Cardiac output monitoring provides important information about a patient's hemodynamic status. There are several invasive and non-invasive methods to measure cardiac output. Invasive methods include thermodilution, Fick method, lithium dilution. Thermodilution, using a pulmonary artery catheter, is considered the clinical gold standard but has fallen out of favor due to risks. Non-invasive options include esophageal Doppler, bioreactance, pulse contour analysis, and partial CO2 rebreathing. Choice of monitoring method depends on the patient's condition and goals of therapy.
2. DEFINITIONS
1. Shock Failure to deliver adequate oxygen to the tissues.
2. Cardiac Output Volume of blood ejected from the left ventricle per minute (the product of
stroke volume and heart rate). Influenced by preload, contractility and afterload.
3. Cardiac index is cardiac output adjusted for body size.
4. Stroke Volume Volume of blood ejected from the ventricle in a single contraction. Usually
60-80 ml for an adult.
5. Preload End-diastolic ventricular wall tension (i.e. tension at the point of maximal filling) â
mainly determined by venous return, and an indicator of filling pressures.
6. Venous Return The blood entering the right atrium per minute.
7. Afterload Tension developed in the ventricular wall during systole (i.e. the tension
generated in order to eject blood during systole) â largely determined by the SVR.
3. 1. Systemic Vascular Resistance All the forces that oppose blood flow through the syst
emic vasculature. Predominantly determined by vasoconstriction in the arteriolar bed.
2. Contractility The amount of mechanical work that the heart can do at a given preload
and afterload (an intrinsic ability of the heart).
3. Mean Arterial Pressure (MAP) Average arterial blood pressure throughout the cardiac
cycle. As 2/3 of the cardiac cycle is spent in diastole, and 1/3 in systole, MAP may be
calculated using the formula: MAP = (Systolic BP + 2 x Diastolic BP) / 3 Or MAP = Diast
olic BP + 1/3(Systolic BP - Diastolic BP)
4. Ejection Fraction The fraction of total blood in a ventricle that is ejected per beat.
Applies to both left and right ventricles. An index of contractility. Normal value in region
of 55-65%.
4. CLINICAL INDICATORS OF CARDIAC
OUTPUT
Clinical signs include:
1. Skin colour
2. Skin temperature, and core-peripheral temperature
difference
3. Capillary Refill Time
4. Heart Rate
5. Urine Output
6. Mental State
5. Cardiac output is the volume of blood pumped by the heart per minute and is the
product of the heart rate and stroke volume
⢠It is the determinant of global oxygen transport to the body
⢠It reflects the efficiency of cardiovascular system
⢠There no absolute value for cardiac output measurement
Cardiacoutput
6. CardiacOutput Measurement
AIM : Hemodynamic monitoring and support in the critically ill
so as to optimize oxygen delivery to the tissues.
⢠Oxygen delivery is determined by Cardiac Output and
amount of oxygen carried in the blood.
⢠Allows us to assess the blood flow to the tissues, and
provides information on how to best support a failing
circulation.
7. Why shouldwe measure?
1.The recognition that in many critically ill patients, low cardiac
output leads to significant morbidity and mortality.
2.The clinical assessment of cardiac output is unreliable/
inaccurate.
8. When shouldwe monitor?
⢠High risk critically ill surgical patients in whom large fluid shifts
are expected along with bleeding and hemodynamic instability.
⢠An important component of goal directed therapy (GDT), i.e.,
when a monitor is used in conjunction with administration of fluids
and vasopressors to achieve set therapeutic endpoints thereby
improving patient care and outcome.
9. Featuresof anideal CardiacOutput
monitor
1. Safe and accurate
2. Quick and easy to use both in terms of
set-up and interpretation of information
3. Operator independent i.e. the skill of the operator
doesnât affect the information collected
4. Provide continuous measurement
5. Reliable during various physiological states
11. Methods of measuringcardiac output
Simple method:
⢠CO (L/min) = HR(beats /min) x SV(L/beat.)
⢠SV: Volume ejected during each beat , depends on
venous return, can be equal to venous return.
⢠CO (at rest) = 5-6 L/min.
⢠HR=72 beats/min , SV=0.07L/min (70ml) .
⢠CO increases when metabolic need (eg. Exercise), Therefore
, HR or SV or both can increase.
13. PULMONARY ARTERY
CATHETERIZATION
1970 â SWAN, GANZ & colleagues introduced PAC for
patients with acute MI.
Standard PAC â 7.0 to 9.0 Fr circumference.
- 110cm in length.
- marked 10cm intervals.
- four internal lumina.
ď1st port â distal port â PA pressure monitoring.
ď2nd port â 30cm proximal â CVP monitoring.
ď3rd port â balloon near the tip.
ď4th port â proximal to balloon â thermistor.
15. PA CATHETERIZATION : waveforms
Right atrial pressure
Rt. Ventricular pressure
PA pressure
PA wedge pressure
Resembles CVP waveforms,
Displays a, c & v waves.
Shows higher systolic pressure
than RA, end-diastolic pressures
are equal in these 2 chambers
Shows distolic step-up compar
ed with ventricular pressure
Shows similar morphology to
right atrial pressure but a,c ,v
waves appears late in cardiac
cycle. 15
18. FICK METHOD:
This method is based on the principle described by ADOLFO FICK in
1870.
PRINCIPLE - the total uptake (or) release of a substance by
an organ is the product of the blood flow through the organ and
the arteriovenous concentration difference of the substance .
19.
20. FICK METHOD: âgold standardâ
ďśThe oxygen uptake in the lungs is the product of the blood flow through the
lungs and the arteriovenous oxygen content difference.
CO = VO2 / O2 art â O2 ven
Arterial O2 = Hb x 1.34 x O2 sat.
Venous O2 = Mixed venous blood
VO2 = Oxygen consumption
21. FICK METHOD:
LIMITATIONS :
Fick cardiac outputs are infrequently used because difficulties
in collecting and analyzing exhaled gas conc.
In critically ill patients with lung abnormalities.
22. ďśVariant of the indicator dilution method
ďśTHREE types :
ďINTERMITTENT thermodilution CO monitoring.
ďCONTINUOUS thermodilution CO monitoring.
ďTRANSPULMONARY thermodilution CO monit.
23. INTERMITTENT thermodilution CO monitoring :
PROCEDURE - A known volume of iced (or) room temp. fluid is injected as
a bolus into the proximal (RIGHT ATRIUM) lumen of PAC & the resulting
change in the pulmonary artery blood temp. is recorded by the thermistor
at the catheter tip.
Real time display of the thermodilution curve from each CO monitoring
is important.
Artifacts â unstable blood temp. , recirculation, incomplete indicator
injection â eliminated.
25. INTERMITTENT thermodilution CO monitoring:
ďRoom temp. injectate is preferred over ice-cold fluid.
ďAdults â 10ml injectate is used.
ďChildren â 0.15 ml/kg is recommended.
26. INTERMITTENT thermodilution CO monitoring:
RESULT :
ďThree CO measuremnets perfomed in rapid succession are averaged â
provide reliable result.
ďSingle injection â a diff. b/w sequential CO measurement of 22% was
required to suggest a clinically significant change.
ďThree injections â averaged to determine the measurement , a change
greater than 13% indicates a clinically significant change in CO.
29. CO= V1( Tb- T1) K1 K2
Ξ ÎTb (t) dt
Where,
1. V1=injectate volume in ml
2. Tb = temperature of pulmonary artery blood
3. T1= injectate temperature °C
4. K1 = density factor
5. K2 = computation constant taking in account the catheter dead-space and heat
exchange in transit ; both computation constant
6. Denominator : change in temp and change in time : corresponds to the area
under thermodilution curve
31. Factors inflencing â accuracy of thermodilution CO-
ďINTRACARDIAC âSHUNTS.
ďTRICUSPID (OR) PULMONARY REGURGITATION.
ďINADEQUATE DELIVERY OF THERMAL INDICATOR
- warming of iced injectate.
ďTHERMISTOR MALFUNCTION FROM FIBRIN (OR) CLOT.
ďPULM. ARTERY BLOOD TEMP. FLUCTUATION.
- following cardio-pulmonary bypass.
- rapid IV fluid administration.
ďRESPIRATORY CYCLE INFLUENCES.
32. CONTINUOUS THERMODILUTION
CARDIAC OUTPUT MONITORING
CONTINUOUS thermodilution CO monitoring:
ď§Continuous CO monitoring done using a warm thermal indicator on PAC.
ďśProcedure âSmall quantities of heat are released from a 10-cm
thermal filament incorporated into the right ventricular portion of a PAC,
app. 15 â 25 cm from the catheter tip & the resulting thermal signal is
measured by the thermistor at the tip catheter in pulmonary artery.
ď§The heating filament is cycled on & off in a pseudorandom biniary
sequence.
34. ďThe displayed value for CO is updated every 30 to 60 sec & represents
the avg. value of CO measured over the previous 3 to 6 mins.
ďSiegel & associates showed that CCO markedly slower than changes
detected by ULTRASONIC, BLOOD PRESSURE, MIXED VENOUS O2
SATURATION.
35. CONTINUOUS V/S INTERMITTENT :
Continuous advantageous over intermittent
ďReproducibility & precision are better.
ďObviating the need for bolus injection.
ďReduces the nursing workload.
ďRisk of fluid overload (or) infection.
ďAverage derived over previous several min. beat
-beat variation in SV that occur over a single
respiratory cycle are equally represented.
36. TRANSPULMONARY THERMODILUTION
CARDIAC OUTPUT MONITORING
Procedure - ice-cold saline is injected into the central
venous line while the change in temp. is measured in a large
peripheral artery( femoral, axillary, brachial) via. special
catheter equipped with a thermistor.
ď Measurements lasts over several cardiac cycles Resp.
effects on stroke volume are averaged & eliminated.
37.
38. TRANSPULMONARY thermodilution CO monitoring:
OTHER INDICES MEASURED :
ďExtravascular lung water (pulmonary odema)
ďGlobal end-diastolic volume
ďIntra thoracic blood volume
ďCardiac function index.
39. Lithium DILUTION CARDIAC output
monitoring
ďBased on INDICATOR DILUTION PRINCIPLE.
Procedure :Following an intravenous bolus injection of a small
dose of lithium chloride, an ion-selective electrode attached to a
peripheral catheter measures the lithium dilution curve.
ďFrom which CO derived.
ďLithium can be injected - Peripheral (or) central.
ď cannot be used â pts. Taking LITHIUM and
NEUROMUSCULAR BLOCKERS.
40. ESOPHAGEAL DOPPLER
CARDIAC output monitoring
ďThe doppler probe is inserted into the esophagus to a depth
of approx. 35cm from the incissor teeth & is adjusted to
optimize the audible doppler flow sound from the descending
aorta.
ďOptimal probe tip POSITION â T5-T6 vertebral interspace or
the 3rd sternocostal jn. Bâcoz esophagus & descending aorta lie
in close approximity & run parallel.
ďTransducer â fixed at an angle.
41. ESOPHAGEAL DOPPLER cardiac output monitoring:
ďMeasures only a fraction of total CO, so correction constant
of 1.4 is used.
ďCorrection constant is almost universal.
ďConstant â not used pregnancy, aortic cross clamping,
cardio-pulmonary bypass.
46. ESOPHAGEAL DOPPLER cardiac
output monitoring:
ďSeveral studies shown that â volume resuscitation guided by
maximizing esophageal doppler measured SV in moderate risk
surgical pts. Reduces perioperative morbidity & shortens
hospital stay.
ďBâcoz most imp. Benefit â mainly focussing on optimizing on
stroke volume rather than total CO.
47. ADVANTAGES :
⢠Ease of use
⢠Minimal invasiveness
⢠Inherent safety.
Additional Hemodynamic
indices can be measured :
ď§ Peak blood flow velocity
ď§ Flow acceleration
DISADAVANTAGES :
Inaccurate :
⢠Aortic valve stenosis
⢠Aortic regurgitation
⢠Thoracic aortic disease
Not easily applied :
ď§ Esophageal pathology
ď§ Non intubated47
48. BIOIMPEDANCE CARDIAC output
monitoring
:
ďFirst described â kubicek & associates.
ďBased on â changes in electrical impedance of the thoracic
cavity occuring with ejection of blood during cardiac systole.
49. Procedure : disposable electrodes are applied along the sides of the
neck & lateral aspect of lower thorax & a continuous small electrical
current is applied along the chest.
ďBioimpedance CO is computed for each cardiac cycle & continuously
displayed as an average value over several heart beats.
ďPt. height, weight & gender are used to calculate the volume of
thoracic cavity.
ďIts reliability deteriorates in â crtically ill pts. With sepsis, pulmonary
edema, AR, cardiac pacing.
50. Partial CO2 rebreathing CARDIAC
output monitoring
This technique is based on a restatement of the fick equation
for CO2 elimination rather than O2 uptake
CO = VCO2 / Cvco2 Caco2
Vco2 â rate of carbon dioxide elimination
Cvco2 â CO2 content of mixed venous blood
Caco2 â CO2 content of arterial blood.
51. ďThis method uses the change in CO2 production & end-tidal
CO2 conc. In response to a brief, sudden change in minute
ventillation.
ď performed in tracheally intubated patient.
ďTechnique â every 3 min a computer controlled pneumatic
valve intermittently increases deadspace for 50-sec period
there by causing partial rebreathing of the exhaled gases.
52. LIMITATIONS :
ďTracheal intubation required.
ďPrecise measurement of exhaled gases to be done.
ďContraindicated in ICP increased patients.
ďChanging patterns of ventillation may have unpredictable influ
ence on meausrement.
ďMeasures pulmonary capillary blood flow as an indicator of to
tal CO & thus requires correction for pulmonary shunt.
53. Pulse contour CARDIAC output
monitoring
Procedure : Continuous measurement of CO is derived from the
analysis of the area under the ARTERIAL PRESSURE WAVEFORM
recorded from an arterial catheter (or) NON-INVASIVE finger blood
pressure waveform.
ďOffers noninvasive, continuous, beat to beat CO monitoring.
ďChange in the strokevolume from beat to beat can be used â to
evaluate vol. status in ventillated pts.
54. LIMITATIONS :
ďA base line known CO is required to account for individual
diff. In vascular resistance, impedence & wave reflectance.
ďRecalibration â every 8 to 12hrs â changes in vascular
characteristic.
ďArterial pressure waveform with discernible dicrotic notch
required â not exist in severe tachycardia ,dysrhythmia (or) low
-output states.
ďMechanically ventilated â beat to beat SV.
55. Gastric tonometry
ďAIM â monitoring gastric circulation as an early
indication of splanchnic hypoperfusion.
ďProcedure : a balloon-tipped tube is inserted into the stomach &
the saline (or) air in the balloon is allowed to equilibrate with the CO2
gastric lumen.
ďIntermittently the air (or) saline is aspirated & CO2 measured.
56. Gastric hypoperfussion â CO2 clearence from gastric mucosa
decreases, where as the CO2 production increases from
Bicorbonate titration of acid released from anaerobic metabolism.
The CO2 from the mucosa diffuses freely to the gastric lumen &
is detected by the tonometry device.
Usefull in critically ill (or) perioperative patients