1. Predicting Fluid Responsiveness in ICU patients: �A Critical Analysis of the Evidence Frederic Michard, MD, PhD; and Jean-Louis Teboul, MD, PhD
CHEST 2002; 121:20002008
critical care review
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2. Volume expansion - critically ill patients to improve hemodynamics.
Positive relationship : ventricular enddiastolic volume and stroke volume
Depends on ventricular function
Expected hemodynamic response to volume expansion increase
Right ventricular end-diastolic volume (RVEDV)
Left ventricular end-diastolic volume
Stroke volume
Cardiac output.
Depends on fluid into the different cardiovascular compliances organized
40 to 72% of critically ill patients - respond to volume expansion by increase stroke volume or cardiac output
3. Predictive factors :
Benefit from volume expansion
Avoid ineffective or deleterious volume expansion
Worsening in gas exchange, hemodilution
Inotropic and/or vasopressor support should preferentially
Guide fluid therapy in Germany
Right atrial pressure (RAP)
Pulmonary artery occlusion pressure (PAOP)
Cardiac filling pressures
Indicators of ventricular preload - predictors of fluid responsiveness
RVEDV
Left ventricular end-diastolic area (LVEDA)
Respiratory - pleural pressure - RAP, arterial pressure, and aortic blood velocity - preload
Analyze - predictive factors of fluid responsiveness in critically ill patients
4. Materials and Methods Selection of Studies To Be Evaluated
Search in MEDLINE (from 1966).
Studies
Predictive factors of fluid responsiveness in critically ill patients
Volume expansion performed in critically ill patients
12 included studies (Table 1)
Volume expansion on stroke volume or on cardiac output
Patients characteristics before volume expansion
Classified in two groups
Responders
Nonresponders
5. Parameters Tested as Predictors of Fluid Responsiveness
Ventricular preload indicators in predicting fluid responsiveness (Table 1)
RAP in 5 studies
PAOP in 9 studies
RAP and PAOP : measured at end-expiration without ventilator disconnection or removal PEEP
RVEDV in 6 studies
RVEDV = (cardiac output/heart rate)/ right ventricular ejection fraction 4 studies
Fast-response thermistor pulmonary artery Catheter
RVEDV - evaluated by cardiac scintigraphy 2 studies
LVEDA in 3 studies
Transesophageal echocardiography
6. The value of dynamic parameters in predicting fluid responsiveness - 5 studies (Table 1)
Inspiratory decrease in RAP (?RAP) - 2 studies
?RAP - the difference between the expiratory and the inspiratory RAP
Expiratory decrease in arterial systolic pressure (?down) - 1 study
?down - the difference between the value of the systolic pressure during an end-expiratory pause and the minimal value of systolic pressure over a single respiratory cycle
Respiratory changes in arterial pulse pressure (?PP) - 1 study
?PP - the difference between the maximal and the minimal value of pulse pressure over a single respiratory cycle
Respiratory changes in aortic blood velocity(?Vpeak) - 1 study
?Vpeak - the difference between the maximal and minimal peak velocity of aortic blood flow over a single respiratory cycle
Aortic blood flow - measured by a pulsed-wave Doppler echocardiographic beam at the level of the aortic valve.
7. Results 334 patients - 406 fluid challenges (Table 1).
Septic (55%)
Receiving mechanical ventilation (84%)
The decision of volume expansion - based on criteria listed Table 2.
Fluid administration
Colloid solutions (albumin, fresh frozen plasma, or hydroxyethylstarch) - 253 instances
Crystalloid solutions (serum saline solution or Ringers lactate) - 153 instances
250 to 500 mL colloids and 300 to 500 mL crystalloids - 9 studies
Volume infusion performed until a rise in RAP = 2 mmHg 2 studies
The volume of serum saline solution infused varied from 100 to 950 mL
Fluid administered until a rise in PAOP = 3 mm Hg 1 study
938 480 mL for serum saline solution
574 187 mL for 5% albumin or fresh frozen plasma.
Hemodynamic response
Increase in stroke volume - 5 studies
Cardiac output - 7 studies
8. RAP Not significantly lower in 3/5 studies
Lower RAP baseline in responders, significant (r2 = 0.20) 2/5 studies (Wagner and Leatherman)
9. PAOP 6/9 studies - not significantly lower
3/9 studies - significant difference
1/3 study, mean value significantly higher in responder patients (14 7 mmHg vs 7 2 mmHg, p < 0.01)
2/3 studies, significantly lower (r2 = 0.33) in responders (Wagner and Leatherman)
10. RVEDV Not significantly lower in 4/6 studies
Lower RVEDV at baseline of responders in 2/6 studies (Diebel et al)
RVEDV index < 90 mL/m2 - high rate of response (100% and 64%)
RVEDV index > 138 mL/m2 - lack of response to volume expansion
One of not significantly lower study (Wagner and Leatherman )
Positive response in 4/9 patients with a RVEDV index > 138 mL/m2
Lack of response in 3/9 patients despite a RVEDV < 90 mL/m2
Significant but weak relationship between the baseline RVEDV index (r2 = 0.19)
12. LVEDA Significantly lower in 2 studies
Tavernier et al - significant and negative relationship (r2 = 0.4, p = 0.01)
Tousignant et al. - marked overlap of baseline - could not be used to predict the response
Another study (Feissel et al )
Not different (10 4 cm2/m2 vs 10 2 cm2/m2)
No significant relationship (r2 = 0.11, p = 0.17)
13. ?RAP Spontaneous breathing activity, 2 studies (Magder et al)
Inspiratory decrease in RAP = 1 mm Hg
Predicted positive response to volume expansion
Positive predictive values of 77% and 84%
Negative predictive values of 81% and 93%
14. ?down Sedated patients receiving mechanical ventilation with sepsis-induced hypotension 1 study
?down was significantly greater (11 4 mm Hg vs 4 2 mm Hg, p = 0.0001) in responders
?down threshold value - 5 mm Hg
Positive predictive value of 95%
Negative predictive value of 93%
Positive and good relationship (r2 = 0.58, p = 0.001)
15. ?PP Sedated patients receiving mechanical ventilation with acute circulatory failure related to sepsis 1 study
?PP was significantly greater (24 9% vs 7 3%, p = 0.001) in responders
?PP threshold value - 13%
Positive predictive value of 94%
Negative predictive value of 96%
Significantly and closely correlated (r2 = 0.85, p = 0.001) with the volume expansion-induced changes in cardiac output
16. ?Vpeak Sedated patients receiving mechanical ventilation with septic shock 1 study
?Vpeak was significantly greater (20 6% vs 10 3%, p = 0.01) in responder
?Vpeak threshold value - 12%
Positive predictive value of 91%
Negative predictive value of 100%
Positive and tight linear correlation (r2 = 0.83, p = 0.001) between the ?Vpeak before volume expansion and the volume expansion induced changes in cardiac output.
17. Discussion Volume expansion cannot be expected of beneficial hemodynamic effect
RAP > 12 mm Hg
PAOP > 12 mm Hg or > 15 mm Hg.
RAP and PAOP - lower in responders patients in 2 studies by Wagner and Leatherman (Fig 1, Table 3).
The lower RAP or PAOP before volume expansion, the greater the increase in response to fluid infusion.
These relationships were weak
No difference in all other clinical studies (Fig 1, Table 3)
No relationship reported between cardiac filling pressures and hemodynamic response
Fluid infusion shown significantly increase cardiac output with CVP > 15 mm Hg.
18. Lower RVEDV index suggested a beneficial hemodynamic effect of volume expansion in 2 studies (Diebel et al )
RVEDV index < 90 mL/m2 - high rate of response (100% and 64%)
RVEDV index > 138 mL/m2 - lack of response to volume expansion (rate of response of 0%)
RVEDV index ranged from 90 to 138 mL/m2 - no cutoff value
Wagner and Leatherman reported
Positive response with a RVEDV index > 138 mL/m2
Lack of response despite a RVEDV < 90 mL/m2
4/6 studies - RVEDV could not predict fluid responsiveness (Fig 2).
19. The echocardiographic measurement of LVEDA
Left ventricular preload
Detect changes in left ventricular function caused by acute blood loss
In 9 anesthetized mongrel dogs, Swenson et al reported
Significant relationship between baseline LVEDA and changes in cardiac output induced by IV fluid therapy
LVEDA could be an indicator of fluid responsiveness.
Significantly lower LVEDA in responders in 2 studies
A significant relationship between the baseline LVEDA index and the changes in stroke volume induced by volume expansion has also been reported.
20. Tavernier et al
Patients with sepsis-induced hypotension
Receiver operating characteristic curve analysis
Minimal value of LVEDA index value to discriminate responders and nonresponders before fluid was administered.
Tousignant et al
Including medical-surgical ICU patients
Considerable overlap of baseline individual values of LVEDA
Cannot reliably predict fluid responsiveness in an individual patient.
Feissel et al
Septic shock patients
No any difference of the mean baseline value of LVEDA index
No any relationship between the baseline value of LVEDA index and the percentage of change in cardiac index in response to volume expansion.
Lack of value of ventricular preload indicators as predictors of fluid responsiveness
21. First, RAP, PAOP, RVEDV, and LVEDA are not always accurate indicators of ventricular preload.
RAP and PAOP - overestimate transmural pressures with external or intrinsic PEEP.
PAOP : highly dependent on left ventricular compliance (sepsis, ischemic, hypertrophic cardiopathy).
RAP and PAOP - related to end-diastolic volumes via the chamber compliance
Pulmonary hypertension (ARDS, mechanical ventilation with PEEP) - tricuspid regurgitation
The LVEDA by echocardiography - not accurately reflect left ventricular enddiastolic volume and LV preload.
Second - right ventricular dysfunction
Beneficial hemodynamic effect of volume expansion cannot be expected
even in the case of low left ventricular preload
22. Third, diastolic chamber compliance
Hypovolemia associated with a normal or high LVEDA value with dilated cardiopathy.
Finally, two matters must be stressed:
(1) The partitioning of the fluid into the different cardiovascular compliances organized
(2) Ventricular function - decrease in ventricular contractility decreases the relationship between end-diastolic volume and stroke volume.
Nonresponder to a fluid challenge
High venous compliance
Low ventricular compliance
Ventricular dysfunction
23. Respiratory changes in pleural pressure - decrease in RAP when inspiratory (Magder et al)
Inspiratory decrease in RAP = 1 mm Hg - Predicted positive response to volume expansion
Unable to produce an inspiratory decrease in ICU
Sedated patients receiving mechanical ventilation
Sedated patients receiving mechanical ventilation with acute circulatory failure related to sepsis
Respiratory changes in left ventricular stroke volume - predict fluid responsiveness
Arterial pulse pressure (systolic minus diastolic pressure)
Proportional to left ventricular stroke volume
Respiratory changes in systolic pressure
Less specific indicator of changes in left ventricular stroke volume
24. Septic patients with hypotension -?down predictor (Tavernier et al)
Cardiac arrhythmias, shock states - ?down and ?PP requires invasive arterial pressure catheterization (A-line).
Doppler echocardiographic imaging of aortic blood velocity - noninvasively (Feissel et al)
Predictors of fluid responsiveness in sedated patients receiving mechanical ventilation with sepsis
?down
?PP
?Vpeak
In the studies analyzed (Table 1)
Various types and volumes of fluid
Speeds of fluid infusion
Definitions of responders to volume expansion
25. The hemodynamic effects
Hypertonic colloid infusion are expected to more dramatic than isotonic crystalloid infusion
Intravascular- extravascular equilibration
Speed of volume infusion
Systemic capillary leakness
Different definitions of responders from study
Individual data were not available
Predictive value of dynamic parameters tested only few studies.
Further studies are required to confirm the high value of dynamic parameters
Our analysis emphasizes the minimal value of static ventricular preload parameters
Strongly supports the use of the dynamic parameters in the decision-making process concerning volume expansion in critically ill patients.
26. Thanks For Your Attentions
