Samuel Padovani StefenI; Davi Freitas TenórioI; Guilherme Carvalhal Gnipper CirilloI; Shirlyne Fabianni GasparI; Karen Amanda Soares de OliveiraII; Fábio Antonio GaiottoI; Fabio B. JateneI
DOI: 10.21470/1678-9741-2022-0107
ABSTRACT
Introduction: The aims of this study were to determine the incidence of severe and moderate primary graft dysfunction (PGD) in our center, to identify, retrospectively, donors’ and recipients’ risk factors for PGD development, and to evaluate the impact of PGD within 30 days after heart transplantation.BiVAD = Biventricular assist device
CI = Cardiac index
CPR = Cardiopulmonary resuscitation
ECMO = Extracorporeal membrane oxygenation
IABP = Intra-aortic balloon pump
ICU = Intensive care unit
ISHLT = International Society for Heart and Lung Transplantation
LVAD = Left ventricular assist device
LVEF = Left ventricular ejection fraction
MAP = Mean arterial pressure
PCWP = Pulmonary capillary wedge pressure
PGD = Primary graft dysfunction
PGD-LV = Left ventricular primary graft dysfunction
PGD-RV = Right ventricular primary graft dysfunction
RAP = Right atrial pressure
RVAD = Right ventricular assist device
TPG = Transpulmonary pressure gradient
VAD = Ventricular assist device
INTRODUCTION
The outcomes after heart transplantation have improved over the last years, with the mean survival being approximately ten years nowadays[1,2]. Despite this improvement, several factors still contribute to the morbidity and mortality of patients undergoing heart transplantation. In this context, primary graft dysfunction (PGD) is the main cause of early mortality after this procedure[3,4]. The most recent report from the International Society for Heart and Lung Transplantation (ISHLT) Registry reported that 42.6% of deaths within 30 days after heart transplantation were due to PGD[1,5]. Due to the lack of standardized criteria for its diagnosis, the incidence of PGD reported in the literature has varied widely between two and 24%[6,7]. To discuss this issue, the ISHLT recently published a consensus with standardized criteria for PGD[8]. The ISHLT consensus emphasized that the diagnosis of PGD must be made within 24 hours after completion of the transplantation surgery, and that other discernible causes such as hyper-acute rejection, pulmonary hypertension, or known surgical complications must be ruled out in order to diagnose PGD.
The objectives of this study are to determine the incidence of severe and moderate PGD in our center using the ISHLT criteria, to identify, retrospectively, donors’ and recipients’ risk factors for PGD development, and to evaluate the impact of PGD within 30 days after heart transplantation.
METHODS
This study was approved by our institutional committee (CAAE: 86764218.1.0000.0068). The medical records of 64 patients undergoing heart transplantation procedures from January 2016 to June 2017 were reviewed. Information about the respective donors was also reviewed. Recipients’ characteristics examined were demographics, etiology of heart failure, and mechanical assistance prior to transplant. Donors’ characteristics included demographics, cause of death, and hemodynamics/use of inotropic support. Procedural characteristics included distance from the donors’ centers to the recipients’ centers, extracorporeal mean time, and cold ischemia time. The ISHLT recently published standardized criteria were used to diagnose PGD (Table 1).
| Left ventricular PGD (PGD-LV) | Mild PGD-LV (one of the following criteria must be met) | LVEF < 40% by echocardiography or hemodynamics with RAP > 15 mmHg, PCWP > 20 mmHg, CI < 2.0 L/min/m2 (lasting > 1 h) requiring low-dose inotropes. |
| Moderate PGD-LV (must meet one criterion from I and another criterion from II) | I. LVEF < 40% or hemodynamic compromise with RAP > 15 mmHg, PCWP > 20 mmHg, CI < 2.0 L/min/m2, hypotension with MAP < 70 mmHg (lasting > 1 h). | |
| II. High-dose inotropes — inotrope score > 10* or newly placed IABP (regardless of inotropes). | ||
| Severe PGD-LV | Dependence on left or biventricular mechanical support including ECMO, LVAD, BiVAD, or percutaneous LVAD. Excludes requirement for IABP. | |
| Right ventricular PGD (PGD-RV) | Diagnosis requires either both i and ii, or iii alone | i. Hemodynamics with RAP > 15 mmHg, PCWP < 15 mmHg, CI < 2.0 L/min/m2. |
| ii. TPG < 15 mmHg and/or pulmonary artery systolic pressure < 50 mmHg. | ||
| iii. Need for RVAD. |
BiVAD=biventricular assist device; CI=cardiac index; ECMO=extracorporeal membrane oxygenation; IABP=intra-aortic balloon pump; LVAD=left ventricular assist device; LVEF=left ventricular ejection fraction; MAP=mean arterial pressure; PCWP=pulmonary capillary wedge pressure; RAP=right atrial pressure; RVAD=right ventricular assist device; TPG=transpulmonary pressure gradient
* Inotrope score = dopamine (1) + dobutamine (1) + amrinone (1) + milrinone (15) + epinephrine (100) + norepinephrine (100) with each drug dosed in mg/kg/min
Donor heart procurement was performed according to a standard procedure using 3000 ml of Custodiol® solution for preservation of the donor’s heart. All transplant procedures were performed with a bicaval technique, and the same immunosuppression protocol was prescribed to all patients.
RESULTS
Baseline characteristics of donors and recipients are listed in Tables 2 and 3, respectively. The mean donor age was 33.4 years, and 90.6% of them were male. The etiology of brain death in the majority of cases was head trauma, followed by intracranial hemorrhage; and 78.1% of the donors were in use of inotropic support. There were 24 cases with a > 200 km distance from the donor’s to the recipient’s center. Cold ischemia mean time was 156 minutes (Table 4).
| Overall (64) | |
|---|---|
| Age, years (mean) | 33.4 |
| Cause of brain death | |
| Head trauma | 44 (68.7%) |
| Intracranial hemorrhage | 14 (21.8%) |
| Other | 6 (9.5%) |
| Sex | |
| Male | 58 (90.6%) |
| Female | 6 (9.4%) |
| Use of inotropic support | 50 (78.1%) |
| Overall (64) | |
|---|---|
| Age, years (mean) | 49.5 |
| Male sex (%) | 62.5 |
| Etiology | |
| Dilated cardiomyopathy | 24 (37.6%) |
| Ischemic cardiomyopathy | 16 (25%) |
| Chagas disease | 20 (31.2%) |
| Others | 4 (6.2%) |
| LVAD support | |
| IABP | 30 (46.8%) |
| ECMO | 2 (3.3%) |
| Others | 3 (4.6%) |
| Use of inotropic support | 29 (45.3%) |
| Distance from the donor’s center (> 200 km) | 24 |
| Extracorporeal mean time (min) | 73 |
| Cold ischemia time (min) | 156 |
Most of the recipients were male (65.5%), with mean age of 49.5 years. The most common etiology of heart failure was dilated cardiomyopathy (37.6%), followed by Chagas disease (31.2%), and ischemic cardiomyopathy (25%). The majority of patients (98.4%) were hospitalized in priority, receiving inotropic support only (45.3%) or some type of left ventricular assist device (LVAD), with intra-aortic balloon pump being the most prevalent (46.8%). Two patients (3.3%) required extracorporeal membrane oxygenation, two patients (3.3%) were in use of LVAD – InCor® support, and only one (1.5%) patient required left Centrimag® support prior to heart transplantation.
A total of 12 (18.7%) patients were diagnosed with moderate or severe PGD using the ISHLT criteria. Of the 12 recipients with PGD, three had right ventricular PGD, six had left ventricular PGD, and three had biventricular PGD. The patients were divided into PGD group and non-PGD group for statistical analysis. The variables compared were recipient-related, donor-related, and procedure-related, and are listed in Table 5.
| Variable | Non-PGD | Moderate/severe PGD | P-value |
|---|---|---|---|
| Recipients’ variables | Overall (52) | Overall (12) | |
| Age (mean), years | 49.85 | 45.5 | 0.44 |
| Gender, female | 28 (53.8%) | 4 (33.3%) | 0.39 |
| Ischemic cardiomyopathy | 12 (23.0%) | 3 (25%) | 0.30 |
| Non-ischemic cardiomyopathy | 40 (67%) | 9 (75%) | 0.35 |
| VAD prior to transplant | 28 (54.7%) | 6 (50%) | 0.75 |
| Prior sternotomy | 3 (5.7%) | 3 (25%) | 0.02 |
| ICU prior to transplant | 31 (59.6%) | 6 (50%) | 0.34 |
| Donors’ variables | |||
| Age (mean) | 32 | 30 | 0.35 |
| Head trauma | 34 (65.3%) | 7 (58.3%) | 0.83 |
| Other cause of death | 18 (34.7%) | 5 (41.7%) | 0.82 |
| Previous CPR | 0 | 2 (16.6%) | 0.01 |
| Inotropic support (not > 0.1 ug/kg/min) | 46.15 (24%) | 7 (58.33%) | 0.2 |
| Procedure-related variables | |||
| Distance from the donor’s center to the transplant center (> 200 km) | 19 (36.5%) | 5 (41.5%) | 0.4 |
| Ischemic mean time (min) | 148 | 155 | 0.76 |
With regard to donors’ characteristics, most variables show no significant differences between the PGD group and the non-PGD group. The only possible predictor of PGD was donor’s previous cardiopulmonary resuscitation (CPR) (P=0.01). Among recipients’ characteristics, a redo operation was identified as a possible predictor of PGD (P=0.02). These findings are shown in Table 5. With regard to postoperative early survival, there were four (6.25%) deaths in the first 30 postoperative days. Among the PGD patients, there was only one (8.3%) death in the early postoperative period, and the other 11 patients (91.6% of all PGD patients) survived the first 30 postoperative days.
DISCUSSION
Heart transplantation is still the best therapy for patients with advanced heart failure who do not respond to conventional treatments[9]. Although survival after cardiac transplantation has been improving for the last two decades, the incidence and mortality from PGD is unclear from the literature but it is the most common cause of early mortality[8,10].
Some previous studies have shown that the incidence of PGD ranges from two to > 20%[11, 12, 13, 14]. This wide range in the reported incidence of PGD is largely due to inconsistent definitions of PGD across studies. Recently, a report from a consensus conference on PGD proposing standardized criteria for PGD was published[8]. Based on these standard criteria, the incidence rate of moderate and severe PGD at our institution was 18.7%, which is consistent with other recent studies[15]. Since we did not report the mild cases, the total incidence of PGD in our center would probably be > 25% of all adult’s transplants. This likely reflects the liberal criteria for PGD proposed by the ISHLT, that recognized that using this definition, a significant number of patients would be diagnosed with PGD[16]. In our study, we only reported the moderate and severe cases since it is not clear in the literature that mild PGD would somehow impact in morbidity and mortality after heart transplant[16].
The pathogenesis of PGD has not been clearly delineated, though its origin is believed to be multifactorial. In one recent study, a longer period of hospitalization and recipients hospitalized at time of transplantation were found to be predictive of PGD[17]. Our study identified that all PGD recipients were hospitalized at the time of transplantation.
Numerous clinical markers indicating a more severe pre-transplant condition of the recipient, including requirement for inotropic or mechanical support, have been identified as risk factors for PGD suggesting that placing a donor’s heart in a “hostile” recipient environment increases the risk for this complication[6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17].
The donors’ and recipients’ factors predictive of PGD also vary widely. In the present study, donor’s previous CPR e redo surgery were identified as possible predictive factors for the development of PGD. In others studies, high-dose inotrope use in the donor’s heart was identified as predictive factor[15], but we did not found statistical difference regarding this issue.
Although PGD was previously thought to impact survival primarily within a 30-day postoperative period, recent evidence suggests that PGD may affect survival for several months beyond the initial post-transplantation period[17]. In our study, the in-hospital/30-day mortality for patients with PGD was similar to that for those patients without PGD, that is 8.3% and 5.7%, respectively. A longer follow-up would better evaluate these findings.
Limitations
This study has several limitations, since it is a retrospective single-center study, with a small number of patients, and with a short 30-day follow-up. More studies should be done applying the ISHLT criteria, mainly in large and contemporary series. This will help to identify potential risk factors of PGD prior to heart transplantation. Also, future prospective studies should be delineated to better understand the pathophysiology of PGD, including possible predictive biomarkers.
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Article receive on Monday, March 7, 2022
Article accepted on Thursday, July 14, 2022
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