Paceport Swan-Ganz Data Collection Study

Completed

• Conditions: Right Ventricular Dysfunction; Right Heart Failure; Congestive Heart Failure

• Registration Number: NCT04782154
• Lead Sponsor: Montreal Heart Institute

Brief Summary

RV dysfunction has been associated with increased mortality in the ICU and cardiac surgical patients. Thus, early identification of RV dysfunction at less severe stages will allow for earlier intervention and potentially better patient outcomes. However, so far, no studies have reported prospectively the prevalence of abnormal RV pressure waveform during cardiac surgery and in the ICU. Our primary hypothesis is that the prevalence of abnormal RV pressure waveform occurs in more than 50% of cardiac surgical patients throughout their hospitalization. Those patients with abnormal RV pressure waveform will be more prone to post-operative complications related to RV dysfunction and failure in the OR and ICU.

Detailed Description

The pulmonary artery catheter (PAC) consists of an intravenous device placed in the pulmonary artery to measure cardiac output, pulmonary artery pressures (Richard C, 2011) as well as cardiac filling pressures. Since its initial presentation by Swan in 1970 (H J Swan, 1970), several modifications were made on the initial catheter now allowing continuous assessment of cardiac output, continuous monitoring of stroke volume (SV), systemic vascular resistance (SVR) and mixed venous saturation (SvO2) (Arora, 2014) (H J Swan, 1970) (Richard C, 2011). We intend to enhance current Swan-Ganz catheters with clinical decision support tools to early identify hemodynamically unstable states that can lead to further deterioration of the patient's health state.

Right ventricular (RV) dysfunction is mostly associated to a decrease in contractility, right ventricular pressure overload or right ventricular volume overload (François Haddad, 2008). RV dysfunction can occur in several clinical scenarios in the intensive care unit (ICU) and operating room (OR): pulmonary embolism, acute respiratory distress syndrome (ARDS), septic shock, RV infarction, and in pulmonary hypertensive patients undergoing cardiac surgery (François Haddad, 2008). RV dysfunction has been associated with increased mortality in the ICU and cardiac surgical patients (André Y. Denault, 2006) (Denault AY B. J.-S., 2016). Thus, early identification of RV dysfunction at less severe stages will allow for earlier intervention and potentially better patient outcomes. Unfortunately, identifying which patients will develop RV dysfunction and then progress towards RV failure have proven difficult. One of the reasons for delaying the diagnosis of RV dysfunction could be the lack of uniform definition, especially in the perioperative period. Echocardiographic definitions of RV dysfunction have been described in previous studies: RV fractional area change (RVFAC) \< 35 %, tricuspid annular plane systolic excursion (TAPSE) \< 16 mm, tissue Doppler S wave velocity \<10 cm/s, RV ejection fraction (RVEF) \<45% and RV dilation have been related to RV dysfunction (Rudski LG, 2010). However, these echocardiographic indices cannot be continuously monitored and are insufficient in describing RV function. The diagnosis of fulminant RV failure is more easily recognized as a combination of echocardiographic measures, compromised hemodynamic measures and clinical presentation (Raymond M, 2019) (François Haddad, 2008) (Haddad F, 2009). RV dysfunction is inevitably associated with absolute or relative pulmonary hypertension because of the anatomic and physiological connection between the RV and pulmonary vascular system (Naeije R, 2014) (François Haddad, 2008). The gold standard for measuring pulmonary pressure is still the pulmonary artery catheter. However, RV output can initially be preserved despite of pulmonary hypertension (Denault AY C. M., 2006). It is therefore mandatory that early, objective, continuous, easily obtainable and subclinical indices of RV dysfunction are found and validated to initiate early treatment of this disease.

Since 2002, Dr Denault's group at Montreal Heart Institute has been using continuous RV pressure waveform monitoring initially for the diagnosis of RV outflow tract obstruction (Denault A, 2014) and then for RV diastolic dysfunction evaluation (St-Pierre P, 2014) (Myriam Amsallem, 2016). Preliminary data based on a retrospective study on 259 patients found that 110 (42.5%) patients had abnormal RV gradients before cardiopulmonary bypass (CPB).Abnormal RV diastolic pressure gradient was associated with higher EuroSCORE II (2.29 \[1.10-4.78\] vs. 1.62 \[1.10-3.04\], p=0.041), higher incidence of RV diastolic dysfunction using echocardiography (45 % vs. 29 %, p=0.038), higher body mass index (BMI) (27.0 \[24.9-30.5\] vs. 28.9 \[25.5-32.5\], p=0.022), pulmonary hypertension (mean pulmonary artery pressure (MPAP) \> 25 mmHg) (37 % vs. 48 %, p=0.005) and lower pulmonary artery pulsatility index (PAPi) (1.59 \[1.19-2.09\] vs. 1.18 \[0.92-1.54\], p\<0.0001). Patients with abnormal RV gradient had more frequent difficult separation from CPB (32 % vs. 19 %, p=0.033) and more often received inhaled pulmonary vasodilator treatment before CPB (50 % vs. 74 %, p\<0.001). However, this was retrospective and limited to the pre-CPB period.

In 2017, in a review article on RV failure in the ICU (Hrymak C, 2017), RV pressure waveform monitoring using the paceport of the pulmonary artery catheter was recommended as a simple method of monitoring RV function (Rubenfeld GD, 1999). However, no studies have reported prospectively the prevalence of abnormal RV pressure waveform during cardiac surgery and in the ICU.

Study Timeline

• Study First Submitted: 2021-03-01
• Study First Submitted QC: 2021-03-01
• Study First Posted: 2021-03-04
• Study Start: 2021-08-09
• Primary Completion: 2022-03-01
• Study Completion: 2022-04-01
• Status Verified: 2022-08
• Last Update Submitted: 2022-08-31
• Last Update Posted: 2022-09-02

Recruitment & Eligibility

• Status: COMPLETED
• Sex: All
• Target Recruitment: 136

Inclusion Criteria

• Be ≥ 18 years of age
• Participate in the Informed Consent process and sign/date the approved informed consent forms
• Projected to receive Swan-Ganz catheter as part of procedure/standard of care with intermittent cardiac output and mixed venous oxygen saturation (SvO2) measures

Exclusion Criteria

• Refuse to sign consent
• Have left bundle branch block
• Have recurrent sepsis
• Have hypercoagulopathy
• Allergic to FORE-SIGHT Elite sensor adhesive
• Latex allergy due to presence of latex in the Swan-Ganz catheter balloon.

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Primary Outcome Measures

Name	Time	Method
Proportion of abnormal diastolic RV waveforms before CPB, after CPB and in the ICU	From thermodilution catheter insertion until 2 hours after ICU arrival	Abnormal RV pressure waveform will be defined as a difference between the RV end-diastolic minus the early-diastolic pressure \> 4 mmHg and a RVdP/dt \< 400 mmHg.

Secondary Outcome Measures

Name	Time	Method
Proportion of patients with difficult and complex separation from cardiopulmonary bypass at the end of cardiac surgery	From the discontinuation of cardiopulmonary bypass until ICU arrival after surgery, assessed up to 4 hours	Difficult separation from cardiopulmonary bypass: instability requiring at least two different types of pharmacological agents (i.e., inotropes ± vasopressors ± inhaled agents) Complex separation from cardiopulmonary bypass: Hemodynamic instability requiring return on cardiopulmonary bypass or addition of mechanical support (intra-aortic balloon pump or extra-corporeal membrane oxygenator)
Cumulative time of Persistent Organ Dysfunction or Death (TPOD) during the first 28 days after cardiac surgery	Up to 28 days or until hospital discharge	TPOD is a continuous variable representative of the burden of care and morbidity during the first 28 days following cardiac surgery and was chosen to circumvent issues arising for using other clinical endpoint such as ICU length of stay
Incidence of deep sternal wound infection or mediastinitis	Up to 28 days or until hospital discharge	Diagnosis of a deep incisional surgical site infection or mediastinitis by a surgeon or attending physician
Duration of mechanical ventilation (in hours)	Up to 28 days or until hospital discharge	A duration of \>24 hours will be considered prolonged ventilation requirements.
Right ventricular strain	From arrival to the operating room until 2 hours after ICU arrival	Assessed by the American Society of Echocardiography guidelines
Tricuspid annular plane systolic excursion	From arrival to the operating room until 2 hours after ICU arrival	Assessed by the American Society of Echocardiography guidelines
Right ventricular performance index	From arrival to the operating room until 2 hours after ICU arrival	Assessed by the American Society of Echocardiography guidelines
Right ventricular stroke work index	From arrival to the operating room until 2 hours after ICU arrival	0.0136x Stroke volume index x (Mean pulmonary artery pressure-mean right atrial pressure)
Pulmonary artery pulsatility index (PAPi)	From arrival to the operating room until 2 hours after ICU arrival	Defined as (systolic pulmonary artery pressure - diastolic pulmonary artery pressure)/central venous pressure
Incidence of deaths during hospitalisation	Up to 28 days or until hospital discharge	Death from any cause
Incidence of acute kidney injury (AKI)	Up to 28 days or until hospital discharge	Acute kidney injury (AKI) according to KDIGO serum creatinine criteria: Stage 1: ≥50% or 27 umol/L increases in serum creatinine, Stage 2: ≥100% increase in serum creatinine, Stage 3 ≥200% increase in serum creatinine or an increase to a level of ≥254 umol/L or dialysis initiation.
Incidence of surgical reintervention for any reasons	Up to 28 days or until hospital discharge	Re-operation after the initial surgery for any cause
Right ventricular fractional area change	From arrival to the operating room until 2 hours after ICU arrival	Assessed by the American Society of Echocardiography guidelines
Up to 28 days or until hospital discharge	Up to 28 days or until hospital discharge	Number of days hospitalized from the day of surgery to discharge
Right ventricular ejection fraction	From arrival to the operating room until 2 hours after ICU arrival	Assessed by the American Society of Echocardiography guidelines
Incidence of major bleeding	Up to 28 days or until hospital discharge	Major bleeding is defined by the Bleeding Academic Research Consortium (BARC) as one of the following: • Perioperative intracranial bleeding within 48h • Reoperation after closure of sternotomy for the purpose of controlling bleeding • Transfusion of ≥5 units of whole blood of packed red blood cells within a 48 hours period • Chest tube output ≥2L within a 24 hours period
Incidence of stroke	Up to 28 days or until hospital discharge	Central neurologic deficit persisting longer than 72 hours
Incidence of major morbidity or mortality	Up to 28 days or until hospital discharge	Including death, prolonged ventilation, stroke, renal failure (Stage ≥2), deep sternal wound infection and reoperation for any reason.
Compliance of the pulmonary artery (CPA)	From arrival to the operating room until 2 hours after ICU arrival	Stroke volume divided by the pulmonary artery pulse pressure (systolic minus the diastolic pulmonary artery pressure)
Right ventricular outflow tract obstruction	From arrival to the operating room until 2 hours after ICU arrival	Right Ventricular Systolic pressure minus Pulmonary Artery Systolic pressure ≤ 6 mmHg.
Incidence of delirium	Up to 28 days or until hospital discharge	Delirium is defined as an intensive care delirium screening checklist (ICDSC) score(18) of ≥4 in the week following surgery or positive result for the Confusion Assessment Method for the ICU (CAM-ICU).
Total duration of ICU stay in hours	Up to 28 days or until hospital discharg	Number of hours passed in the ICU
Duration of vasopressor requirements (in hours)	Up to 28 days or until hospital discharge	Vasopressors include norepinephrine, epinephrine, dobutamine, vasopressin, phenylephrine, milrinone, isoproterenol and dopamine
Portal flow pulsatility fraction	From arrival to the operating room until 2 hours after ICU arrival	Portal flow pulsatility fraction
Relative pulmonary pressure	From arrival to the operating room until 2 hours after ICU arrival	The ratio of the mean systemic arterial pressure divided by the mean pulmonary artery pressure
Right ventricular function index	From arrival to the operating room until 2 hours after ICU arrival	Defined as (isovolumic contraction time + isovolumic relaxation time)/RV ejection time
Pulsatility of femoral venous flow	From arrival to the operating room until 2 hours after ICU arrival	Velocity variations of blood flow in the femoral vein during the cardiac cycle

Trial Locations

Locations (1)

Montreal Heart Institute; 🇨🇦 Montreal, Quebec, Canada