an active or passive process?

Answer 17

1. Chemotaxis - attracted along chemical gradient
2. Rolling along the sides of the vessel.
3. Adhesion by integrins
4. Aggregation
5. Diapedesis - force their way between cell junctions and digest the basement membrane

Passive

Question 18

When might a chronic inflammation arise in relation to an acute inflammation?

Answer 18

1. After an unresolved acute inflammation
2. Alongside a severe acute inflammation
3. Without an acute inflammation eg TB, autoimmune arthritis

Question 19

What are the key features of chronic inflammation?

Answer 19

Fibrosis
Macrophages
Lymphocytes

Can have - pus, granuloma, giant cells

Question 20

What is the major white blood cell involved with chronic inflammation?

Answer 20

Macrophages

Question 21

Give three functions of a macrophage.

Answer 21

1. Phagocytosis
2. Present antigens to T lymphocytes to trigger production of antibodies
3. Secrete substances such as cytokines to further immune response

Question 22

What are antigens and antibodies?

Answer 22

Antigens are signal proteins on bacteria cell walls which are recognised by lymphocytes. The T lymphocytes then produce antibodies to specifically attack that bacteria.

Question 23

How is fibrosis caused? Give an example.

Answer 23

Overstimulation of fibroblasts by cytokines during chronic inflammation leads to excessive scar tissue and shrinkage. Eg cirrhosis of the liver.

Question 24

What is a granuloma? Give two situations which might cause a granulomatous inflammation.

Answer 24

The body’s response to insoluble particles.

1. Foreign body eg a splinter
2. Hypersensitivity to a molecule eg. TB, sarcoidosis, crohns

Question 25

What is a giant cell? Give three specific types of giant cell and describe their nuclei.

Answer 25

When macrophages fuse together.

1. Langhans - nuclei in a peripheral ring
2. Touton - nuclei in a central ring
3. Foreign body - nuclei randomly spaced

Question 25

In what type of inflammation would you find a giant cell?

Answer 25

Chronic granulomatous inflammation.

Question 25

Describe the type of inflammatory response you would expect to see with a TB infection.

Answer 25

Caseous necrosis

Granulomatous inflammation with Langhans giant cells

Question 26

What kind of protein can build up in an alcoholic liver?

Answer 26

Malory’s hyaline from altered keratin

Question 27

What causes reperfusion injury?

Answer 27

When blood is returned to an area after ischaemia, endothelial cells produce more reactive oxygen species, causing damage to the reperfused tissue.

Question 28

What are free radicals? Give 4 ways they can be produced in the body.

Answer 28

Highly reactive ions which cause damage to tissue. Eg. OH, 1/2o2, ONOO, H2O2
Can be produced by Fenton reaction, Haber Weiss reaction, radiation, escape from electron transport chain.

Question 29

What is the difference between a red and white infarct? Where math they occur?

Answer 29

A White infarct is simple occlusion of blood and tissue death.
Red infarct haemorrhages after death.

White occur where there is solid stroma eg heart, kidney, spleen
Red occur where there is loose stroma eg lungs, gonads, colon

Question 30

What are the body’s natural defences against reactive oxygen species?

Answer 30

SOD enzyme plus catalase
NADPH keeps up stores of glutathione
ACE vitamins

Question 31

Describe the mechanism of apoptosis.

Answer 31

Intrinsic - activation of p53 increases permeability of mitochondria, cytochrome c is released which creates an apoptosome and interacts with caspases

Extrinsic - ligand such as TRAIL activates caspases

Caspases cleave up the cytoskeleton

Question 32

What is the function of heat shock proteins? Give an example.

Answer 32

After cell damage, they collect up damaged proteins, unfold them and take them back to the endoplasmic reticulum to be re folded.
Eg chaperonins

Question 33

What is granulation tissue? Name some of its contents.

Answer 33

Early scar tissue - proud flesh

Fibroblasts
Type 3 collagen (later replaced by type 1)
Macrophages and neutrophils
Lots of new blood vessels

Question 34

Define haemostasis

Answer 34

The collection of processes which maintain blood volume by preventing excess bleeding.
Requires vessel wall, platelets, coagulation and afterwards fibrinolysis

Question 35

What is virchow’s triad?

Answer 35

Triad of risk factors for thrombosis:

Blood components
Blood flow
Vessel wall

Question 36

Define thrombosis

Answer 36

Formation of a solid mass of blood in the circulation

Question 37

Give three differences between the appearances of venous and arterial thrombosis.

Answer 37

Venous - dark red
             - lots of cells
             - soft
Arterial - pale
            - not many cells - lines of zahn form striped between cells and fibrin
            - hard
            -

Question 38

What are the 5 possible outcomes of a thrombus?

Answer 38

1. Lysis
2. Propagation - progressive spread towards the heart because of stagnant blood. (Backwards in arteries and forwards in veins.)
3. Organisation - granulation tissue then scar
4. Re canalisation - channels form through the scar
5. Ischaemia - eg DVT, MI, stroke depending on location

Question 39

Define an embolus and give 4 substances which can form one.

Answer 39

Obstruction of a blood vessel at a distant site.
Can be formed by-
1. Thrombus (thrombo embolus)
2. Air
3. Fat
4. Nitrogen
5. Amniotic fluid

Question 40

What are the contents of granulomatous inflammation? (Granulomas)

Answer 40

Epithelioid cells and macrophages

Plus sometimes fibroblasts and giant cells

Question 41

What happens during the vascular phase of the clotting cascade?

Answer 41

Vessels transiently dilate then constrict
Tissue factors from endothelium activate extrinsic pathway
Collagen activates the intrinsic pathway
Von willebrand factor activates platelets

Question 42

What happens during the platelet phase of the clotting cascade?

Answer 42

Platelets are released from megakaryocytes
Formation of the primary plug
Gla residues attract the clotting factors

Question 43

What happens during the coagulation phase of the clotting cascade?

Answer 43

Extrinsic pathway and intrinsic pathway meet at factor 10 - prothrombin
Activate thrombin which activates fibrin which attaches to the primary plug and forms a clot

Question 44

What is measured by 1. Bleeding time 2. Prothrombin time 3. PTTK?

Answer 44

1. Platelet activation and formation of primary plug
2. Extrinsic pathway of clotting cascade
3. Intrinsic pathway of clotting cascade

Question 45

What tissue factors are absent in Haemophilia? What measure will increase?

Answer 45

8 and 9

Increase in PTTK

Question 46

What is missing in Von Willebrands disease? What measure will increase?

Answer 46

Von willebrand factor which activates platelets

Bleeding time will increase

Question 47

What measure will increase in a vitamin k deficiency?

Answer 47

INR (prothrombin time)

Question 48

Name 4 substances which help fibrinolysis and name the substance they act on.

Answer 48

Anti thrombin c - clotting factors
Plasminogen - fibrin
Protein c and thrombomodulin - thrombin
Prostacyclin - platelets

Question 49

When would each of the following drugs be used to break down a clot?
Aspirin
Streptokinase
Heparin
Warfarin

Answer 49

1. Chronic - platelet action
2. Emergency - clotting factor action
3. Acute - clotting factor action
4. Chronic - clotting factor action

Question 50

What is the difference between atheroma and atherosclerosis?

Answer 50

Atheroma is the accumulation of intra and extra cellular lipid in the intima of arteries.
Atherosclerosis is the hardening of the arterial wall as a consequence.

Question 51

How does atheroma develop macroscopically?

Answer 51

Fatty streak
Simple plaque - fibrosis/necrosis
Complicated plaque - extends to media

Question 52

How does atheroma develop microscopically?

Answer 52

Smooth muscle proliferation
Macrophages, Foam cells and extra cellular lipid
Fibrosis/necrosis
Extends to the intima

Question 53

Describe the pathogenesis of atheroma.

Answer 53

1. Endothelial injury - eg high ldl, bp, ox stress
2. Platelet adhesion, releases growth factor, smooth muscle proliferates
3. Lipid insudation - uptake by smooth muscle and free lipid
4. Macrophages and foam cells aggregate in the intima

Question 54

What is intermittent claudication and what does it indicate?

Answer 54

Aching pain on exercise, classically in the leg that eases with rest.
Indicative of peripheral vascular disease - atheroma in the peripheral arteries

Question 55

What are the risk factors for atheroma?

Answer 55

Age and gender

Smoking and alcohol

Hyperlipidaemia
Hypertension
Diabetes

Question 56

What are stem cells?

Answer 56

Undifferentiated cells which can both divide and differentiate. They can divide indefinitely because they express telomerase.

Adult - uni potent except haemopoetic
Embryonic - pluripotent

Question 57

How do stem cells divide and differentiate?

Answer 57

1. Stem cell divides - one for self renewal and one differentiates into a progenitor cell
2. Progenitor cell is the one which divides continuously

This protects the original stem cells from too much division which would increase the risk of mutation.

Question 58

What are the three types of stem cell and where are they found?

Answer 58

Labile - divide constantly eg blood, epithelia
Stable - normally quiescent but can divide eg liver, bone
Permanent - cannot mount an effective proliferation eg neurones, skeletal muscle

Question 59

What is the difference between hyperplasia and hypertrophy? Give examples of each.

Answer 59

Hyperplasia is an increase in cell number eg psoriasis, thyroid goitre
Hypertrophy is an increase in cell size eg skeletal muscle, pregnant uterus

Question 60

Define metaplasia. Give two examples.

Answer 60

The process of a cell being replaced by another differentiated cell type.
Eg barratts oesophagus
Or pseudo stratified ciliates respiratory - stratified squamous in a smoker

Question 61

Define atrophy. Give two examples.

Answer 61

Decrease in cell size and cell number

Eg dementia, post menopause ovary

Question 62

Define aplasia.

Answer 62

Congenital hypoplasia - a complete failure to develop a body part

Question 63

What are the 5 parts of the cell cycle? What happens during each one?

Answer 63

M - mitosis
G1 or G0
S - DNA synthesis
G2

Question 64

What are the options for a cell entering G0?

Answer 64

Quiescence - transient
Replicative senescence - run out of telomere so permanent
Carcinogenic senescence - protective mechanism, permanent

Question 65

What is the restriction point of the cell cycle and when does it occur?

Answer 65

The point of no return- after which a cell will enter the next stage of the cycle. During G1

Question 66

Describe the mechanism which encourages a cell to proliferate beyond the restriction point and enter the cell cycle.

Answer 66

1. Growth factor binds to receptor which activates tyrosine kinase
2. Tyrosine kinase activates RAS
3. RAS activates cyclin D and CDKinase
4. CDKinase phosphorylates and deactivates pRb so it releases transcription factors
5. Cell can progress to DNA synthesis

Question 67

Describe the mechanism that prevents a cell from proliferating and moving beyond the restriction point of the cell cycle.

Answer 67

1. P53 activates CDKinase inhibitor

2. CDKinase does not deactivate pRb so transcription factors are not released

Question 68

Define a tumor suppressor gene and give two examples.

Answer 68

A normal gene which, when altered by mutation can act against the growth of cancer.
P53
pRb

Question 69

Define a protooncogene and give an example

Answer 69

A normal gene which, when altered by a mutation, can contribute to cancer. Eg RAS

Question 70

Define neoplasia.

Answer 70

An abnormal growth of cells that persists after a stimulus is removed.

Question 71

What is the difference between a benign and a malignant neoplasm?

Answer 71

Potential to spread to distant sites.

Question 72

Define dysplasia.

Answer 72

Poorly differentiated cells

Question 73

Describe the features of poorly differentiated cells.

Answer 73

Increase in size of nucleus
Increase in ratio nucleus:cytoplasm 
Hyperchromasia (darker) 
Mitotic figures
Pleomorphism (variation)

Question 74

What is a telomere? What happens over time? Which type of cell is an exception to this rule?

Answer 74

A region of repetitive nucleotide sequences at the end of each chromatid which protects the DNA.
They slowly degrade over time and when they run out, a cell will enter G0 due to replicative senescence
Stem cells secrete telomerase so this does not happen and they can relplicate indefinitely .

Question 75

What is a carcinoma in situ?

Answer 75

As dysplasia (cell differentiation) worsens it will become malignant.
Carcinoma in situ is a malignant dysplasia in a state prior to invasion of the basement membrane.

Question 76

What is the name given to a dysplasia which invades the basement membrane?

Answer 76

Invasive carcinoma

Question 77

Why does ulceration occur around a malignant neoplasm?

Answer 77

Because the neoplasm is growing faster than angiogenesis can occur so the tissue dies.

Question 78

What is the name given to cancer of epithelia?

Answer 78

Carcinoma

Question 79

What is the name given to cancer of stroma such as smooth muscle or fibroblasts?

Answer 79

Sarcoma

Question 80

What is the name given to cancer of haemopoetic cells in the bone marrow?

Answer 80

Leukaemia

Question 81

What is the name given to cancer of white blood cells?

Answer 81

Lymphoma

Question 82

What is the name given to cancer of glands?

Answer 82

Adenocarcinoma

Question 83

Describe 4 local effects of neoplasm.

Answer 83

1. Direct invasion
2. Ulceration
3. Perforation
4. Compression/blocking

Question 84

What are 3 general systemic effects of neoplasm?

Answer 84

1. Increased tumour burden
2. Hormone and growth factor secretion
3. Paraneoplastic syndrome

Question 85

Define tumour burden. If it is increased, what are the effects?

Answer 85

The total amount of neoplastic material distributed throughout the body, increasing metabolic load.

1. Weight loss
2. Malaise
3. Decreased appetite
4. Immunosuppression
5. Increased cytokines and and platelet derived growth factor - thrombosis

Question 86

Define metastasis.

Answer 86

The development and growth of a neoplasm at a secondary site not contiguous with the primary site.

Question 87

What is the difference between the stage and grade of a tumour?

Answer 87

Stage - extent of metastasis and growth

Grade - extent of dysplasia (how poorly differentiated)

Question 89

Is stage or grade a better indicator of current morbidity?

Answer 89

Stage

Question 90

What are the 4 processes which must occur for a neoplasm to grow and invade at its primary site?

Answer 90

1. Epithelial to mesenchymal transmission
2. Adhesion
3. Stromal proteolysis
4. Motility

Question 91

Is stage or grade a better indicator of potential morbidity?

Answer 91

Grade

Question 92

What is epithelial to mesenchymal transmission?

Answer 92

Cancer cell changes to look like a mesenchymal cell so that is can invade unnoticed.

Question 93

How does a cancer cell increase adhesion as it grows?

Answer 93

Decreases E cadherin secretion which allows the cancer cells to bind together
Decreases integrin secretion which allows the cancer cells to bind to the stroma

Question 94

How does a cancer cell activate stromal proteolysis as it grows?

Answer 94

Increases protease secretion from “niche” spy cells

Question 95

How does a cancer cell increase its motility as it invades the basement membrane?

Answer 95

G protein signalling to weaken the actin cytoskeleton

Question 96

What are the three modes of transport available to a cancer cell?

Answer 96

1. Blood
2. Lymph
3. Transcoelomic

Question 97

Where will a cancer cell tend to end up if it travels by blood?

Answer 97

Lung, liver, bone, brain

Question 98

Where are the most common sites for metastasis?

Answer 98

Lung, liver, bone, brain

Question 99

Where will a cancer cell tend to end up if it travels by lymph?

Answer 99

Regional lymph nodes, beginning at the sentinel node.

Question 100

Where will a cancer cell tend to end up if it travels across the coelom?

Answer 100

Within the same coelom eg pouch of Douglas to the rest of the peritoneum

Question 101

Which types of cancer commonly spread to bone?

Answer 101

Hexagon of bone mets

• thyroid/ bronchus
• breast
• kidney
• prostate

Question 102

What is DIC?

Answer 102

Disseminated intravascular coagulation
Lots of clotting everywhere, ischaemia in small vessels
Use up all the clotting factors and platelets so there is uncontrolled bleeding.

Question 103

Give four examples of growth factors.

Answer 103

Epidermal
Vascular endothelial
Platelet derived
Granulocyte colony stimulating

Question 104

What is meant by regeneration/resolution? What must be in tact for it to occur completely?

Answer 104

The growth of functional, differentiated cells and tissues to replace lost structures.
Complete resolution requires a connective tissue scaffold to remain in tact.

Question 105

Describe the processes involved in the formation of a fibrous scar.

Answer 105

Blot clot
Acute inflammation
Chronic inflammation
Angiogenesis
Myofibroblasts infiltrate
Glycoproteins and collagen are produced
Collagen matures and contracts

Question 106

Give four differences between healing by primary and secondary intention.

Answer 106

Primary -

Smaller scar
Quicker to heal, earlier contraction
No granulation tissue
Only occurs with clean incision where there is contact between the layers of epidermis

Question 107

What happens if there is insufficient fibrosis over a wound?

Answer 107

Hernia, ulceration

Question 108

What happens if there is excessive fibrosis over a wound?

Answer 108

Excessive scarring eg keloids

Question 109

What happens if there is excessive contraction of the collagen following fibrous repair?

Answer 109

Limited joint movement - contractures

Obstruction of tubes and channels - strictures

Question 110

Why can’t cartilage repair easily?

Answer 110

Lack of blood supply.

Question 111

Why do some cancers consistently spread to apparently odd sites? Give an example.

Answer 111

Seed and soil explanation. Some cancers need a certain type of host cell.
Eg stomach cancer spreads to the ovary

Question 112

Why do some cancers lie dormant?

Answer 112

They might travel to a secondary site but fail to colonise. They leave dormant micrometastases. When the conditions become favourable the micrometastases can develop properly. This is why cancer can’t be cured.

Question 113

What is the name given to the process of growth of a neoplasm at a secondary site?

Answer 113

Colonisation

Question 114

Why is colonisation an inefficient process?

Answer 114

Cancer cells face immune attack, hostile secondary site - lack of niche cells, slow rate of angiogenesis.

Question 115

Why do some cancers consistently spread to apparently odd sites? Give an example.

Answer 115

Seed and soil explanation. Some cancers need a certain type of host cell.
Eg stomach cancer spreads to the ovary

Question 116

What is the name given to the process of growth of a neoplasm at a secondary site?

Answer 116

Colonisation

Question 117

What tissue types have no (very limited) ability to heal?

Answer 117

Cartilage

Cardiac muscle

Question 118

Which tissue types use outside cells to aid healing? What are the names of these cells?

Answer 118

Central nervous system - glial cells

Skeletal muscle - satellite cells

Question 119

Describe how bone heals.

Answer 119

1. Haematoma
2. Granulation tissue - fibrin, blood vessels, macrophages,..
3. Cytokines activate osteoblasts
4. Soft callus - fibrocartilage
5. Hard callus - woven bone
6. Remodelling

Question 120

Describe how a peripheral nerve heals.

Answer 120

1. Axons degenerate
2. Stumps sprout
3. Old Schwann cells guide the path back to the tissue
4. Growth is slow - 1-3mm per day

Question 121

What is the name of adhesion molecules that bind cells to each other?

Answer 121

Cadherins

Question 122

What is the name of adhesion molecules that bind cells to the extracellular matrix?

Answer 122

Integrins

Question 123

What is contact inhibition?

Answer 123

When a cell is in contact with other cells by cadherins and integrins, it is inhibited from replicating.
When it becomes isolated from other cells, it enters the cell cycle to aid wound healing.

Question 124

What causes sputum to be yellow? What does it indicate?

Answer 124

Neutrophils and eosinophils

Allergic reaction or infection

Question 125

What causes sputum to be green? What does it indicate?

Answer 125

Broken down neutrophils

Chronic infection

Question 126

What causes sputum to be brown/black? What does it indicate?

Answer 126

Old blood
Chronic coughing or tobacco
Possible lung cancer/pneumonia

Question 127

What causes sputum to be red? What does it indicate?

Answer 127

New blood

PE, left heart failure, lung cancer, pneumonia

Question 128

What is sarcoidosis? Which organs are commonly affected?

Answer 128

Diagnosis of exclusion describing chronic granulomatous inflammation.
Commonly affects lung and lymph.

Question 129

How does thrombosis differ from clotting?

Answer 129

Pathological versus physiological response

Thrombus occurs too fast for fibrinolysis to occur effectively

Question 130

What is the most common cause of aneurysm?

Answer 130

Atherosclerosis weakens wall

Question 131

Give three tumour biomarkers and their associated cancer.

Answer 131

Hcg - testicular and Choriocarcinoma
PSA - prostate
CA 125 - ovarian

Question 132

Which type of cancer secretes ADH and ACTH? What can this cause?

Answer 132

Bronchial small cell carcinoma
ADH - water retention
ACTH - cortisol - cushings

Question 133

What type of cancer secretes PTH? What is the effect of this?

Answer 133

Bronchial squamous cell carcinoma

PTH - hypercalcaemia

Question 134

List some functions of the complement system and give some examples of complement.

Answer 134

C3a and c5a
Generally compliments the immune response

1. Opsonisation - identifying pathogens for phagocytosis
2. Amplification of proteases and cytokines
3. Activation of membrane attack complex

Question 135

Which cells are infected by HPV virus? What can infection lead to?

Answer 135

Keratinocytes in basal layer of stratified epithelium
Can cause cervical, vulval cancer
Also genital warts

Question 136

How does a pulmonary embolus kill you?

Answer 136

1. Mechanical shock due to sudden decreased preload of the left heart
2. Right sided heart failure due to severe pulmonary hypertension