Albert Smith

Question 1

How does a ruptured aortic aneurysm present?

Answer 1

• Abdominal and back pain
• Syncope- fainting
• Vomiting
• Haemodynamically compromised- hypotensive, tachycardic, diaphoretic- sweating
• Pulsatile abdominal mass
• Tenderness

Question 2

What are the differential diagnoses of paleness and clamminess of the skin?

Answer 2

• Anxiety attack
• MI
• Heat exhaustion
• Internal bleeding- shock
• Low blood oxygen
• Sepsis
• Anaphylaxis
• Pain
• Hyperhidrosis
• Menopause- hot flushes
• Fever
• Hyperthyroidism

Question 3

4 types of aneurysm

Answer 3

• True- all layers of the vessel are dilated
• Pseudoaneurysm aka false aneurysm- hole in one layer
• Fusiform
• Saccular- common in abdomen, less elastin in abdominal aorta than in thoracic.

Question 4

What is Starling’s law

Answer 4

• Increased venous return increases the ventricular filling (end-diastolic volume) and therefore preload, which is the initial stretching of the cardiac myocytes prior to contraction. Myocyte stretching increases the sarcomere length, which causes an increase in force generation and enables the heart to eject the additional venous return, thereby increasing stroke volume.
• This phenomenon can be described in mechanical terms by the length-tension and force-velocity relationships for cardiac muscle. Increasing preload increases the active tension developed by the muscle fibre and increases the velocity of fibre shortening at a given afterload and inotropic state.
• One mechanism to explain how preload influences contractile force is that increasing the sarcomere length increases troponin C calcium (helps form cross bridges) sensitivity, which increases the rate of cross-bridge attachment and detachment, and the amount of tension developed by the muscle fibre (see Excitation-Contraction Coupling). Other mechanisms are undoubtedly involved. The effect of increased sarcomere length on the contractile proteins is termed length-dependent activation.

Question 5

What is CVP

Answer 5

pressure in thoracic vena cava nearest the right atrium

Question 6

CVP and pressure in the … are pretty much equal

Answer 6

RA

Question 7

BP= …. x ….

Answer 7

TPR X CO

Question 8

What is poiseulle’s law

Answer 8

explains the role of radius on resistance- greater radius= less resistance

Question 9

what is the myogenic response?

Answer 9

intrinsic response is: increased distension of vessel leads to constriction and decreased pressure causes vasodilation.

Protective mechanism- ensures good blood flow even when there is low BP

Question 10

3 things that affect viscosity of blood

Answer 10

blood velocity
vessel diameter
haematocrit

Question 11

What effect does a fall in blood pressure have on HR, ventricular contractility, tone in the resistance vessels and capacitance vessels?

Answer 11

• HR: increase
• ***Ventricular contractility: decreases. There is less ventricular filling.
• Tone in resistance vessels (arteries): vasodilation, leading to reduced TPR myogenic response
• Tone in capacitance vessels (veins): decrease. There is a reduced pressure gradient so there will be less pressure in the veins and the tone will decrease.
• Baroreceptor reflexes- activate sympathetic adrenoceptors to increase HR and contractility and cause vasoconstriction and increasing vascular resistance. The brain benefits from the increased resistance- redistribution from less important organs
• Chemoreceptor reflexes- vasoconstriction causes systemic acidosis, chemoreceptors recognise this and further stimulate the SNS response.
• Circulating vasoconstrictors
• Renal reabsorption of sodium and water- RAAS system
• Activation of thirst mechanisms
• Reabsorption of tissue fluids- reduced capillary hydrostatic pressure

Question 12

How does blood loss lead to shock?

Answer 12

• Hypovolemia
• Leads to decreased BP- less blood to pump
• Tachycardia due to adrenaline release
• Vasoconstriction causes pallor

Question 13

MOA of ACh

Answer 13

o Parasympathetic nervous system
o Bind to muscarinic receptors (M2) on SAN and AVN cells- Gai causing hyperpolarisation by increasing K efflux
o Increases vagal activity to SAN, decreasing firing rate

Question 14

MOA of adrenaline and noradrenaline

Answer 14

o Binds to both alpha- and beta-adrenergic receptors
 alpha 1: vasoconstriction via Gaq
 alpha 2: vasoconstriction via Gai
 beta: increase HR, impulse conduction, increase contraction and vasodilation via Gas

Question 15

example of mAch antagonist

Answer 15

atropine

Question 16

example of indirect AchR agonist

Answer 16

neostigmine

Question 17

example of a1 adrenergic receptor agonist

Answer 17

phenylephrine

Question 18

difference between adrenaline and noradrenaline

Answer 18

• Noradrenaline is the main neurotransmitter of the sympathetic nerves in the cardiovascular system- secreted by the nerves.
• Adrenaline is the main hormone secreted by the adrenal medulla.
• Noradrenaline has more specific effects- only works on a receptors
• Adrenaline has more widespread effects both a and b receptors

Question 19

How to stabilise a patient with a suspected AAA

Answer 19

• Immediate high flow oxygen
• IV access- 2x large bore cannula
• Urgent bloods- FBC, U&Es, clotting
• Cross matching for minimum 6 units
• Treat the shock carefully- don’t want to dislodge a clot that is tamponading the rupture- aim to keep systolic BP <100mmHg- known as permissive hypotension to prevent excess blood loss.
• Inform vascular registrar, consultant and anaesthetist
• If patient is stable- CT angiogram
• In unstable- open surgical repair

Question 20

What is a fluid challenge, including the amounts given and time frames

Answer 20

• A diagnostic intervention used to decide if a patient with haemodynamic compromise will benefit from further fluid replacement.
• A small amount of fluid is administered in a short period of time. Assess whether the patient has the preload reserve that can be used to increase SV with more fluid.
• A positive response to a fluid challenge would be an increase in SV of >10%.
• A negative response would be an increase in PAOP with an increase of SV of <10%.
• Bolus of 500ml over less than 15 minutes (NICE guidelines) use colloid fluids

Question 21

What are “packed RBCs”?

Answer 21

• Made by removing the plasma from blood.
• Contain WBCs, platelets and residual plasma.
• Indicated for anaemia and can be used to treat haemorrhagic stroke when administered with volume expanders.
• Used to improved oxygen carrying capacity and blood volume

Question 22

What does cryoprecipitate contain?

Answer 22

• Precipitate of thawed FFP FFP is repeatedly frozen and thawed to produce a liquid rich in clotting factors.
• High in FVIII and fibrinogen
• Precipitate of thawed FFP FFP is repeatedly frozen and thawed to produce a liquid rich in clotting factors.
• High in FVIII and fibrinogen

Question 23

Where is a central line inserted

Answer 23

• Internal jugular vein is preferred but can use the subclavian vein less likely to cause a pneumothorax.

Question 24

Reasons for a central line

Answer 24

o Administration of medications that require central access e.g. amiodarone, inotropes
o Fluid balance monitoring with CVP
o IV access for long term e.g. chemo

Question 25

Complications of central line

Answer 25

o	Infection
o	Haemothorax
o	Pneumothorax
o	Haematoma
o	Arterial puncture 
o	Air embolism
o	Arrhythmias 
o	Thrombosis

Question 26

3 examples of sympathetic agonists

Answer 26

salbutamol
dobutamine
epinephrine

Question 27

5 effects of sympathetic agonists

Answer 27

increased HR, contractility
bronchodilation 
sphincter contraction
increased glycogenolysis 
venoconstriction 
peripheral vasdilation

Question 28

4 types of sympathetic antagonist

Answer 28

a blockers

b blockers

a2 adrenergic agonists

monoamine-depleting agents

Question 29

2 effects of a blockers

Answer 29

o Decrease vasoconstriction via a1r and increase vasodilation via b2r- Decrease BP
o Increased renin secretion via b1r - Increase water retention

Question 30

effect of b blockers

Answer 30

mainly inhibit b1r in heart- decrease HR, contractility and AV conduction

Question 31

effect of a2 adrenergic agonists

Answer 31

o Activate a2r in presynaptic sympathetic neurons in CNS increasing negative fb. This leads to less catecholamine release- dopamine and norepinephrine. Reduced sympathetic tone, reduced vasoconstriction and lower BP

Question 32

effect of monoamine- depleting agents

Answer 32

o Inhibit uptake of norepinephrine and dopamine into presynaptic vesicles of adrenergic neurons.
o This reduces catecholamine release, decreasing CO and BP
o Less vasoconstriction leads to lower BP

Question 33

2 groups of parasympathetic agonist

Answer 33

muscarinic receptor agonist

cholinesterase inhibitors

Question 34

effect of muscarinic receptor agonist

Answer 34

o a decrease in heart rate and in atrial contraction
o indirect vasodilatation due to stimulation of NO from vascular endothelial cells
o contraction of smooth muscle of the gastrointestinal tract along with relaxation of the sphincters
o stimulation of exocrine glands leading to gastric acid secretion, salivation, lacrimation and sweating
o contraction of the detrusor muscle and relaxation of the bladder sphincters, leading to urination
o constriction of the pupil and the ciliary muscle of the eye, leading to miosis and decreased intraocular pressure

Question 35

example of parasympathetic antagonist

Answer 35

muscarinic receptor antagonist

Question 36

4 effects of muscarinic receptor antagonist

Answer 36

o to cause pupil dilation to facilitate eye examinations (e.g. atropine; tropicamide)
o to cause relaxation of bronchial smooth muscle in COPD (e.g. ipratropium)
o to decrease gastric motility (e.g. hyoscine)
o to decrease bladder emptying (e.g. oxybutynin)