Carotid Doppler and EEOT for Fluid Responsiveness Prediction

Study Description

Brief Summary

Fluid responsiveness prediction prior to fluid challenge administration is a topic of interest, which has been extensively investigated, but remains challenging.

In clinical practice, functional hemodynamic tests (FHT) consisting of maneuvers that affect cardiac function and/or heart-lung interaction, have been introduced in order to identify fluid responders and non-responders without fluid challenge administration.

Changes in cardiac output induced by the Passive Leg Raising (PLR) test reliably predicted the increase in cardiac output to volume expansion. New approaches have been recently developed based on changes in respiratory dynamics, such as a transient increase in tidal volume, or a lung recruitment maneuver or an end-expiratory occlusion (EEO) test. The EEO leaded to an increase in venous return, cardiac preload and stroke volume in preload-responsive patients. The authors found that an increase in cardiac output ≥ 5% during a 15-s EEO reliably predicted its response to a 500-ml saline infusion.

However, in order to identify the rapid and transient increase in cardiac index during the EEO, continuous and instantaneous cardiac output monitoring is necessary. Pulse contour analysis methods provide a beat-to-beat estimation of cardiac output and had been used in most of studies validating the EEO test.

Carotid doppler is a non-invasive, bedside, easy to use ultrasound technique that measuring blood flow peak velocity (CDPV) and duration of systolic component of each cardiac cycle (from the onset to dicrotic notch- Flow time - FT) allows a reliable estimation of fluid status and could be an interesting alternative to track changes in SV and cardiac output.

Detailed Description

The aim of the present study is to investigate whether changes in systolic peak velocity (ΔV peak-CA) and in flow time (ΔFT) using carotid artery Doppler during an End-Expiratory Occlusion Test (EEOT) predict fluid responsiveness in patients with septic shock and lung protective mechanical ventilation in ICU.

All patients will be in supine position (trunk elevated 30°), sedated, paralyzed and mechanically ventilated in the volume control mode. Tidal volume will be set at 6-8 ml/kg of predicted body weight.

They will be all monitored by an EV1000TM/Volume View (Edwards Lifesciences Corporation, Irvine, CA 92614) for measurement of cardiac index through transpulmonary thermodilution (TPTD) and pulse contour analysis. Cardiac index and the other hemodynamic parameters derived from pulse contour analysis will be continuously recorded over a 20-sec period.

Phase 1 (baseline): a first set of TPTD will be performed to assess the cardiac index (CI), the stroke volume index (SVI), the stroke volume variation (SVV), the systemic vascular resistance index (SVRI). The mean arterial pressure (MAP), heart rate (HR), central venous pressure (CVP) were also recorded. A carotid doppler was performed to measure the systolic peak velocity (CDPV) and the flow time (FT) (see below).

Phase 2 (EEOT): A 20-second EEO will be than applied through a touch of ventilator for measuring the total end-expiratory pressure. MAP, HR, SVI, CVP, SVRI, pulse contour-derived CI were averaged during the 5 last seconds of the EEO because the maximal hemodynamic effects of the occlusion were observed at this time and because the EV1000TM monitor updates the data every 20 seconds. During this pause a carotid Doppler will be performed and the last 5 seconds will be recorded.

The effects of EEOT on cardiac index will be measured by pulse contour analysis and not by TPTD because these effects must be assessed by a real-time monitoring technique. In practice, the investigators will observe the continuously changing values of pulse contour analysis-derived cardiac index while performing the Doppler measurements.

Phase 3 (fluid challenge): The patients then will receive a 10-minute infusion of 500 mL saline or lactate ringer (7 ml/kg). A last set of hemodynamic measurements, including CI, MAP, HR, SVI, CVP, SVRI, and carotid Doppler, will be recorded after fluid infusion.

As soon as the cardiac index value started to increase, the investigators will consider that it had reached its maximum. At this precise time, they will freeze the image of the echograph and performed the Doppler measurements on the values displayed during the previous seconds. If pulse contour analysis-derived cardiac index will increase ≥ 5% during the EEOT, compared to the baseline value, the patient will be consider as responder to the test.

Catecholamine's infusion, mechanical ventilation settings and bed position will be kept constant during the study period.

Study Design

Outcome Measures

Primary Outcome Measures

1. Fluid responsiveness [during EEOT]

   Evaluation of changes in systolic peak velocity (ΔV peak-CA) and in flow time (ΔFT) using carotid artery Doppler during an end-expiratory occlusion test and after fluid-challenge (500 ml)

Eligibility Criteria

Criteria

Inclusion Criteria:

• sedated and mechanically ventilated patients

• need a fluid challenge

• hypotension defined as a systolic arterial pressure ≤90 mmHg

• tachycardia ≥100 beats/min

• urinary flow ≤0.5 mL/kg/min for 2 hrs

Exclusion criteria:

• age< 18 y old

• significant valvular heart diseases

• cardiac arrhythmia

• peripheral arterial disease

• common carotid artery stenosis greater than 50%

• spontaneous breathing.

Contacts and Locations

Locations

Sponsors and Collaborators

• Fondazione Policlinico Universitario Agostino Gemelli IRCCS

Investigators

Study Documents (Full-Text)

More Information

Publications

• Blehar DJ, Glazier S, Gaspari RJ. Correlation of corrected flow time in the carotid artery with changes in intravascular volume status. J Crit Care. 2014 Aug;29(4):486-8. doi: 10.1016/j.jcrc.2014.03.025. Epub 2014 Apr 2.
• Hossein-Nejad H, Mohammadinejad P, Lessan-Pezeshki M, Davarani SS, Banaie M. Carotid artery corrected flow time measurement via bedside ultrasonography in monitoring volume status. J Crit Care. 2015 Dec;30(6):1199-203. doi: 10.1016/j.jcrc.2015.08.014. Epub 2015 Aug 22.
• Ibarra-Estrada MÁ, López-Pulgarín JA, Mijangos-Méndez JC, Díaz-Gómez JL, Aguirre-Avalos G. Respiratory variation in carotid peak systolic velocity predicts volume responsiveness in mechanically ventilated patients with septic shock: a prospective cohort study. Crit Ultrasound J. 2015 Dec;7(1):29. doi: 10.1186/s13089-015-0029-1. Epub 2015 Jun 26.
• Mackenzie DC, Khan NA, Blehar D, Glazier S, Chang Y, Stowell CP, Noble VE, Liteplo AS. Carotid Flow Time Changes With Volume Status in Acute Blood Loss. Ann Emerg Med. 2015 Sep;66(3):277-282.e1. doi: 10.1016/j.annemergmed.2015.04.014. Epub 2015 May 21.
• Monnet X, Osman D, Ridel C, Lamia B, Richard C, Teboul JL. Predicting volume responsiveness by using the end-expiratory occlusion in mechanically ventilated intensive care unit patients. Crit Care Med. 2009 Mar;37(3):951-6. doi: 10.1097/CCM.0b013e3181968fe1.
• Myatra SN, Prabu NR, Divatia JV, Monnet X, Kulkarni AP, Teboul JL. The Changes in Pulse Pressure Variation or Stroke Volume Variation After a "Tidal Volume Challenge" Reliably Predict Fluid Responsiveness During Low Tidal Volume Ventilation. Crit Care Med. 2017 Mar;45(3):415-421. doi: 10.1097/CCM.0000000000002183.
• Pinsky MR. Functional hemodynamic monitoring. Crit Care Clin. 2015 Jan;31(1):89-111. doi: 10.1016/j.ccc.2014.08.005. Review.
• Shokoohi H, Berry GW, Shahkolahi M, King J, King J, Salimian M, Poshtmashad A, Pourmand A. The diagnostic utility of sonographic carotid flow time in determining volume responsiveness. J Crit Care. 2017 Apr;38:231-235. doi: 10.1016/j.jcrc.2016.10.025. Epub 2016 Nov 9.