Veno-arterial extracorporeal membrane oxygenation (VA-ECMO) provides effective hemodynamic support in cardiogenic shock, but in some cases may be complicated by left ventricular (LV) distension and pulmonary edema. The Impella, a catheter-mounted microaxial pump has been used to unload the LV. Recent studies have compared the clinical outcomes of VA-ECMO to the combination of Impella and VA-ECMO. The purpose of this review is threefold: firstly, to discuss the physiological effects of Impella support in addition to VA-ECMO, secondly to review published studies on the outcome of this combined support, and thirdly to provide a practical overview of the approach to combining Impella and VA-ECMO.
Left ventricular distension is a recognized complication of VA-ECMO support.
Impella is an effective venting or decompression strategy during VA-ECMO support.
The hemodynamic effects of Impella differ from other left ventricular venting strategies.
Introduction
Peripheral VA-ECMO or extracorporeal life support (ECLS) provides effective hemodynamic support in cardiogenic shock. However, VA-ECMO modifies the normal hemodynamics in the lung and left ventricle, with consequent increase in left ventricular (LV) end-diastolic pressure, LV distension, and pulmonary edema in some patients. A number of LV ‘venting’ or ‘decompression’ strategies have been used with varying degrees of success to mitigate this increase in LV end-diastolic pressure (Table 1). The insertion of a left-sided Impella (2.5, CP or 5.0) is one such strategy.
Table 1
Left ventricular venting strategies
Intra-aortic balloon pump
Left ventricular assist device (e.g.,: Impella 2.5, CP or 5.0)
(Surgical) Left ventricular drainage
Retrograde trans-aortic catheter drainage
(Trans-septal) left atrial drainage
Pulmonary artery catheter drainage
Pulmonary venous drainage
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The Impella class of devices consists of catheter-mounted microaxial pumps that function as an Archimedes-screw pump, aspirating blood from the left ventricle and expelling into the aorta. The concomitant use of Impella with VA-ECMO was first described by Vlasselaers and colleagues in 2006 in a 13-year old boy [1]. Since that case report, this Impella-VA-ECMO combination has been increasingly deployed in the management of cardiogenic shock [2, 3]. The comparative physiology and outcomes of Impella versus VA-ECMO in patients with cardiogenic shock, the use of Impella in high-risk coronary intervention, or in the treatment of acute myocardial infarction have been extensively reviewed [4‐8]. This review will focus on (i) the physiology of combined Impella-VA-ECMO support, (ii) the clinical outcomes with this combines mechanical circulatory support strategy, and (iii) the practical approach to the use of Impella-VA-ECMO. This article is based on previously conducted studies and does not contain any studies with human participants or animals performed by any of the authors.
The Physiology of LV Distension on VA-ECMO
The circulatory physiology of VA-ECMO has been reviewed previously [9]. VA-ECMO generates a non-physiological circulation that has different effects on the right (RV) and LV. Firstly, the VA-ECMO circuit competes with the RV for preload. Higher VA-ECMO flow deprives the RV of preload and reduces RV output and pulmonary blood flow. Clinically, the latter may be evidenced by the reduction in pulmonary artery pulse pressure and partial pressure of end-tidal carbon dioxide levels unless ventilation is significantly decreased.
Secondly, blood is delivered retrogradely into the aorta (typically via a return cannula in the femoral artery), which pressurizes the systemic circulation and increases hemodynamic load on the LV. In order to overcome the increased afterload to maintain the ejection, the LV must have sufficient intrinsic contractility or, if unable to attain sufficient contractility following initiation of VA-ECMO, must recruit preload.
A number of mechanisms may conspire to limit LV contractile response under VA-ECMO support: (i) The ventricle in end-stage heart failure may intrinsically only have limited contractile reserve due to alterations in beta1-adrenoreceptor signaling and intracellular calcium handling [10]; (ii) LV contractile function may be compromised by high VA-ECMO flow [11, 12], possibly due to LV distension and impaired myocardial blood flow; (iii) in the case of respiratory failure associated with persistent LV ejection, flow of poorly oxygenated blood to the coronary circulation may worsen myocardial ischemia (and hypoperfusion of the upper body—so-called differential hypoxemia, north–south syndrome, or harlequin syndrome) and contractile dysfunction; and (iv) be in a state of myocardial stunning due to prolonged cardiac arrest, even in the presence of adequate cardiopulmonary resuscitation.
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Other factors can contribute to LV distention other than inadequate LV contractility. Since the aorta is pressurized, pre-existing aortic regurgitation may be exacerbated by VA-ECMO. In addition, continuous filling of the LV due to bronchial and, to a lesser extent, Thebesian blood flow contribute to LV distension.
At a given level of contractile function, the heart must recruit preload (increase end-diastolic volume) to maintain stroke volume in the face of increased afterload (Fig. 1a) [13]. However, there are limits to which LV preload can increase. The heart is constrained by an intrinsic limit in recruitable preload reserve. In addition, due to the non-linear diastolic pressure–volume relation, a small increase in LV diastolic volume in the setting of an already dilated LV, results in a disproportionately greater increase in end-diastolic pressure (and risk of pulmonary edema). Exhaustion of preload reserve and limited contractile reserve renders the failing heart exquisitely sensitive to increases in afterload—a phenomenon that underpins the acute hemodynamic effects of vasodilators in heart failure with reduced ejection fraction; and the failure of LV ejection in response to acute increase in afterload associated with VA-ECMO (Fig. 1b).
Fig. 1
a In the face of increased afterload, at constant level of contractility, the LV must increase diastolic volume (1) to recruit preload and maintain stroke volume (2). b Further increase in afterload (3), when the limit of preload reserve is reached (4) will lead to reduction in stroke volume, evident as narrowing of the width of the pressure–volume loop (5)
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The failure to sufficiently increase contractility or recruit preload to meet the increased afterload results in reduced LV stroke volume and diminished arterial pulse pressure, with concomitant increase in mean arterial blood pressure on VA-ECMO support. The simultaneous increase in LV volume and reduction in stroke volume reduces myocardial efficiency (the ratio of stroke work to myocardial oxygen consumption, the latter is approximated by the pressure–volume area) [14].
In this regard, VA-ECMO maintains pressure and blood flow in the systemic circulation, in contrast to the reduced pulmonary blood flow, effectively uncoupling the two circulations.
The Physiology of Impella and VA-ECMO
Case reports and case series have described significant reductions in filling pressures, LV distension, and consequent improvement in cardiogenic pulmonary edema with Impella when deployed in combination with VA-ECMO in cardiogenic shock [15, 16]. Cheng et al. [17] reported almost halving of pulmonary artery wedge pressure and reductions in central venous pressure and LV end-diastolic diameter (7.8 ± 1.4 to 6.2 ± 0.8 cm, p = 0.001) in five patients with cardiogenic shock and LV distension related to VA-ECMO support (average Impella flow of 2.0 ± 0.5 l/min). These clinical observations are consistent with the physiological unloading effects of the Impella.
However, the unloading effect of Impella differs from other ‘venting’ strategies, such as pulmonary venous, pulmonary arterial, or trans-atrial septal drainage [18]. The latter strategies reduce LV end-diastolic volume and pressure (preload), thereby unloading the LV and diminish LV stroke volume. The reduction in LV stoke volume is directly related to drainage rate and may result in the loss of LV ejection (Fig. 2a). Hence, pulmonary venous, pulmonary arterial or trans-atrial septal drainage can reduce antegrade blood flow from the LV to the aorta. When these alternate strategies are used, special attention should be given to ensure that the aortic valve is opening to avoid stasis and thrombus formation in the LV and proximal aorta.
Fig. 2
a Pulmonary arterial, venous, or left atrial vent diminish LV volume (preload) with consequent reduction in LV end-diastolic pressure (1). Reduction in LV preload at unchanged contractility will reduce LV systolic pressure (2). The LV will fail to eject if LV systolic pressure fails to exceed aortic pressure (horizontal line). b The Impella continuously drains from the LV, reducing LV volume and converts the pressure–volume loop into a triangular shape due to the loss of isovolumic phases (3). Left ventricular systolic pressure drops below aortic pressure and the LV fails to eject (4), but the Impella maintains LV output
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In contrast, the Impella continuously drains the LV and delivers the blood to the proximal aorta, thus maintaining flow from LV to the aorta even in the absence of LV ejection and a closed aortic valve. The continuous drainage of the LV abolishes the isovolumic phases, resulting in a triangular-shaped pressure–volume loop, reducing LV work, and unloading the LV (Fig. 2b). Furthermore, unlike left atrial or ventricular ‘vent’ drainage, which reduces LV ejection, the Impella contributes to total flow.
Clinical Outcomes of Combined Impella and VA-ECMO Support
There are no prospective randomized trials that have compared venting strategies in VA-ECMO. Nevertheless, there are a number of (mostly single-center) retrospective registry studies that have evaluated the strategy of Impella and VA-ECMO in patients with cardiogenic shock (Table 2). Some reports have also inferred that this combination of Impella and VA-ECMO may facilitate LV recovery [19‐21]. There are inherent limitations with these reports with considerable risk of biases—small number of patients, the selection of patients, decision to vent, the use of Impella instead of other venting strategies, and management strategies of patients on VA-ECMO.
Table 2
Outcome of combined Impella and VA ECMO support in cardiogenic shock
Author
Description
Results
Tepper 2017
Single-center study
30-day survival (p = 0.42):
23 patients with Impella + VA ECMO compared to 22 VA ECMO + surgical vent
Impella + VA ECMO 43%
VA ECMO + surgical vent 32%
Pappalardo 2017
Multi-center study
Hospital mortality:
34 Impella + VA ECMO compared to 123 VA ECMO
Impella + VA ECMO 47% vs. VA ECMO 80% (p < 0.001)
Successful bridging to recovery or next therapy:
Propensity matched cohort
Impella + VA ECMO 68% vs. VA ECMO 28% (p < 0.001)
21 Impella + VA ECMO compared to 42 VA ECMO
Propensity matched:
Impella + VA ECMO 48% vs. VA ECMO 74% (p = 0.04)
Higher rates of hemolysis (76 vs. 33%, p = 0.004) and CVVH (48 vs. 19%, p = 0.02) in the Impella + VA ECMO group
Colombier 2018
Single-center study
Median time to Impella 84 (24–186) h
31 patients with refractory shock despite VA ECMO and IABP
Median Impella support 8 (5–10) days
30-day survival 53%
Median age 53 years, 74% males
HFREF independent risk factor for 30-day mortality
12 patients (22%) upgraded from Impella CP to Impella 5.0
Median duration of VA ECMO support: 6 (3–10) days
Median duration of Impella support: 6 (3–12) days
12 patients bridged to durable LVAD, no patients bridged to transplantation
30-day mortality 64%
Patel 2019
Single-center study
Surgical venting in 21 (58%) of VA ECMO patients
30 patients with Impella + VA ECMO compared to 36 patients with VA ECMO
30-day survival: Impella + VA ECMO 43% vs. VA ECMO 22% (p = 0.02)
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In a propensity matching study, Pappalardo et al. [22] compared Impella plus VA-ECMO to VA-ECMO alone in patients with cardiogenic shock of different etiologies. Overall in-hospital mortality is high (73%), and the mortality in the VA-ECMO only group was significantly higher than the Impella and VA-ECMO group (48%). However, there were significant differences in baseline characteristics between groups (the VA-ECMO only group was significantly more likely to have undergone cardiopulmonary resuscitation and had lower pH levels). Nevertheless, hospital survival remained significantly better in the propensity score-matched subgroup (Impella plus VA-ECMO group 48% vs. VA ECMO alone 74%, p = 0.04). In a separate study, Patel et al. [23] noted similar difference in survival between VA-ECMO alone compared to Impella plus VA-ECMO (30-day survival 22 vs. 43% respectively, p = 0.02) in a cohort of 66 patients with cardiogenic shock of mixed etiologies. However, there were many differences in baseline characteristics between these groups, which limits the ability to draw any conclusions.
The timing of Impella support may be relevant. Akanni et al. [24] compared the outcomes of different sequences of support (Impella to Impella plus VA-ECMO, VA-ECMO to Impella plus VA-ECMO vs. VA-ECMO alone) in a cohort of patients with cardiogenic shock of various etiologies. The Impella was added after a median interval of 12 (4–26) h, and VA-ECMO was added to Impella after an interval of 7 (3–31) h. With this strategy of early escalation of support, there was no significant difference in 30-day survival between the groups (47 vs. 43 vs. 49%, p = 0.913).
Colombier et al. [25] described their experience with Impella in 31 patients with VA-ECMO who had insufficient LV unloading with an intra-aortic balloon pump. The median time to Impella insertion was 84 (24–186) h. Overall mortality at 30 days was 53%, with significantly worse outcomes in patients with chronic heart failure. The physiology of patients with cardiogenic shock due to end-stage chronic heart failure differs from patients with acute myocardial infarction [26]. These patients with cardiogenic shock due to chronic heart failure are characterized by poor LV contractility, LV dilatation, often with co-existing mitral regurgitation and marked afterload sensitivity, which renders them particularly vulnerable to LV distension. These patients also tend to have greater degrees of RV dysfunction than in the acute myocardial infarction patients. It is possible that earlier Impella support may improve outcomes in these patients with end-stage heart failure.
Tepper et al. [27] compared Impella to a surgical vent in 45 patients with cardiogenic shock. Post-cardiotomy shock was more common in the surgical vent group, while acute myocardial infarction was significantly more common in the Impella group. Both Impella and surgical vent reduced pulmonary artery diastolic pressure although the change of central venous pressure was only significant in the Impella group. Despite comparable improvement in pulmonary artery diastolic pressure, radiological improvement in pulmonary edema was more common in the Impella group (65%) compared to the surgical vent (24%) group. There was no significant difference in 30-day survival, bleeding, or vascular complications. Some of the differences may be related to patient heterogeneity, small sample size, and differences in the surgical vent (cannula size and position) [28].
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Complications of Combined Impella and VA-ECMO Support
It is likely that the addition of Impella will also introduce Impella-related complications, but it is difficult to discern the clinical significance and contributions of VA-ECMO versus Impella to the adverse events in the absence of prospective randomized trials. In addition, the adverse event rates are confounded by the inherent biases in selecting the ‘venting’ strategies and implanter (center) experience with Impella and VA-ECMO.
Pappalardo et al. did note a higher incidence of hemolysis and renal failure in the Impella plus VA-ECMO group, but no significant difference in bleeding. However, these events are generally transient in nature, and may not compromise survival in the Impella group. Schrage et al. [29] reported their combined Impella plus VA-ECMO experience in 106 patients. Vascular complications requiring intervention, bleeding requiring intervention, hemolysis, and sepsis were reported in 34, 25, 47, and 42% of patients, respectively.
Other studies of Impella have reported significant risks of complications, primarily related to vascular access, bleeding, and hemolysis. In the Impella-EUROSHOCK registry with Impella 2.5, which included 120 patients, major bleeding at the vascular access site, hemolysis, and pericardial tamponade occurred in 34 (28.6%), nine (7.5%), and two (1.7%) patients, respectively [30]. In the Europella registry of 144 patients who underwent Impella 2.5 for high-risk PCI, rates of bleeding requiring transfusion or surgery and vascular complications were 6.2 and 4%, respectively [31]. In a small randomized trial of 25 patients (12 with Impella), Seyfarth et al. [32] noted one acute limb ischemia requiring surgery, higher free hemoglobin, and greater packed red cells transfusions compared to IABP.
In contrast, Badiye et al. reported a significantly higher frequency of hemolysis, which occurred in the majority of patients on Impella support (62.5% of 118 devices), with an average duration of support of 86 h [33]. Severe hemolysis resulting in acute renal failure has also been described [34]. Less common Impella-related complications include device failure due to kinking of the driveline (device failure) [35] and iatrogenic mitral regurgitation related to the positioning of the Impella in the mitral valve apparatus [36, 37]. There do not appear to be any significant short or long-term detrimental effects on the aortic valve [38, 39].
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Combining Impella and VA-ECMO in practice
Cardiogenic shock is a complex syndrome with heterogenous clinical presentation, pathophysiology, etiology, and hemodynamic profile. Mechanical circulatory support (MCS) is a key element of cardiogenic shock care pathways [40]. Specifically, center-specific care pathways should define the triggers for initiation of MCS, the choice of MCS modality, and the escalation and management of MCS in patients with cardiogenic shock.
Impella and/or peripheral VA-ECMO are often the primary MCS modality of choice in critical cardiogenic shock, as they can be deployed rapidly. In either case, the adequacy of hemodynamic support and the adequacy of LV unloading need to monitored. The most direct means of guiding care through each of these stages of clinical decision-making is the use of a pulmonary artery catheter to measure central venous pressure, pulmonary capillary wedge pressure, and cardiac output. These critical measurements, when added to standard clinical measures such as blood pressure, lactate, urine output, and echocardiographic assessments of LV size, function, and aortic valve opening can help simultaneously optimize pharmacologic and guide escalation of mechanical circulatory support.
Escalation of support from Impella CP
The Impella CP, which provides up to 3.5 l/min blood flow, can be inserted rapidly percutaneously, and is being increasingly deployed in patients with cardiogenic shock due to acute myocardial infarction. Impella 5.0, with its larger bore catheter and pump, has a blood flow capacity of 5.0 l/min; however, this device generally requires surgical cutdowns for insertion. Thus, in many institutions, Impella CP is the first choice for support.
Right heart failure is an indication for escalating support from Impella CP. Rising central venous pressure (CVP), changes in CVP waveform (new ‘v’ waves and/or steep ‘y’ descent), diminishing pulmonary artery pulse pressure, and right ventricular dilatation on echocardiogram would be indicative of right heart failure. Typically, Impella flow would be limited by recurrent suction events in right heart failure, necessitating down-titration of Impella pump power level. The addition of VA ECMO to Impella CP is indicated in right heart failure.
In some cases, persistent low cardiac output may reflect inadequate support from Impella CP. Upgrading to Impella 5.0 may be indicated in the absence of right heart failure.
Addition of Impella to VA-ECMO
Left ventricular distension and pulmonary edema is a complication of VA-ECMO, occurring in 30–68% of patients, at variable time from institution of VA-ECMO [41, 42]. A combination of arterial blood pressure monitoring, echocardiography (aortic valve opening, LV volume, spontaneous contrast and mitral regurgitation), pulmonary artery (wedge) pressure monitoring, partial pressure of end-tidal carbon dioxide levels and chest radiographs should be used routinely during VA-ECMO support for surveillance. Indication and threshold for LV decompression vary between centers, which reflect differences in practices in the absence of clinical trials. In general, indications for LV decompression include rising pulmonary artery pressures (and wedge pressure) and/or reducing arterial pulse pressure (LV ejection) in association with LV dilatation and/or worsening pulmonary congestion on chest radiograph, or (ii) spontaneous contrast on echocardiography with limited or no aortic valve opening. We have adopted the routine insertion of Impella CP at the time of peripheral VA-ECMO support in Birmingham since 2016, a practice that is not unique to our center [31].
We have previously estimated the total systemic blood flow using the Fick principle during Impella and VA-ECMO support [43] [SUPPLEMENTARY MATERIAL]. The increase in trans-pulmonary blood flow is supported by the observed increase in partial pressure of end-tidal carbon dioxide, a finding that has been confirmed by other investigators [44].
Conclusions
Left ventricular distension and pulmonary edema are recognized complications of the abnormal circulatory physiology associated with VA-ECMO. The Impella left ventricular assist device effectively unloads the LV and relieves VA-ECMO-related LV distension. Unlike other venting strategies, the Impella also contributes to total blood flow. Despite the additional risks associated with Impella, some studies have reported better clinical outcomes with combined Impella and VA-ECMO support compared to VA-ECMO alone; and these findings will need to be confirmed in future prospective studies.
Acknowledgements
Funding
No funding or sponsorship was received for this study or publication of this article.
Authorship
All named authors meet the International Committee of Medical Journal Editors (ICMJE) criteria for authorship for this article, take responsibility for the integrity of the work as a whole, and have given their approval for this version to be published.
Disclosures
Hoong Sern Lim has nothing to disclose.
Compliance with Ethics Guidelines
This article is based on previously conducted studies and does not contain any studies with human participants or animals performed by any of the authors.
Data Availability
Data sharing is not applicable to this article as no datasets were generated or analyzed during the current study.
Open Access
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