Ischemic Heart Disease Clinical Trial
Official title:
Can Changes in LVOT VTI Before and After Passive Leg Raising (PLR) Test Serve as a Sensitive Indicator for Changes in SV and CO and Hence Volume Responsiveness ?
Hypothesis: A validated technique to measure cardiac output (CO) using echocardiography is
to calculate stroke volume from the product of LVOT area and LVOT VTI and multiplying the
product with heart rate ( CO = SV x H/R; SV = LVOT area x LVOT VTI ).
The LVOT diameter for an individual is more or less a constant measurement. Therefore using
the formula mentioned above (SV = LVOT area x LVOT VTI), if the LVOT area is constant, then
SV should be proportional to the VTI. This means if a PLR manoeuvre or fluid bolus helps to
achieve a rise in SV, then it should be reflected in an increase in VTI as well. If this
assumption is true, then an increase in the value of VTI from baseline after fluid challenge
(10-15%), should identify a volume responsive patient.
Can changes in LVOT VTI before and after passive leg raising (PLR) test serve as a sensitive
indicator for changes in SV and CO and hence volume responsiveness ?
What is Doppler LVOT VTI? Placing a Pulsed Wave Doppler gate on the LVOT immediately below
the opening of the aortic valve while aligning the Doppler beam as parallel to the
LVOT/aortic axis as possible with an angle of Doppler alignment <20˚, one may obtain Doppler
flow velocity measurements which can help measure the LVOT VTI (Velocity Time Integral). If
one integrates this velocity profile between two time points (i.e., calculates the area
under the curve), the distance traversed of "a region of blood" flowing during this period
may be estimated. Since flow velocity is not constant throughout a flow cycle, all of the
flow velocities during the entire ejection period is integrated to measure "distance
traversed" of this "region of blood." This integration of flow velocities in a given period
of time is called the velocity-time integral (VTI)(1) and yields length or distance
(measured in cm).
Goal: Whether VTI (LVOT) measured from the deep transgastric (deep TG) or transgastric long
axis (TG LAX ) views reflect changes in stroke volume(SV) and hence cardiac output (CO)
measured by the gold standard method (PA CCO by thermodilution) before and after passive leg
raising test (PLR).
Hypothesis: A validated technique to measure cardiac output (CO) using echocardiography is
to calculate stroke volume from the product of LVOT area and LVOT VTI and multiplying the
product with heart rate ( CO = SV x H/R; SV = LVOT area x LVOT VTI ).
The LVOT diameter for an individual is more or less a constant measurement. Therefore using
the formula mentioned above (SV = LVOT area x LVOT VTI), if the LVOT area is constant, then
SV should be proportional to the VTI. This means if a PLR manoeuvre or fluid bolus helps to
achieve a rise in SV, then it should be reflected in an increase in VTI as well. If this
assumption is true, then an increase in the value of VTI from baseline after fluid challenge
(10-15%), should identify a volume responsive patient.
Why do the investigators wish to do the study? A significant improvement in the field of
anesthesiology would occur if we could have a simple yet accurate relatively non-invasive
tool to correctly assess fluid responsiveness. Excessive fluid infused in the operating room
would prolong mechanical ventilation and stay in the ICU and negatively affect the prognosis
of the patient. While monitoring with CCO PA catheter considerable adds to the expense, it
has its own complications and as may not be indicated in majority of operative cases. A
simple non invasive tool using TEE can significantly add to our understanding of
hemodynamics and help guide fluid therapy. If our assumption proves to be correct, then it
could be a simple, yet rapid bedside indicator of CO. It could be used as a simple tool to
assess fluid responsiveness.
The fundamental reason why a fluid challenge (PLR or fluid boluses) is used is to assess
whether there is an increase stroke volume in response to it (2). If the fluid loading fails
to improve the stroke volume the fluid challenge/loading serves no useful purpose. In normal
physiological conditions both the ventricles operate on the ascending limb of the
Frank-Starling curve. Once the left ventricle starts functioning on the 'flat' portion of
the Frank-Starling curve, fluid loading has little or no effect on stroke volume. If LVOT
VTI could be shown to reflect SV adequately then it will be a relatively simple non invasive
dynamic bedside tool to test if fluid boluses are resulting in an increase in VTI hence the
SV.
Volume responsiveness has been assessed in literature by measuring the response to fluid
boluses or to PLR. Thus a positive test where after a PLR, VTI increased significantly
reflecting a positive change in SV and CO, more fluid would be required. Whereas if during
PLR, CO and SV diminished reflected by a decrease in the VTI value compared to baseline, the
subject would be unlikely to respond to fluid therapy and probably would require inotropic
support.
Why PLR ? A recent meta-analysis (3), which pooled the results of eight recent studies,
confirmed the excellent value of PLR to predict fluid responsiveness in critically ill
patients with a global area under the receiver operating characteristic curve of 0.95.
Limitations of using Doppler VTI: However, use of these equations entails a number of
assumptions, including (a) laminar blood flow in the area interrogated, (b) a flat or blunt
flow velocity profile such that the flow across the entire CSA interrogated is relatively
uniform, and (c) Doppler angle of incidence between the Doppler beam and the main direction
of blood flow is less than 20 degrees, so that the underestimation of the flow velocity is
less than 6%.
Study population: 50 adult patients undergoing coronary artery bypass surgery. Materials &
Methods: After institutional ethics committee approval and personal informed consent, 50
patients undergoing elective coronary artery bypass surgery would be included into the
study. Patients with significant arrhythmias, concomitant aortic aneurysms, and esophageal
pathology precluding the use of TEE would be considered ineligible for the study.
Patients would be divided into two groups. Patients with normal LV function or mild LV
systolic dysfunction (LVEF >40%)(4), assessed by preoperative echocardiography would
comprise Group 1, whereas those with preoperative LV moderate to severe systolic dysfunction
(LVEF <40%)(4) would be designated to Group 2.
Anesthetic protocol: Patients would be fasted for 8 hours preceding the operation. No i.v.
fluids would be administered during this period. Patients would be pre-medicated with their
usual cardiovascular medication and 1mg of Lorazepam the night before and would receive 1-2
mg of Midazolam at arrival to the operation theatre. After initiating standard monitoring
(ECG, Pulse oximetry, NBP) invasive lines would be introduced under local anesthetic
infiltration while the patient would receive supplemental oxygen via facemask. Induction of
anesthesia would include 0.05 mg kg_1 Midazolam and 5 mcg kg_1 Fentanyl in addition to
Sevoflurane 3-5% titrated to loss of eyelash reflex. Tracheal intubation would be
facilitated by Rocuronium 0.1 mg kg_1. Anaesthesia would be maintained by Sevoflurane 1.5-2%
titrated to an end tidal value of >1.5%and above supplemented by additional doses of
fentanyl up to a total dose of 15-20 mg kg_1. All patients would receive 500 ml of lactated
Ringer solution during the induction period.
Hemodynamic and Echocardiographic monitoring. A 7.0Fr triple lumen central line, a 8.5 Fr PA
sheath and 7.0 Fr CCO (Continuous Cardiac Output) PA catheter and a 16 G femoral arterial
canula would be introduced prior to induction of anesthesia under light sedation and local
anesthesia. ````A Philips HD 11XE ultrasound machine (Andover, USA) and transesophageal
multiplane echocardiographic probe would be used in all patients. After a comprehensive TEE
examination the probe would be positioned to record images from either a deep TG or TGLAX
views. Images would be recorded for off-line evaluation. A Board certified echocardiographer
proficient in TEE would perform all echocardiographic measurements. Offline
echocardiographic measurements would be done by a trained echocardiographer who would be
blinded to the study protocol. All hemodynamic measurements will be recorded by a dedicated
research nurse.
Experimental protocol: After the induction of anesthesia and initiation of hemodynamic
monitoring the patients would be stabilized as necessary and observed for 10-15 min. No
further interventions would be allowed during this period, including further fluid
administration, changes in anesthetic concentrations or manipulations with inotropic or
vasoconstrictor concentrations. A period of at least 5 min of stable BP, heart rate, CVP,
and continuous cardiac output would be required before obtaining the baseline set of
hemodynamic measurements. A passive leg raising (PLR) maneuver (45%) using protocol
described before* in literature would be performed and changes in hemodynamic and
echocardiographic parameters would be measured within 1 minute post PLR. The same sequence
of PLR and echocardiographic and hemodynamic measurements would be repeated after the end of
the operation and before the transfer to the ICU. No measurements would be carried out in
the presence of hemodynamic instability or immediately following changes of inotropic or
anesthetic medications.
The first set of measurements (HR, MAP, VTI, SV, CO, LVEF and LVOT area ) would be obtained
in the semi-recumbent position (45°; designated 'baseline'). Then, the lower limbs would be
lifted while straight (45°) with the trunk lowered in the supine position. The second set of
measurements of (designated 'during PLR') was obtained during leg elevation, at the moment
when VTI plateaued at its highest value. The stroke volume with CCO monitor would be
recorded at the moment when it plateaued at its highest value.
NB. Why record changes in VTI/SV etc . within 1 minute post PLR ? Because the maximal
hemodynamic effects of PLR occur within the first minute of leg elevation, it is important
to assess these effects with a method that is able to track changes in cardiac output or
stroke volume on a real-time basis.(5)
NB. Passive leg raising. The passive leg raising test consists in measuring the hemodynamic
effects of a leg elevation up to 45°. A simple way to perform the postural maneuver is to
transfer the patient from the semirecumbent posture to the passive leg raising position by
using the automatic motion of the bed.
;
Allocation: Randomized, Intervention Model: Single Group Assignment, Masking: Double Blind (Caregiver, Outcomes Assessor), Primary Purpose: Screening
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