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. 2021 Jul 20;17(4):e274–e286. doi: 10.4244/EIJY21M05_01

Joint EAPCI/ACVC expert consensus document on percutaneous ventricular assist devices

Joint EAPCI/ACVC expert consensus document on pVADs

Alaide Chieffo 1,*, Dariusz Dudek 2, Christian Hassager 3, Alain Combes 4, Mario Gramegna 5, Sigrun Halvorsen 6, Kurt Huber 7, Vijay Kunadian 8, Jiri Maly 9, Jacob Møller 10, Federico Pappalardo 11, Giuseppe Tarantini 12, Guido Tavazzi 13, Holger Thiele 14, Christophe Vandenbriele 15,16, Nicolas M Van Mieghem 17, Pascal Vranckx 18, Nikos Werner 19, Susanna Price 20
PMCID: PMC9709772  PMID: 34057071

Abstract

There has been a significant increase in the use of short-term percutaneous ventricular assist devices (pVADs) as acute circulatory support in cardiogenic shock and to provide haemodynamic support during interventional procedures, including high-risk percutaneous coronary interventions. Although frequently considered together, pVADs differ in their haemodynamic effects, management, indications, insertion techniques, and monitoring requirements. This consensus document summarizes the views of an expert panel by the European Association of Percutaneous Cardiovascular Interventions (EAPCI) and the Association for Acute Cardiovascular Care (ACVC) and appraises the value of short-term pVAD. It reviews the pathophysiological context and possible indications for pVAD in different clinical settings and provides guidance regarding the management of pVAD based on existing evidence and best current practice.

Preamble

This consensus document summarizes the views of an expert panel endorsed by the European Association of Percutaneous Cardiovascular Interventions (EAPCI) and the Association for Acute Cardiovascular Care (ACVC) and appraises the importance of short-term percutaneous ventricular assist device (pVAD). It reviews the pathophysiological context, initiation, and indications for pVAD in different clinical settings and provides guidance regarding the management of pVAD based on existing evidence and best current practice.

Introduction

There has been a significant increase in the implementation of short-term percutaneous ventricular assist device (pVAD) in recent years, aiming to improve outcomes in cardiogenic shock (CS) and high-risk percutaneous coronary intervention (HR-PCI). These devices aim to reduce cardiac stroke work and myocardial oxygen demand whilst maintaining systemic and coronary perfusion.1,2 Although frequently considered interchangeable, the indications, management and evidence supporting the use of various types of pVAD differ significantly.3 This Joint European Association of Percutaneous Cardiovascular Interventions (EAPCI)/Association for Acute Cardiovascular Care (ACVC) expert consensus document reviews the pathophysiological context and indications for pVAD in different clinical settings and provides guidance regarding the clinical management of patients requiring pVAD.

Pathophysiology of shock and haemodynamic response to pVADs

Understanding the pathophysiological background of haemodynamic changes during disease and in response to support is vital for selection and monitoring, troubleshooting, and assessment of pVAD performance. Different options for pVAD are currently available (see Figure 2 for their possible selection based on left and right ventricular (RV) support; Supplementary material online, Table S1 for comparison among different pVAD). The phenotype and severity of CS additionally dictate device selection, including RV and/or left ventricular (LV) support, with/without oxygenation.4 The position and shape of ventricular pressure-volume (PV) loops are preload and afterload-dependent5 with normal PV loops bound by the end-systolic PV relationship (ESPVR) and enddiastolic PV relationship (EDPVR) (Figure 1). The ESPVR is relatively linear, with the slope Ees (end-systolic elastance) and the volume-axis intercept (Vo), shifting with changes in contractility. The EDPVR is non-linear and defines the diastolic properties of the ventricle. Afterload can additionally be depicted on the PV plane by the ‘effective arterial elastance’ (Ea) line. The Ea line starts on the volume axis at the end-diastolic volume intersecting the ESPVR at the ventricular end-systolic PV point of the PV loop (Figure 1A).6 Based on pulmonary artery catheter measurements, numerous haemodynamic parameters can be measured, allowing calculation of cardiac index, systemic vascular resistance, pulmonary vascular resistance, and pulmonary artery pulsatility index, all of which may contribute to device selection. Several different haemodynamic variables are associated with worse outcome in RV dysfunction which may also assist in device selection (Table 1).

Figure 1.

Figure 1

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Pressure-volume loops. (A) Normal PV-loop and PV-loop in acute cardiogenic shock, the slope (Ees) shifts with changes in contractility. (B) PV-loop in VA-ECMO supported cardiogenic shock. PV-loop becomes narrower and is associated with an increase in EDPVR. (C) PV-loop in a left ventricular microaxial flow pump supported configuration, resulting in loss of normal isovolumetric periods, reduced EDPVR and conversion of the typical PV-loop to a triangular shape. Ea: arterial elastance; EDPVR: end-diastolic pressure-volume relationship; EDPVR: end-diastolic pressure-volume relationship; EDV: end-diastolic volume; Ees: end-systolic elastance; ESPVR: end-systolic pressure-volume relationship; ESV: end-systolic volume

Table 1. Haemodynamic parameters assisting device selection.

Deteriorating shock (SCAI-C and D) – failure to respond to initial therapy. Consider mechanical support. Clinical signs of (relative) hypoperfusion: mottled, cold, clammy, volume overload, extensive rales, (non)-invasive ventilation, alteration in mental status
RV failure LV failure
Central venous pressure (CVP) ≥15 mmHg Systolic blood pressure (SBP) ≤90 mmHg or mean arterial pressure (MAP) <60 or >30 mmHg drop and inotropes/vasopressors
Pulmonary artery pulsatility index (PAPi) ≤1.857 Cardiac index (CI) <2.2 L/min/m2
Cardiac power output (CPO) <0.6 W8
Right atrial to pulmonary capillary wedge pressure ratio (RA/PCWP) ≥0.87 Left ventricular end-diastolic pressure (LVEDP) >15 mmHg
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Current models of left-sided pVAD comprise three different circuit configurations: right atrium to aorta (e.g. veno-arterial extracorporeal membrane oxygenation, VA-ECMO); left atrium to aorta (e.g. the TandemHeart, LivaNova London, UK); or left ventricle to aorta (Impella, Abiomed, Danvers, MA, USA; PulseCath iVAC2L, PulseCath BV, Amsterdam, The Netherlands; HeartMate PHPTM, St. Jude Medical/Abbott Vascular, St. Paul, MN, USA) (Figure 2).5,9 Peak flow rates range between 2.0 and 7.0 L/min, depending on the circuit and cannula(e) diameter(s). Devices may be used alone, in combination, and some allow/mandate concomitant use of an oxygenator within the circuit.

Figure 2.

Figure 2

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Different options for pVAD. Arrows indicate which part of the circulation is supported by the pVAD-modality. Devices in green can add blood oxygenation next to mechanical support. IABP: intra-aortic balloon pump; VA-ECMO: veno-arterial extracorporeal membrane oxygenation

The haemodynamic response to different pVADs is discussed in the Supplementary material online.

pVAD in high-risk PCI

The rationale and indications (Table 2) for pVAD in high-risk percutaneous coronary intervention (PCI) are described in the Supplementary material online. The aims of pVAD in the setting of HR-PCI are to initiate haemodynamic support in very high-risk patients before the intervention, to prevent profound hypotension/low cardiac output (CO) episodes, and allow sufficient time to achieve optimal and complete revascularization (Table 2).1,16

Table 2. Indication for pVAD-support in HR-PCI<sup>a</sup>.

Device Indication Evidence
IABP Should not be used BCIS-110
AFP May be considered in highly selected patients undergoing HR-PCI in case of acceptable femoral access (>6 mm diameter common femoral artery, no severe tortuosity) PROTECT II11 and cohort studies12,13,14,15
VA-ECMO Should not be used No data available
AFP: microaxial flow pump; HR-PCI: high-risk percutaneous coronary intervention; IABP: intra-aortic balloon pump; VA-ECMO: veno-arterial extracorporeal membrane oxygenation. aThere is no common definition of HR-PCI. PCIs might be considered as high risk in patients satisfying the followings clinical and/or anatomical high-risk criteria: clinical characteristics [stable/decompensated LVEF <35%, haemodynamic instability, diabetes mellitus, acute coronary syndromes (ACS), previous cardiac surgery, chronic kidney disease] angiographic characteristics (diffuse CAD, multivessel disease, unprotected left main coronary disease involving bifurcation, severe coronary total occlusion, severely calcified lesions needing rotational atherectomy, last patent conduit).2
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pVAD in high-risk myocardial infarction without cardiogenic shock

The rationale and indications (Table 3) for pVAD in high-risk acute myocardial infarction (AMI) without CS are described in the Supplementary material online. In high-risk AMI, unloading of the left ventricle can be initiated prior to reperfusion in order to rapidly reduce wall tension and potentially reduce myocardial damage.19,20 No data from randomized trials or long-term outcomes of a pre-emptive unloading strategy are available, however, the DTU (Door to Unload) trial is currently enrolling patients (Table 3).

Table 3. Indication for pVAD in HR-AMI without CS.

Device Indication Evidence
IABP It is not suggested CRISP-AMI and PAMI-II17,18
AFP Impella CP use seems feasible as a preventive unloading strategy; currently, there are no data showing an advantage for this approach Pre-clinical studies and pilot trial19,20,21,22
VA-ECMO Should not be used; increasing afterload in the setting of acute coronary ischaemia might be harmful No data available
AFP: microaxial flow pump; CS: cardiogenic shock; HR-AMI: high-risk acute myocardial infarction; IABP: intra-aortic balloon pump; VA-ECMO: veno-arterial extracorporeal membrane oxygenation
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Left-sided pVAD in cardiogenic shock

The rationale and indications (Table 4) for pVAD in CS are described in the Supplementary material online. Left-sided pVADs primarily aim to restore CO in patients with CS or in case of refractory cardiac arrest. There are, however, no randomized clinical trials addressing optimal timing or selection of pVAD in CS. Outside the cardiac arrest setting, usual practice is to initiate pVAD in CS as soon as possible, and before the onset of multi-organ failure. In patients with CS complicating AMI, registry data (uncontrolled and with inherent selection bias) suggest higher survival rates with device placement before revascularization than after in patients with AMI and CS.27 These findings have been supported by preclinical data.20 Recent data in a larger cohort of CS patients have challenged the concept of pre-emptive device placement.34 Until high-quality data are available, decisions regarding the timing of pVAD initiation (as with every pMCS), are therefore based on the risk/benefit assessment, including severity of shock and the burden of comorbidity, as evaluated by the multidisciplinary shock team.

Table 4. Indication for pVAD in CS.

Device Indication Evidence
IABP Routine use is not recommended23; may be used in patients with mechanical complications post-AMI or in non-AMI related shock IABP-SHOCK II24,25,26
AFP Impella CP may be used as a short-term therapy in CS,a stage C and D with potentially reversible underlying cause/transplant/VAD candidates Small randomized study and cohort studies4,27,28,29
VA-ECMO May be used as a short-term therapy in CS stage C, D, and E, particular in patients with combined respiratory insufficiency with potentially reversible underlying cause/transplant/VAD candidates
May be used for selected patients in refractory cardiac arrest		 Prospective and retrospective cohort studies30,31,32
AFP: microaxial flow pump; AMI: acute myocardial infarction; CS: cardiogenic shock; IABP: intra-aortic balloon pump; VAD: ventricular assist device; VA-ECMO: veno-arterial extracorporeal membrane oxygenation. aAccording to SCAI CS classification.33
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Right-sided pVAD in cardiogenic shock

The rationale and indications (Table 5) for RV-pVAD in CS are described in the Supplementary material online. No clinical trials exist that address the optimal timing of RV-pVAD placement in patients with acute RV failure. Furthermore, there are no parameters that have been demonstrated to predict RV failure or requirement for RV-pVAD after initiation of LV-pVAD. The decision to initiate RV-pVAD should be based on decisions made by the multidisciplinary shock team.

Table 5. Indications for right pVAD in CS.

Device Indication Evidence
IABP It is not suggested in isolated RV failure None
Percutaneous right-sided support Impella RP may be used in patients with CS predominantly due to RV failure
Protek Duo may be used in those requiring isolated right heart support±oxygenation		 Small cohort studies35,36,37,38
VA-ECMO May be used in case of severe haemodynamic compromise especially when combined LV failure and/or respiratory insufficiency, in CS stage C, D, and E in patients with potentially reversible underlying cause/transplant/VAD candidates Case series39,40,41
AFP: microaxial flow pump; CS: cardiogenic shock; IABP: intra-aortic balloon pump; LV: left ventricle; RV: right ventricle; VAD: ventricular assist device; VA-ECMO: veno-arterial extracorporeal membrane oxygenation
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Biventricular pVAD in cardiogenic shock

The rationale and indications (Table 6) for biventricular pVAD in CS are described in the Supplementary material online. Acute, primary biventricular support (vs. delayed, secondary) should be implemented before the onset of multiorgan failure in selected patients as a strategy to buy time for recovery or bridge to other therapies.

Table 6. Indications for percutaneous biventricular assist devices in CS.

Device Indication Evidence
VA-ECMO May be used in case of:
– Combined left and right ventricular failure
– Combined left ventricular and ventilation/oxygenation failure
– Combined ventilation/oxygenation and right ventricular failure
– Refractory cardiac arrest		 Registry data, case reports42,43,44
ECPella VA-ECMO and left ventricular unloading Registry data, case reports45,46,47
BiPella May be used in right and left ventricular failure without pulmonary failure Registry data, case reports48,49
CS: cardiogenic shock; VA-ECMO: veno-arterial extracorporeal membrane oxygenation.
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Clinical monitoring and ongoing management of patients requiring pVAD

The monitoring of cardiac function and tissue perfusion is pivotal to optimize treatment and recognize potential complications of pVAD. This is described in Table 7 and the Supplementary material online.

Table 7. pVAD monitoring.

Variable Advantages Limitations
Echocardiography
Ventricular size End-diastolic volume (EDV) Difficult to assess for RV, may vary depending on the level of support
Ejection fraction
LV velocity time integral
Pre ejection and total ejection time		 Global assessment of LV function
– Estimation of LV stroke volume/CO
– Integrated with LVEF allow the assessment of Ees		 – Load and heart rate dependent
– Less indicative in case of asynchrony
– Aortic stenosis
– Angle dependent
– Not validated in cardiogenic shock
MAPSE/TAPSE Early and sensitive for systolic function Annular abnormalities
Tissue Doppler velocity; strain/strain rate Early and sensitive for systolic and diastolic function Require high skill and further validation
Valvular abnormalities – Indirect evaluation of ventricular function (dP/dT; TAPSE/sPAP)
– Ventricular offloading (MR) Dependent by alignment
– Right side pressures (sPAP, dPAP)		 – TOE is more sensitive
– Dependent by alignment
Haemodynamic and respiratory
Pulse-oximetry Continuous monitoring of peripheral oxygen saturation – To be placed on the right arm in ECMO patients
– Dependent on skin conditions
– Arterial flow pulsatility
Invasive blood pressure monitoring – Systemic blood pressure
– Oxygenation/metabolic profile (pH, paO2, paCO2, base excess, meta-haemoglobin)
– Lactate
– Haemoglobin		 – Right radial artery is more representative of coronary and upper body oxygenation
– To be taken before full regimen anticoagulation
Pulmonary artery catheter – Pulmonary (sPAP, dPAP, mPAP) and right atrial pressures
– SVR/PVR
– Left ventricular capillary wedge pressure
– CO/CI
– PAPi
– CPO
– SvO2
– Pa-vCO2 		– To be taken prior of full regimen anticoagulation
– SvO2 inaccurate in VA-ECMO and TandemHeart patients due to the venous component of the blood coming from the native pulmonary circulation
Conductance catheter V-A coupling Not validated in cardiogenic shock
Non-invasive monitoring
Near-infrared spectroscopy (NIRS) – Easy values to interpret
– Regional oxyhaemoglobin saturation (rSO2)
– Perfusion of the distal limb		 – No absolute numbers, but the trend of the values
– Individual Hb level and variations in cerebral venous/arterial blood ratio
– Needs confirmation with ultrasound
Optical nerve shear diameter Indirect evaluation of intracranial pressure Needs validation in this setting
Coagulation monitoring
Activated clotting time – Easy and bedside
– Widely available and sensitive		 High variability and non-specificity for heparin
aPTT – Easy and bedside
– Widely available and sensitive		 High variability and non-specificity for heparin
Anti-Xa Sensitive to heparin function Not widely available
Cardiac-specific markers
BNP, NT-pro-BNP Ventricle overload – No absolute numbers, but the trend of the values
– No specific validation in this setting
hs-TnI Rise/fall sensitive for myocardial ischaemia – No absolute numbers, but the trend of the values
– No specific validation in this setting
aPTT: activated partial thromboplastin time; BNP: B-type natriuretic peptide; CI: cardiac index; CO: cardiac output; CPO: cardiac power output; CRP: C-reactive protein; dPAP: diastolic pulmonary artery pressure; Ees: end-systolic elastance; hs-TnI: high-sensitivity troponin I; LV: left ventricle; LVEF: left ventricular ejection fraction; MAPSE: mitral annular plane systolic excursion; mPAP: mean pulmonary artery pressure; MR: mitral regurgitation; PAPi: pulmonary artery pulsatility index; PVR: pulmonary vascular resistance; RV: right ventricle; sPAP: systolic pulmonary artery pressure; SVR: systolic vascular resistance; TAPSE: tricuspid annular plane systolic excursion; TOE: transoesophageal echocardiography; V-A coupling: ventricular-arterial coupling; VA-ECMO: veno-arterial extracorporeal membrane oxygenation
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Complications and their management

Complications associated with pVAD are potentially serious, life-threatening and may be related to the device itself, its insertion or from device-induced alteration of homeostasis or organ function, or anticoagulation (Figure 3). The most frequent complication is bleeding (related to vascular cannulation, full anticoagulation, or device-induced alteration in the coagulation pathways).50,51,52,53,54 Other complications include infection,55,56 haemolysis,57,58 limb ischaemia,59 device failure, and central nervous system haemorrhage or infarction.60,61 The incidence of heparin-induced thrombocytopenia is relatively low (0.36%, n=21/5797) in VA-ECMO and does not impact survival.62

Figure 3.

Figure 3

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Complications associated with pVAD. Most frequent complications associated with pVADs depending on timepoint of implantation and weaning. *Indicates problems like bleeding, leg ischaemia, dissection or pseudoaneurysm; **Indicates problems as Harlequin-syndrome, cannula dislocation, afterload and/or preload mismatch. ICU: intensive care unit; SIRS: systemic inflammatory response syndrome

SPECIFIC, DEVICE-RELATED COMPLICATIONS AND THEIR MANAGEMENT

Impella devices are associated with the highest incidence of haemolysis among pVAD (5-10% in registry data).57,58 Accurate placement, and reduction of pump speed may decrease haemolysis and associated acute kidney injury. In a retrospective analysis of patients with AMI-related CS, the use of Impella was associated with more frequent bleeding (10.4% vs 1.7%, P<0.01), sepsis (38.2% vs. 17.4%, P<0.01) and peripheral vascular complications (9.6% vs. 3.5%, P=0.05) compared with matched patients from the IABP-SHOCK II trial supported with intra-aortic balloon pump (IABP).28 In a propensity-matched registry-based retrospective cohort study of patients with AMI complicated by CS, Impella was associated with more major bleeding (31.3% vs. 16.0%, P<0.001) compared with matched patients supported with IABP.34 In another retrospective analysis of 48306 patients, undergoing PCI with pVAD, when analysed by time-periods or at hospital/patient-level, Impella use was associated with: bleeding [odds ratio (OR)=1.10] and stroke (OR=1.34), although a similar, non-significant result was observed for acute kidney injury (OR=1.08).63

Specific complications of the TandemHeart include air embolism and cardiac perforation, tamponade, and atrial septal defect from transseptal cannulation.64 Drainage cannula displacement in the right atrium may cause massive shunting of deoxygenated blood to the arterial circulation.

VA-ECMO provides retrograde blood flow in the aorta and increases LV afterload and left ventricular end-diastolic pressure, that may induce pulmonary oedema and potentially myocardial ischaemia.65,66 Combining VA-ECMO and IABP (to unload the left ventricle) was associated with lower mortality in a meta-analysis based on observational data.45 The addition of an Impella to VA-ECMO decompresses the left ventricle may also improve outcome.45,67,68,69 Direct venting of left-cardiac chambers or percutaneous balloon atrial septostomy are other strategies used to offload the left ventricle in VA-ECMO. Since retrograde ECMO flow competes with the native heart ejection, in case of lung failure, deoxygenated blood may be directed to the upper part of the body resulting in heart and brain hypoxia. This situation is termed differential hypoxia, the North-South or Harlequin Syndrome.70,71,72 Veno-arterial-venous ECMO (which splits the reinfused blood by a Y-connector into an arterial and a venous cannula, additionally returning oxygenated blood to the right atrium) can provide circulatory and adequate pulmonary support in this setting.72 Veno-veno-arterial ECMO (VV-ECMO) configuration (completely offloading the right heart and reducing LV ejection) is another option. The incidence of major vascular complications with VA-ECMO can exceed 15% with significant impact on patient prognosis.73 Insertion of a distal perfusion cannula into the superficial femoral artery, positioned using contrast-enhanced Doppler ultrasound or invasive angiography, may prevent limb ischaemia.74 Ultrasound-guided percutaneous cannulation is the preferred option in VA-ECMO, and associated with less local infection (16.5% vs. 27.8%, P=0.001), similar rates of limb ischaemia (8.6% vs. 12.4%, P=0.3), sensory-motor complications (2.6% vs. 2.3%, P=0.8) and improved 30-day survival (63.8% vs. 56.3%, P=0.03) compared to surgical cannulation in a propensity-matched study including 532 patients receiving VA-ECMO.75

Antithrombotic pharmacology: anticoagulation and antiplatelet therapy

Up to 80% of patients on VA-ECMO suffer from major bleeding requiring transfusion and up to 16% develop intracranial haemorrhage.76 The precarious balance between bleeding and thrombotic complications, is a significant challenge and strongly influences pVAD-induced morbidity and mortality.51,77,78 A well-balanced antithrombotic strategy is mandatory.

Anticoagulation with unfractionated heparin (UFH) is the standard of care due to its short half-life, rapid on- and offset, low cost and ready availability.79 Other anticoagulation strategies (bivalirudin, argatroban) have been reported, especially in the context of heparin-induced thrombocytopenia.80,81 Due to their long half-life and renal excretion, the use of non-vitamin-K-oral-anticoagulants and low-molecular-weight heparins should be avoided.82 Monitoring UFH in patients on pVAD is challenging. Although activated clotting time (ACT)-guided monitoring is common it should be avoided due to its high variability, the non-specificity for heparin and the lack of widespread availability of ACT monitoring outside the catheterization lab.79,83 The activated-partial-thromboplastin-time (aPTT, most frequently used) and/or anti-Xa assays (the gold standard although not widely available) are preferred.84 In patients with sepsis, disseminated intravascular coagulation, liver failure or unexplained aPTT-prolongation, anti-Xa-testing should be used. The use of thromboelastography-guided UFH-monitoring has been evaluated, aiming to take platelet interactions and fibrinolysis into account, but further validation is pending.85 Antithrombin-monitoring should be considered when heparin-resistance is suspected.86

Randomized studies for specific heparin dose-regimens for anticoagulation are lacking. The Impella anticoagulation-guidelines favour therapeutic anticoagulation levels in all non-bleeding patients on pVAD.87 Nevertheless, a more individualized approach, well-balanced with the risk of bleeding, is suggested.88 Supplementary material online, Table S3 describes various devices with recommended antithrombotic strategies. pVAD-patients with underlying atrial fibrillation, mechanical valves or fresh (venous or arterial) thrombi should additionally receive therapeutic anticoagulation in the absence of major bleeding. No anticoagulation in (left-sided) pVAD-supported patients can be considered in major, life-threatening bleeding but the high risk of acute circuit failure and/or systemic embolization/thrombosis must be taken into consideration. An important number of pVAD-supported patients will have an additional indication for dual antiplatelet therapy because of PCI with stent implantation. Here, UFH should be combined with low dose aspirin plus clopidogrel (triple antithrombotic therapy) or with clopidogrel alone (dual antithrombotic therapy) depending on the individual bleeding risk of the patient. Prasugrel and ticagrelor are not recommended in a triple therapy strategy due to their increased bleeding hazards when compared with clopidogrel.89

In addition to determining the optimal UFH-dose, optimizing the platelet count and fibrinogen levels, and any bleeding source control is mandatory (surgical control, topic tranexamic, and/or adrenaline application in the cannula or mucosal bleeds or circuit change in case of consumption coagulopathy).

Although bleeding and thrombotic complications are the most frequent cause of morbidity and mortality in pVAD-supported patients, evidence from randomized clinical trials is scarce. Large, prospective multicentre trials are urgently needed to investigate the optimal anticoagulation management strategies during pVAD support.

Pharmacological support

Catecholamines are a standard part of the armamentarium of pVAD-supported patients although few data on safety and outcome are available to recommend inotrope/vasopressor selection and use.90 In CS, norepinephrine is the first-line vasopressor. Although vasopressin significantly increases mean arterial pressure (MAP), it has a lesser effect on cardiac index compared to norepinephrine.91,92 Its theoretical advantage at low dose (pulmonary vasoconstriction) deserves further investigation. MAP should be titrated according to the clinical scenario—maintaining organ perfusion pressure, whilst avoiding excessive increases in after-load. Following pVAD initiation, pressor support should be reduced to the lowest dose possible, and relative hypotension may/may not be tolerated, depending on other organ involvement (e.g. cerebral perfusion pressure in the context of post-cardiac arrest management).

Inotropic support may be required to enhance ventricular contractility but may alter ventricular loading and precipitate arrhythmia. In the case of univentricular pVAD, inotropy may be required to maintain adequate function of the non-supported ventricle. In CS, dobutamine is the inotrope of choice in patients93 as epinephrine has shown to be associated with a worse metabolic profile and patient outcomes.94,95,96

A randomized trial of norepinephrine versus epinephrine in patients with AMI-related CS demonstrated a higher incidence of lactateacidosis, tachycardia and refractory CS in the epinephrine-group, although many received concomitant dobutamine.96 In case of RV failure, phosphodiesterase-type-3 inhibitors (i.e. milrinone) may be preferred for their inodilators effects, despite lacking randomized trials.97 The long-acting calcium-sensitizer levosimendan (0.05-0.1 μg/kg/min) may be used given its inotropic and vasodilatory effect. However, hypotension and supraventricular arrhythmias may occur.98 Although levosimendan has shown beneficial haemodynamic effects during pVAD-weaning, further validation is needed.

Weaning from pVAD

The potential for weaning from pVAD should be evaluated daily from 24 to 48 h after the initiation of support. Several clinical features may predict the likely duration of pVAD support and likelihood of cardiac recovery including age, underlying pathology and presence/absence of pulmonary hypertension. Although the patient’s condition/pVAD complications may demand accelerated weaning/device explantation, the cornerstones guiding elective weaning include clinical, biochemical, echocardiographic parameters and right heart catheterization, depending on the clinical context, and all indicating resolution of cardiac/non-cardiac pathophysiological derangement.

Measures of ‘off-pump’ LVEF, end-diastolic diameter, pulmonary capillary wedge pressure (PCWP), together with tissue Doppler and strain imaging on echocardiography are widely used to predict successful long-term pVAD explantation.99 Similar parameters have been proposed to predict weaning from VA-ECMO. Here, in stable patients (low dose vasopressor ± inotropic support without pulmonary congestion/hypoxemia or other significant uncontrolled medical conditions) echocardiographic signs of improved LV function (LVEF >20-25%, velocity-time integral >10 cm and lateral mitral annulus peak systolic velocity >6 cm/s) during reduced flow (1-2 L/min) with no significant fall in MAP predict weaning success.100,101 There are many proposed VA-ECMO weaning algorithms, but none has been shown to be superior in randomized studies. In case of cardiorespiratory failure, where cardiac function has recovered, but the lungs remain severely impaired, downgrading to VV-ECMO may be an option. If the right ventricle is also significantly compromised, but the left ventricle has recovered, an oxy-right ventricular assist device may be an option.

The literature on weaning from other pVAD is limited, with recommendations/weaning algorithms based on expert consensus (Figure 4). Principles are, however, similar to VA-ECMO; the patient must be stable with a pulsatile arterial waveform (MAP >60-65 mmHg) on low-dose vasopressor ± inotropic support without pulmonary congestion/other conditions that may preclude successful weaning including arrhythmia, acid-base/metabolic disturbance, and mechanical complications. In left-sided support, PCWP should be near normal (preferably <15 mmHg) in a patient without former heart failure, before weaning is considered. There are no validated echocardiographic cut-off values that predict successful weaning in either left- or right-sided pVAD.

Figure 4.

Figure 4

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Algorithm for pVAD weaning in cardiogenic shock. MCS: mechanical circulatory support; PCWP: pulmonary capillary wedge pressure

Where a weaning trial is unsuccessful, it is vital to identify and address the cause of weaning failure. When the patient continues to fail to wean, consideration should be made regarding the potential options, including a longer run on the existing device/modification of support to the least injurious to the patient (if cardiac recovery is anticipated), upgrade to more durable circulatory support, or withdrawal of support.59,102,103,104,105,106,107,108,109,110,111,112,113,114,115,116,117

Futility

Ceilings of care, and determining futility are important, but challenging to set in the context of patients referred for pVAD, especially with the absence strong predictors of outcome at the time of onset of CS, and the need to proceed quickly to pVAD initiation. These challenges are discussed in the Supplementary material online.

Future directions and conclusions

The rapid expansion of pVAD use in the settings of CS and HR-PCI without sufficient evidence from large-scale randomized trials is problematic. Currently, this widespread adoption is based on small series and registries, including industry-sponsored studies alone. Importantly, in particular in CS, the rates of device-related complications remain high. Consequently, there is an urgent need for adequately powered randomized clinical trials and large national/multinational registries to better define those patients who may benefit from pVAD, and how best to evaluate, monitor and manage every aspect of their care, especially in the setting of CS.

GAPS IN KNOWLEDGE AND FUTURE STUDIES

(1) Pathophysiological studies evaluating ventricular unloading in high-risk myocardial infarction and CS.

(2) Randomized clinical trials demonstrating the benefit of pVAD over standard of care in high-risk PCI and CS.

(3) Randomized clinical trials demonstrating the benefit paradigm shift from door to balloon to door to unload.

(4) Large prospective national and international registries evaluating the outcomes of pVAD in a real-world population.

(5) Algorithms and protocols to better define patients population and timing for pVAD.

(6) Protocols and proper education of physicians and healthcare providers to reduce device-related complications.

Supplementary data

Supplementary File
Supplementary Table 1

Comparison among different devices.

Supplementary Table 2

Randomized Clinical Trials on pVAD.

Supplementary Table 3

Proposed Antithrombotic Strategy in pVAD.

Acknowledgments

Conflict of interest statement

A. Chieffo received consulting fees/honoraria from Abiomed, Abbott Vascular, Cardinal Health, Biosensor, Magenta Medical. D. Dudek has served on the Scientific Advisory Board of Impella CP. A. Combes received grants and personal fees from Getinge. J. E. Møller received grants and personal fees from Abiomed and personal fees from Orion Pharma and Novartis. F. Pappalardo received personal fees from Abiomed. G. Tarantini received personal fees from Abiomed and GADA. G. Tavazzi received personal fees from GE Healthcare. N. van Mieghem received grants and personal fees from Abbott Vascular, Medtronic, Boston Scientific, PulseCath BV. N. Werner received personal fees and non-financial support from Abiomed. None of the other authors has relevant conflicts of interest to disclose.

Contributor Information

Alaide Chieffo, Interventional Cardiology Unit San Raffaele Scientific Institute - Milan, Italy.

Dariusz Dudek, Institute of Cardiology, Jagiellonian University Medical College, Krakow, Poland.

Christian Hassager, Department of Cardiology, Copenhagen University Hospital, Rigshospitalet Blegdamsvej 9, 2100 Copenhagen, Denmark.

Alain Combes, Sorbonne Université, INSERM, UMRS_1166-ICAN, Institute of Cardiometabolism and Nutrition, and Department of Medical Intensive Care Unit, Cardiology Institute, Pitié Salpêtrière Hospital, Assistance Publique-Hôpitaux de Paris (AP-HP), Sorbonne University Medical School, F-75013 Paris, France.

Mario Gramegna, Cardiac Intensive Care Unit, IRCCS San Raffaele Scientific Institute, Via Olgettina 60, 20132 Milan, Italy.

Sigrun Halvorsen, Department of Cardiology, Oslo University Hospital Ullevål and University of Oslo, Kirkeveien 166, 0450 Oslo, Norway.

Kurt Huber, 3rd Department of Medicine, Cardiology and Intensive Care Medicine, Wilhelminenhospital, Montleartstrasse 37, A-1160 Vienna, and Sigmund Freud University, Medical School, Freudplatz 3, A-1020 Vienna, Austria.

Vijay Kunadian, Translational and Clinical Research Institute, Faculty of Medical Sciences, Newcastle University and Cardiothoracic Centre, Freeman Hospital, Newcastle upon Tyne NHS Foundation Trust, Newcastle upon Tyne, NE2 4HH, United Kingdom.

Jiri Maly, Cardiac Center, IKEM Prague, Videnska 1958/9, 14021 Prague 4, Czech Republic.

Jacob Møller, Department of Cardiology, Copenhagen University Hospital, Blegdamsvej 9, 2100 Copenhagen, Denmark.

Federico Pappalardo, Department of Anesthesia and Intensive Care, IRCCS ISMETT, UPMC Italy, Via Ernesto Triconi 5, 94100 Palermo, Italy.

Giuseppe Tarantini, Interventional Cardiology Unit, Department of Cardiac, Thoracic, Vascular Sciences and Public Health, University of Padova, Via Giustiniani 2, 35128 Padua, Italy.

Guido Tavazzi, Department of Clinical-Surgical, Diagnostic and Pediatric Sciences, University of Pavia, Unit of Anaesthesia and Intensive Care, Fondazione Policlinico San Matteo Hospital IRCCS, Piazzale Golgi 19, 27100 Pavia, Italy.

Holger Thiele, Department of Internal Medicine/Cardiology, Heart Center Leipzig at University of Leipzig and Leipzig Heart Institute, Struempellstr 30, 04289 Leipzig, Germany.

Christophe Vandenbriele, Department of Cardiovascular Diseases, University Hospitals Leuven, Herestraat 49, 3000 Leuven, Belgium; Department of Adult Intensive Care Unit, Royal Brompton and Harefield NHS Foundation Trust, Royal Brompton Hospital, Sydney Street, SW3 6NP London, UK.

Nicolas M. Van Mieghem, Department of Interventional Cardiology, Erasmus University Medical Centre, Dr Molewaterplein 40, 3015 GD Rotterdam, the Netherlands

Pascal Vranckx, Department of Cardiology and Critical Care Medicine, Jessa Ziekenhuis, Stadsomvaart 11, 3500 Hasselt, Belgium, and Faculty of Medicine and Life Sciences University of Hasselt Martelarenplein 42, 3500 Hasselt, Belgium.

Nikos Werner, Heart Center Trier,Department of Internal Medicine III, Krankenhaus der Barmherzigen Brüder, Nordallee 1, 54292 Trier, Germany.

Susanna Price, Department of Adult Intensive Care Unit, Royal Brompton and Harefield NHS Foundation Trust, Royal Brompton Hospital, Sydney Street, SW3 6NP London, UK.

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Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

Supplementary File
EIJY21M05_01_Chieffo_SD.pdf (1.2MB, pdf)
Supplementary Table 1

Comparison among different devices.

EIJY21M05_01_Chieffo_SD.pdf (1.2MB, pdf)
Supplementary Table 2

Randomized Clinical Trials on pVAD.

EIJY21M05_01_Chieffo_SD.pdf (1.2MB, pdf)
Supplementary Table 3

Proposed Antithrombotic Strategy in pVAD.

EIJY21M05_01_Chieffo_SD.pdf (1.2MB, pdf)

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