Describe the different types of shock
Hypovolaemic
Cardiogenic
Distributive
Obstructive
Cytotoxic
Mitchondrial toxicity e.g. sepsis, cyanide
Describe the cardiovascular response to surgery
SNS activated by peripheral nerves
Increase pituitary hormones - ADH
Increase ACTH and cortisol
Cytokine release IL6, IL1 TNF alpha
Describe the cardiovascular repsonse to shock
Autonomic effects
Arterial hypotension causes baroreflex activation.
Decreased cardiac output causes chemoreceptor activation.
Both reflexes result in autonomic phenomena:
Decreased vagal stimulus; thus increased heart rate
Sympathetic activation, which has multiple effects:
Increased peripheral vascular resistance
Redistribution of blood flow away from the cutaneous and splanchnic circulation
Stimulation of systemic catecholamine release from adrenal glands, which produces an increased systemic effect in addition to the peripheral sympathetic nervous system effects
Stimulation of vasopressin release via the projections from the nucleus of the solitary tract to the hypothalamus
Stimulation of renin release by sympathetic stimulation of the juxtaglomerular cells, and due to lower renal perfusion
Neurohormonal effects
Renin secretion causes:
Vasoconstriction (by angiotensin)
Increased sodium retention (by aldosterone)
Vasopressin release causes:
Vasoconstriction (by V1 receptors)
Increased water retention (by V2 receptors)
Venous hypotension decreases atrial natriuretic peptide secretion, which causes:
Decreased renal blood flow
Decreased urinary water and sodium excretion
The net effect is decreased urine output and increased retention of sodium and water
Name different method of cardiac output monitoring
Fick’s
Indicator dilution
Pulse contour analysis
Doppler Velocity Measurement
Flow rotometer
Explain Fick’s principle and the limitations of this method
CO = VO2/Ca-Cv
The total uptake of oxygen is equal to the product of the cardiac output and the arterial-venous oxygen content difference.
Direct measurements of these things can be difficult.
Indirect measurements introduce inaccuracies
e.g.:
VO2 estimate from nomograms
Use CVC O2 or venous estimates
Estimate Ca from SpO2
VO2 measurement takes time - CO may change during this
Can substitute CO2 for this too!
Estimation of CaCO2 on the basis of end-tidal CO2
Estimation of CvCO2 on the basis of EtCO2 during rebreathing
Explain indicator dilution method of CO estimate and its limitations
Inject indicator or change property of blood and measure its concentration distally (or the effect of change of property)
CO = indicator dose/area under [ ] time curve
Prone to error!
delivery technique (flow, volume, temp, timing with resp) changes results
sampling rate must be high
corrections needed for thermodilution
Limitations
Indicator limits repeat observations (recycling)
Relies on uniform mixing and unidirectional flow
Explain pulse contour analysis
Arterial waveform converted into volume measurement using a calibration factor based either on
estimate from nomogram
derived from indicator measurement
These are a signifcant source of error. Calibration is dependent on properties of the vascular system.
If this changes recalibration is needed e.g. vasoconstriction
Explain doppler velocity measurement
CO = HR x CSA aorta x VTI (velocity time integral)
Measure velocity over time in 5 chamber view and integrate. Need serial measurements to account for resp cycle variation. Further serial measurments for AF.
Beam angle needs to be right.
Gives a fair estimate in experienced hands.
Explain the determinants of pulse pressure
PP = SBP - DBP, usually 40mmHg
PP = SV / Compliance
Systolic
Arterial compliance ***
Stroke volume
Peripheral resistance
Diastolic
Peripheral resistance (increases DBP) ***
Arterial compliance
Time constant of vessels (and therefore HR)
Note that increased resistance generally reduces compliance as constricted vessels don’t expand as well.
Describe different scenarios leading to pulse pressure changes
Respiratory pulse pressure variation:
As intrathoracic pressure changes, so do preload and afterload, and this gives rise to a variation in stroke volume, which is in turn a major determinant of systolic pressure.
Pulse pressure variation in shock:
In hypovolemia the pressure gradient for venous return becomes more sensitive to changes in intrathoracic pressure.
In cardiac tamponade, changes in preload exaggerate the normal inspiratory drop in blood pressure through interventricular interdependence.
Pulse pressure variation with stress and exercise:
Increased sympathetic activity increases the stroke volume and therrefore the systolic blood pressure
Pulse pressure variation due to arterial compliance:
As arterial compliance decreases, systolic pressure increases and diastolic pressure drops because of the steeper pressure-volume curve
Pulse pressure variation due to heart rate
With a slower heart rate, the diastolic pressure decline occurs over a longer time period, and is therefore deeper, and the diastolic filling is longer, resulting in a higher stroke volume and higher systolic pressure
Pulse pressure difference according to the site of measurement:
Distal pulse pressure amplification due to constructive interference of reflected waves increases the systolic and decreases the diastolic pressure in distal arteries
Pulse pressure variation with pathological states:
Describe pathological states associated with pulse pressure changes
NARROW PP
Shock - more susceptible to standard changes in preload associated with respiration
Tamponade - intrathoracic pressure changes lead to interventricular dependence
Any decrease in SV
Aortic stenosis
Heart failure
High afterload
Increased compliance - AV fistula
WIDE PP
Increase in stroke volume
hyperdynamic, early sepsis
thyrotoxicosis
anaphylaxis
Decreased compliance
age
atherosclerosis
aortic aneurysm (no Windkessel)
Structural
Aortic regurg
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