Pulmonary Hypertension Clinical Trial
Official title:
Comparative Effects of Brief Inhaled Milrinone Versus Intravenous Milrinone on Pulmonary Arterial Pressure in Patients Undergoing Mitral Valve Surgery
Our main hypothesis is that inhalation of milrinone can reduce the elevated pulmonary arterial pressure due to severe mitral valve regurgitation without compromising systemic hemodynamics. Therefore, the effects of a brief inhaled milrinone (IH) on pulmonary artery pressure are determined and compared to those of intravenous milrinone (IV) in severe mitral regurgitation patients undergoing mitral valve surgery.
Perioperative pulmonary hypertension (PHT), an independent risk factor for cardiac surgery,
1,2 is frequently associated with chronic mitral valve regurgitation and tends to produce
right ventricular (RV) dysfunction. Worsening PHT, which is sensitive to any increase in the
RV afterload, reduces the right coronary perfusion pressure, exacerbates RV dysfunction, and
compromise the left ventricular (LV) preload and systemic perfusion pressure. 3,4 Although
intravenous (IV) milrinone is preferred for treating PHT due to its beneficial effects in
enhancing myocardial contractability without increasing the heart rate-related myocardial
oxygen consumption, 5-7 its frequent association with systemic vasodilation requires
additional vasoconstrictor therapy for maintaining the optimal perfusion pressure.8-10
Selective pulmonary vasodilation, which reduces the RV afterload without systemic arterial
vasodilation, is important for managing PHT and the accompanying RV dysfunction.11 A study
reported that nebulized and inhaled (IH) milrinone ( 1 mg/ml) produced dose-dependent
selective pulmonary vasodilatation in postoperative PHT in the intensive care unit.12 If IH
milrinone during the pre-cardiopulmonary bypass (CPB) period produces selective pulmonary
vasodilation in patients with PHT undergoing mitral valve surgery, it would be a beneficial
option for managing intraoperative PHT.
Our main hypothesis is that a brief inhaled milrinone could reduce the pulmonary arterial
pressure without the systemic side effects better than intravenous milrinone in elevated
pulmonary artery pressure patients. The aim of this study is to determine the effects of
hemodynamic before and after administering IH and to compare them to those of IV milrinone
in patients with elevated pulmonary artery pressure due to severe mitral regurgitation
undergoing mitral valve surgery.
Materials and Methods Experimental Groups Adult patients with PHT (systolic PAP > 50 mmHg
estimated by the velocity of tricuspid valve regurgitation in preoperative transthoracic
echocardiography) undergoing mitral valve surgery for chronic mitral regurgitation are
enrolled in this study after obtaining approval from the institutional research board and
providing written informed consent.
Preoperative exclusion criteria include preoperative supraventricular tachycardia (SVT),
atrial fibrillation, atrial flutter, multiple ventricular ectopic contractions, continuous
inotropic support, LV ejection fraction (EF) < 30%, emergent surgery, obstructive
cardiomyopathy, bleeding diatheses, bronchial asthma and had biochemical evidence of hepatic
disease or renal impairment.
The pharmacist implements the randomization process for grouping the patients by giving the
enrolled patients, a patient identification number (PIN). Then, the patients are stratified
by their PIN in a 1:1 ratio to receive IH (Primacor, Sanofi-Synthelabo Canada Inc., Markham,
ON, Canada) (Group IH) or IV (Group IV) milrinone. The investigators are blinded to the
allocation of the study group.
Anesthesia and Patient Monitoring When the patient arrived in the operating room, continuous
monitoring of a five-lead ECG (lead II and V5), the bispectral index (BIS), pulse oximetry,
and invasive arterial pressure via the radial artery are started. Patients are given
midazolam 1.5-2 mg intravenously in the patient holding area. Anesthesia is induced with
propofol 1-1.5 mg/kg, fentanyl 10-15 μg/kg, and rocuronium 0.9 mg/kg. Target controlled
infusion (TCI) and a TCI infusor (Diprifusor™ TCI system; Fresenius, Waltham, MA, USA) are
used to administer propofol for anesthetic induction and maintenance, and the infusion dose
is titrated to achieve a propofol effect-site concentration of 2-2.5 μg/ml. Additional
fentanyl at 10-30 μg/kg/h and rocuronium at 20-30 mg/h are administered to maintain
anesthesia, and the propofol concentration is adjusted to maintain a BIS score of 40-60.
After tracheal intubation, volume-controlled ventilation of oxygen with air (FiO2 0.6, flow
rate 100 ml/kg/min) is started with a tidal volume of 10 ml/kg, respiration rate of
12-14/min, inspiration:expiration ratio of 1:2, and peak airway pressure lower than 25
cmH2O. Then, the respiration rate is adjusted to maintain an end-tidal CO2 of 35-40 mmHg.
An introducer and a pulmonary artery catheter (Oximetrix™ Opticath catheter; Abbot
Laboratories, North Chicago, IL, USA) are placed in the right internal jugular vein. A
transesophageal echocardiography (TEE) probe is placed, and intraoperative TEE is used to
monitor ventricular and valvular function throughout the operation. The LV EF is measured
using a modification of Simpson's method from the midesophageal 4 or 2 chamber view of
two-dimensional TEE images as appropriate.
During and after anesthesia induction and obtaining vascular access for hemodynamic
monitoring, synthetic hydroxyethylstarch (Voluven™; Fresenius Kabi, Bad Homberg, Germany) is
administered as needed to maintain stable hemodynamics, and bolus phenylephrine 50-100 μg is
administered intravenously to treat any refractory hypotension (MAP < 60 mmHg) persisting
for more than 1 min with intravascular volume administration.
After delivering the study drugs and collecting data, CPB with moderate hypothermia (rectal
temperature 28-30ºC) via crystalloid cardioplegia is used during the surgical procedure. The
MAP was maintained at 50-80 mmHg by adjusting the pump flow and administering 50 μg boluses
of phenylephrine during the CPB period.
The IV milrinone infusion (0.5 μg/kg/min) is started at the release of the aortic
cross-clamp and a continuous infusion of norepinephrine is started at a rectal temperature
of 35ºC as needed; its dosage is titrated to wean the patient from CPB and to maintain the
optimal hemodynamics during the post-CPB period in both groups.
Delivery of the Study Drug After performing the sternotomy and achieving stable
hemodynamics, but before the initiation of CPB, the study drugs are administered; IH
milirinone and IV placebo (0.9% normal saline 0.05 ml/kg) or IH placebo (distilled water)
and an IV bolus of milrinone (50 μg/kg) are administered in Group IH and IV, respectively.
Milrinone is used at its commercial concentration (1.0 mg/ml) for both inhalation and IV
administration. The reservoir of a nebulizer (MiniHeart™; Westmed, Tucson, AZ, USA) in the
inspiratory limb of the ventilator circuit (90 cm proximal to the Y-piece) is filled with
milrinone or placebo. The milrinone or placebo in the reservoir is nebulized with a fixed
operating flow at 2 L/min of O2 (as per the manufacturer's recommendation) and delivered
over 10 min at a ventilator flow rate of 100 ml/kg/min to avoid rebreathing the expiratory
flow, which may produce contamination or interaction between the nebulized milrinone and CO2
absorbent (Fig. 1). The aerosol size and delivery rate of the nebulized drug are assumed to
be 1.0-2.5 μm and 45-65 μL per gas flow, respectively, according to the manufacturer's
manual for the nebulizer. Excess inspiratory gas flow from the nebulizer was compensated for
by adjustment of minute ventilation settings on the ventilator, keeping minute ventilation
constant. Inspiratory oxygen fraction (FiO2) is kept constant throughout the procedure. If
MAP decreases below 60 mmHg, inhalation of the study drug is stopped and the patient
excluded from the study.
Hemodynamic Data The following data are obtained before and 10 min after completely
administering the study drug: mean arterial pressure (MAP), mean pulmonary arterial pressure
(MPAP), central venous pressure (CVP), pulmonary arterial occlusion pressure (PAOP), the
transpulmonary pressure gradient (TPG= mean PAP-PAOP), thermodilution cardiac output (CO),
systemic vascular resistance (SVR), pulmonary vascular resistance (PVR), arterial O2 tension
(PaO2), mixed venous O2 saturation (SvO2), and TEE measured EF.
Statistical Analysis Intergroup comparisons of the changes in SVR, PVR, the PVR/SVR ratio,
and TPG are used to identify selective pulmonary vasodilation. The data before and after
administration are compared using paired t-test. If the data do not pass a normality test,
the Wilcoxon signed-rank test was used. Intergroup data are compared using the t-test. The
need for bolus phenylephrine due to hypotension in the pre-CPB period or during CPB is
compared using Fisher's exact test. Statistical significance is assumed at p<0.05.
;
Allocation: Randomized, Endpoint Classification: Efficacy Study, Intervention Model: Parallel Assignment, Masking: Double Blind (Subject, Caregiver, Investigator, Outcomes Assessor), Primary Purpose: Treatment
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