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The ABCDE approach to difficult weaning from venoarterial extracorporeal membrane oxygenation
Critical Care volume 26, Article number: 216 (2022)
Venoarterial extracorporeal membrane oxygenation (VA ECMO) has been increasingly applied in patients with cardiogenic shock in recent years. Nevertheless, many patients cannot be successfully weaned from VA ECMO support and 1-year mortality remains high. A systematic approach could help to optimize clinical management in favor of weaning by identifying important factors in individual patients. Here, we provide an overview of pivotal factors that potentially prevent successful weaning of VA ECMO. We present this through a rigorous approach following the relatable acronym ABCDE, in order to facilitate widespread use in daily practice.
Venoarterial extracorporeal membrane oxygenation (VA ECMO) has become increasingly used for the urgent and potentially lifesaving support of patients with severe cardiorespiratory failure [1, 2]. This increase in popularity may be attributable to improving mortality rates and growing ease of VA ECMO initiation .
These encouraging developments are at least in part overshadowed by a considerable percentage (30–70%) of patients that can ultimately not be successfully weaned from VA ECMO support [4, 5]. When patients are not eligible for a durable ventricular assist device or heart transplantation, weaning failure implicitly means withdrawal of life-sustaining support. It is therefore apparent that great caution should be used to carefully review and optimize all reversible factors before VA ECMO extraction is performed. Naturally, factors that would clearly prevent successful weaning should be addressed before performing a weaning trial and inferring these conclusions.
To our knowledge, these factors have not been systematically summarized in a rigorous, clinical practice-oriented way. A comparable and well-recognized approach exists for patients who cannot be weaned from mechanical ventilation, known as ‘ABC,’ which forms the basis for weaning protocols from mechanical ventilation . Given the imperative for such an overview to guide clinical practice in the setting of VA ECMO, we set out to summarize contributing factors and underlying disease-related reasons for VA ECMO weaning failure and provide a daily tool for a structured diagnostic and therapeutic approach.
Failure to wean from VA ECMO
A multitude of studies have assessed the occurrence of VA ECMO weaning failure and its predisposing risk factors . Throughout these studies, however, the definition of weaning failure varies considerably. Some authors have proposed that successful weaning should be defined as 30-day survival without (re)implantation of another mechanical support device [5, 7, 8]. Other groups have limited the critical time frame to 48 [9, 10] or even 24 h [11, 12] after decannulation.
A careful consideration of the exact definition of weaning success seems important as successful decannulation does not unequivocally translate into beneficial patient outcome [5, 13]. About 20 to 60 percent of patients still die after decannulation but before hospital discharge [4, 13]. This so-called ECMO gap seems largely explained by persistent multiorgan failure, adverse neurological events, bleeding, intercurrent infections (most notably pneumonia) and decompensated cardiac failure . An additional 10 percent of patients ultimately die after hospital discharge but before 1-year follow-up . This seems mainly attributable to underlying disease states, as well as the acquired frailty after a prolonged and complicated intensive care stay .
Consequences of VA ECMO weaning failure
VA ECMO is intended to serve as a bridge to recovery in most cases. When recovery is not possible and a patient remains VA ECMO dependent, prognosis is poor or dependent on long-term therapeutic options . A way out is only possible by implantation of a mechanical circulatory support (MCS) device, i.e., a left ventricular assist device (LVAD) or a biventricular assist device (BIVAD)), or urgent heart transplantation. Yet, these bridging steps are generally restricted to the most favorable prognostic scenarios while on ECMO and patient selection requires careful evaluation and weighing of specific prognostic factors [18,19,20]. In France, patients receiving VA ECMO are prioritized for cardiac transplant but their eligibility is confined to 12–16 days of extracorporeal support duration to optimize their waitlist and posttransplant mortality .
Patients who ultimately receive an LVAD in the setting of VA ECMO weaning failure have a 30-day survival of 77 percent which drops to about 50 percent after 1 year . This last number approximates overall survival of VA ECMO-supported patients .
The ABC concept as a systematic approach to VA ECMO weaning failure
A systematic and concise evaluation of all reversible factors may maximize weaning success rates and outcomes of VA ECMO-supported patients. As many different and potentially interrelated factors may be dynamically involved in each individual patient, a systematic approach to this critical process is necessitated. In the absence of definitive guideline recommendations and clear evidence concerning weaning from VA ECMO, the diagnostic and therapeutic recommendations outlined here are based on the practice experience and opinion of the authors and their critical appraisal of the literature. In Fig. 1, an overview of the various factors is provided. Depending on the specific case, the reader may find some factors of greater importance than others. Also, several factors may have already been assessed during an earlier phase of ECMO support. The practical approach described here is intended to provide a complete overview of factors that may contribute to persistent VA ECMO dependency. Naturally, this approach can also be extrapolated to patients who clinically deteriorate after decannulation.
Cardiac output can be significantly compromised by both bradyarrhythmias and tachyarrhythmias. In the weaning phase from VA ECMO, it seems advisable to strive for a normally conducted sinus rhythm with a heart rate of 60–100 beats per minute (bpm), whenever possible.
From a conceptual perspective, a lowest possible heart rate seems ideal in recovering heart failure under VA ECMO support as it may limit myocardial mechanical loading, calcium (dys-)handling and overload, and metabolic demand directly. A sinus rhythm with a rate between 60 and 80 bpm may at times be acceptable during weaning from VA ECMO, especially in ischemic heart disease. When cardiac output is strongly compromised by the low heart rate itself, e.g., in the context of a relatively rate-independent, ‘fixed’ stroke volume, temporary pacing at high normal rates (100 bpm) should be considered to facilitate weaning from VA ECMO. In such instances, chronotropism can be stimulated through adrenergic medications. A high-degree atrioventricular block may respond accordingly, while distal conduction block may become worse and also warrant temporary pacing.
A high heart rate (> 100 bpm) is inherently related to a significant mechanical and metabolic myocardial burden and should therefore, especially in a recovering heart, be reduced as much as possible to a degree that still guarantees an acceptable native cardiac output.
Supraventricular (tachy-)arrhythmias, i.e., atrial fibrillation and flutter, are frequently encountered during critical illness and may be caused by a combination of cardiovascular failure and systemic inflammation in the setting of multiorgan failure . A (tachy-)arrhythmia-induced cardiomyopathy can be the cause of severe cardiogenic shock requiring VA ECMO , but may also contribute to persisting VA ECMO dependency. It can do so by ablating the atrial kick, compromising passive ventricular filling and reducing myocardial contractility. A ‘rhythm control’ strategy seems preferable to assure the persistence of an ‘atrial kick.’ Yet, restoration of sinus rhythm does not necessarily result in the immediate recovery of mechanical forces and atrial stunning may persist for days. Therefore, a ‘rate control’ strategy may be equally valid when sinus rhythm cannot durably be achieved . An arrhythmia-induced cardiomyopathy justifies an aggressive rate control strategy, including definite ablation of the atrioventricular node, and pacing .
Ventricular arrhythmias during VA ECMO support can arise due to a variety of factors which include electrolyte abnormalities (see section ‘E: extracardiac factors’), pro-arrhythmogenic side effects of medication, myocardial ischemia, novel structural abnormalities or complications (see section ‘D: dysfunction of mechanical origin’). The occurrence of ventricular arrhythmias mandates a thorough diagnostic work-up. Although ventricular arrhythmias may not immediately lead to hemodynamic compromise in the setting of extracorporeal support, they should immediately be attended to as the absence of native cardiac ejection may cause pulmonary ischemia, left-sided cardiac congestion and distention, pulmonary edema and thrombo-embolism. Depending on the underlying pro-arrhythmogenic mechanisms involved, temporary pacing at rates above the baseline heart rate that allowed ventricular arrhythmias to occur, possibly combined with anti-arrhythmic medications, may prevent recurrences. Also, catheter ablation should be considered, which may be safely performed during VA ECMO support .
It is well appreciated that an altered atrioventricular and inter-ventricular dyssynchrony significantly impacts on heart failure severity and cardiac output. Cardiac output and efficiency may improve with cardiac resynchronization through atrioventricular and biventricular pacing . From a mechanistic perspective, these insights from optimizing heart failure by chronic pacing may also prove beneficial in the setting of acute heart failure and VA ECMO support. Yet, the literature on optimal atrioventricular and biventricular pacing is scarce and limited to case reports and series and requires further study .
Diagnostic and therapeutic recommendations for A: arrhythmias
Strive for sinus rhythm. When cardiac output depends on maintaining a very low stroke volume, consider aiming for heart rates around 100/min by means of medication or pacing.
Aggressively correct ventricular arrhythmias and search for contributing factors.
In severe dyssynchrony impairing cardiac performance, consider resynchronization therapy to enable weaning.
B: blood pressures and loading conditions
A key aspect of heart failure management is to unload the heart by lowering preload and afterload, reduce myocardial metabolism and oxygen demand, and favorably influence the remodeling processes, while maintaining cardiac function and integrity. This important notion directly translates into optimal blood pressure management and is particularly important during VA ECMO support where the heart is additionally burdened by the non-physiologic, retrograde and continuous aortic flow of the extracorporeal circuit [26, 27]. Despite these challenges, the best prerequisites for weaning will be met through an optimization of ventricular preload and afterload.
Both preload and afterload are influenced by a wide array of factors, some of which are shared by both the left (LV) and right ventricle (RV) [27, 28]. These factors are summarized in Fig. 2. Preload of both ventricles is lowered by decreasing circulating blood volume. Left ventricular afterload is primarily determined by arterial blood pressure which in turn is greatly influenced by systemic vascular tone and VA ECMO blood flow. A lowering of the ECMO blood flow rate and blood pressure through decreasing the ECMO pump speed, inodilators or heart failure medication results in a more beneficial left ventriculo-arterial coupling. Adjunct left ventricular unloading should always be considered when aortic valve opening is incomplete or even absent; echocardiographic ‘smoke’ can be detected reflecting low blood flow in the LV, left atrium or ascending aorta; the pulmonary capillary wedge (PCWP) or left atrial pressure is significantly elevated (> 15 mmHg) or when pulmonary edema is present. Please note in this context that left atrial or ventricular dilatation merely represents cardiac geometry and does not necessarily translate into myocardial overload without considering cavity pressures.
The RV generally tends to be unloaded during VA ECMO support, which also renders it more challenging to assess its proper contractile performance. As such, right ventricular–pulmonary arterial coupling deserves particular attention as insufficient right ventricular function often forms a limiting step in the weaning process from VA ECMO. Pulmonary vascular resistance (PVR) should be optimized by striving for a low–normal partial pressure of CO2 and a high normal partial pressure of O2 in the arterial blood both promoting vasodilation. Also, inhaled nitric oxide (iNO) or other potent and selective pulmonary vasodilators can significantly aid to reduce the PVR.
Diagnostic and therapeutic recommendations for B: blood pressures and loading conditions
Lower afterload as far as physiologically tolerable through the use of inodilators and possibly heart failure medications as well as by decreasing the ECMO pump speed.
For right ventricular unloading, consider aiming for physiological pH or mild alkalemia, normal partial pressures of arterial carbon dioxide and oxygen, and consider adding iNO.
For left ventricular unloading: a) lower blood pressure and ECMO blood flow rate as far as tolerated by end-organ perfusion and b) consider adjunct LV unloading.
Lower preload as physiologically tolerated by decreasing the circulating blood volume through diuretics or continuous renal replacement therapy/ ultrafiltration. Strive for CVP < 12 and PCWP < 15 mmHg.
C: contractility and coronaries
An adequate degree of contractile reserve and its proper stimulation to meet circulatory demands is a prerequisite for successful VA ECMO weaning. Myocardial contractility is influenced by many factors including an intact intra- and inter-cellular myocardial structure, provision of sufficient nutrients and oxygen, proper neuro-vegetative and neuro-humoral regulation, thyroid hormone signaling, and an adequate electrolyte homeostasis including cardiomyocyte calcium handling. Cardiac performance and myocardial integrity may also be negatively influenced by the effects of VA ECMO, an effect which seems primarily the consequence of alterations in cardiac loading conditions .
Therapeutic interventions improving native contractility should be aimed at optimizing cardiac loading conditions (see section ‘B: blood pressures and loading conditions’), myocardial oxygen consumption and initiating specific medication. No randomized clinical trials have evaluated the effects of inotropic medication on weaning success rates in the setting of VA ECMO. While observational studies in VA ECMO recipients suggested that epinephrine was associated with an increased mortality risk , administration of levosimendan was associated with a 1.6 times higher pooled odds for successful VA ECMO weaning . In addition, a case series also suggested that initiation of phosphodiesterase-III inhibition (milrinone or enoximone), in conjunction with low-dose beta blocker administration, increased weaning success from VA ECMO . Overall, inodilator therapy may have beneficial effects associated with an increased weaning success rate.
Further, coronary oxygen content and myocardial oxygen demand should be optimized as much as possible. Appropriate transfusion thresholds and hemoglobin targets for the setting of VA ECMO weaning failure are currently unknown.
Diagnostic and therapeutic recommendations for C: contractility and coronaries
Consider the initiation of inodilator therapy and heart failure medication, while avoiding the potential negative sequelae of these drugs.
In case of failure to wean, optimize oxygen content of arterialized blood. Please beware to measure arterial oxygen saturation on the right arm as this most consistently reflects coronary blood oxygenation.
Reduce myocardial oxygen demand and reduce systemic oxygen extraction as much as possible by suppressing fever, work of breathing and shivering.
When signs of myocardial ischemia exist and/or coronary status is unknown, consider performing a (repeat) coronary angiography. Revascularization should be pursued in most cases where severe coronary artery stenoses are found.
D: dysfunction of mechanical origin
Several mechanical issues may cause cardiac dysfunction and prevent successful liberation from VA ECMO. These include cardiac tamponade, ventricular septal rupture (VSR), new onset severe mitral valve regurgitation (due to chordal rupture after myocardial infarction), and systolic anterior motion (SAM) of the anterior mitral valve leaflet with resulting severe mitral regurgitation and left ventricular outflow tract obstruction (LVOTO).
The occurrence of cardiac tamponade has been described in about 2 percent of patients supported with venovenous (VV) and VA ECMO . Cardiac tamponade might develop secondary to reactive pericarditis, e.g., after myocardial infarction or heart surgery, perimyocarditis , free wall rupture , cardiac perforation during cannulation  or accumulation of thrombus in the pericardial sac after cardiac surgery. Recognition of cardiac tamponade may be obscured in the setting of VA ECMO as traditional signs are mitigated by the effects of a parallel extracorporeal circulation as created by the VA ECMO circuit. A clinical suspicion of cardiac tamponade in combination with pericardial effusion or thrombus should prompt drainage of a pericardial effusion. With weaning success rates and in-hospital survival rates approximating 82 and 73 percent, respectively, the prognosis of patients after drainage appears relatively good .
Ventricular septal rupture as a contributing factor to persistent shock during VA ECMO support might be clinically hard to distinguish from left and right ventricular failure due to myocardial infarction. Suspicion should be raised when new right ventricular dilatation or failure develops, a new loud murmur is appreciated, or pulmonary artery catheter-based measurements indicate a significant step-up in oxygen saturation and/or high cardiac output despite persistent low end-organ perfusion shortly after a myocardial infarction. Thirty-day mortality among patients with VSR under VA ECMO support was described as varying between 43 and 57 percent .
Clinically significant mitral valve regurgitation may be observed in severe left ventricular heart failure on a regular basis and may negatively influence the weaning process from VA ECMO. Also, device-related mitral valve regurgitation has been described as a complication of Impella support, which might be used in conjunction with VA ECMO for left ventricular unloading and as a facilitator for weaning from VA ECMO . VA ECMO support for severe mitral valve regurgitation secondary to papillary muscle rupture has been described in 42 patients in the ELSO registry . In-hospital survival approaches 43 percent , and therapeutic options include valvular repair or replacement  and percutaneous repair .
Patients with cardiogenic shock due to left ventricular outflow tract obstruction (LVOTO) as a result of hypertrophic cardiomyopathy  and stress-induced cardiomyopathy  have been successfully supported with VA ECMO. As LVOTO requires an increase in left ventricular afterload and preload, VA ECMO conveys beneficial effects on its severity . For the same reason, the contribution of LVOTO to VA ECMO weaning failure might be underappreciated or even go unnoticed at high VA ECMO blood flow rates. Special attention should therefore be devoted to its presence during a weaning trial or when cardiogenic shock ensues shortly after decannulation. Percutaneous transluminal septal myocardial ablation, or surgical myectomy with or without mitral valve plasty/replacement must be considered when VA ECMO liberation depends on the presence of LVOTO and conservative measures fail .
Diagnostic and therapeutic recommendations for D: dysfunction of mechanical origin
In case of failure to wean from VA ECMO, actively exclude a clinically significant degree of pericardial effusion/thrombus, the presence of a VSR, severe mitral valve regurgitation, and LVOTO.
Note that the functional consequences of cardiac tamponade, VSR, and LVOTO might be masked by the inherent hemodynamic effects of VA ECMO.
In case of a hemodynamically compromising degree of pericardial effusion/thrombus, consider drainage or surgical exploration prior to performing a weaning trial.
In case of VSR, consider repair or percutaneous closure after an initial stabilization phase.
In case of new onset severe mitral valve regurgitation, consider surgical valve repair/replacement or percutaneous repair.
In case of LVOTO due to hypertrophic cardiomyopathy, consider alcohol septal ablation, surgical myectomy.
E: extracardiac factors
Myocardial function is strongly influenced by a wide array of extracardiac factors which may be grouped into the following categories:
Most patients receiving VA ECMO require invasive mechanical ventilation as severe cardiogenic shock is often accompanied by overt respiratory insufficiency. Although VA ECMO may provide supplementary respiratory support, optimal management of mechanical ventilation remains indispensable and the impact of gas exchange depends on the degree of dual circulation and differential oxygenation present [43,44,45]. This includes appreciating heart–lung interaction, assuring adequate pulmonary mechanics and counteracting hydrostatic pulmonary edema, the latter being a common and serious complication of VA ECMO [46,47,48].
The current literature does not provide clear evidence to guide daily practice of mechanical ventilation during VA ECMO. Yet, pathophysiological considerations may aid in setting clinical goals that should be considered when aiming to optimally promote weaning from VA ECMO.
Positive end-expiratory pressure
Finding an optimal positive end-expiratory pressure (PEEP) requires weighing influences on right and left ventricular preload and afterload, while striving to minimize pulmonary edema and atelectasis. Generally, a high–normal PEEP around 10 cm H2O seems a fair compromise, while combined echocardiographic and hemodynamic monitoring of right and left ventricular geometry and function can aid in determining what appears optimal for the individual patient. This becomes particularly relevant when native pulmonary gas exchange becomes pivotal when the heart increasingly ejects blood originating from the pulmonary circulation into the ascending aorta and coronary arteries. Likewise, right ventricular function will benefit from a low–normal PVR in the absence of edema and atelectasis.
VA ECMO-related lung injury might be important and mediated by different mechanisms and clinical entities including not only hydrostatic pulmonary edema, but also inflammation, alveolar hemorrhage, thrombo-embolism, and ischemia, the latter being sequelae of reduced transpulmonary blood flow during periods of high extracorporeal blood flow rates . This all implies that a lung-protective ventilatory strategy, as is widely accepted for patients with the acute respiratory distress syndrome (ARDS), should be the goal, while gas exchange should suffice to guarantee a functional right–left shunt as inherent to VA ECMO. Toward the time of anticipated weaning from VA ECMO, patients should not be substantially dependent on the membrane oxygenator for gas exchange, but rather be mechanically ventilated to achieve adequate gas exchange.
Heart failure requiring ECMO support can occur in both hyperthyroidism  and hypothyroidism . It is unknown to what extent thyroid hormone alterations could contribute to VA ECMO weaning failure. This is especially relevant since thyroid hormone alterations in the absence of disease in the hypothalamic–pituitaric–thyroidal axis (so-called non-thyroidal illness) are observed in a majority of critically ill patients . In the absence of unequivocal evidence, we would advocate to consider correcting severely altered thyroid hormone levels in patients who experience VA ECMO weaning failure.
Adrenal insufficiency can precipitate heart failure [53, 54] and even necessitate VA ECMO support in severe cases [51, 55]. It is unknown to what extent (relative) adrenal insufficiency plays a role in ECMO weaning failure. A thorough endocrinological work-up seems imperative when no apparent explanation is found for high vasopressor needs and typical features of adrenal insufficiency exist. In exceptional cases, a pheochromocytoma can also explain cardiogenic shock necessitating ECMO support through catecholaminergic stress .
Development of infection has been described in 14 to 65 percent of ECMO-supported patients  where chances of contracting an infection seem to accumulate as ECMO support duration lengthens . In a selection of patients who were supported longer than 48 hours, the majority of infections were characterized as ventilator-associated pneumonia (VAP: 55%), followed by blood stream infections (18%), cannula infections (10%), and mediastinitis (11%). Some studies have suggested that acquiring an infection during ECMO support is associated with a significantly increased risk for weaning failure and in-hospital mortality .
Transient episodes of congestive heart failure [60, 61] and cardiogenic shock  have been reported in patients with overt hypocalcemia. Also, historical studies have indicated improvements in cardiac output and mean arterial blood pressure after intravenous calcium infusion in patients during, or shortly after, cardiopulmonary bypass [63, 64]. The effects of serum calcium concentrations and calcium infusion on myocardial function during VA ECMO support have not been evaluated. The arrhythmogenic risk seems to be augmented by severe hypokalemia and hypomagnesemia . Hyperkalemia, on the other hand, may cause serious conduction disturbances and severe bradycardia.
Diagnostic and therapeutic recommendations for E: extracardiac factors
Aim for ventilator settings that optimize cardiac loading conditions, which should also improve right–left ventricular interdependence.
In case of an active infection, consider repeating a weaning trial after adequate source control and antibiotic treatment. If delay is not possible, suppress fever and shivering as much as possible.
In case of overt hypothyroidism, initiate thyroid hormone supplementation.
When suspecting adrenal insufficiency, perform a thorough endocrinologic work-up and initiate mineralocorticoid and corticosteroid hormone supplementation, as indicated.
In case of insufficient ventricular systolic performance, consider optimizing serum calcium levels (> 1.0 mmol/L).
High–normal potassium (> 4.0 mmol/L) and magnesium (> 1 mmol/L) levels should be pursued.
After having discussed all the different factors, we provide a checklist of examinations (Table 1) which can be used in a patient who is difficult to wean from VA ECMO support. The order of relevance of these different examinations may differ, depending on the specific case.
The poor weaning success rates from VA ECMO today underscore the necessity to focus our efforts on a variety of factors that may improve future outcomes, including:
It is imperative that a universal definition of VA ECMO weaning failure be agreed upon to maximize efficiency and comparability of relevant studies.
Large-scale observational studies with high-quality and detailed data incorporating repeated measures for each patient are necessary for: (1) improving patient selection, (2) identifying predictors for weaning failure and successful LVAD implantation, and (3) the assessment of risk factors and their contribution to weaning failure.
Finally, there is a clear unmet need for randomized clinical trial data investigating different therapeutic interventions which could improve weaning success. These include (1) optimal timing of VA ECMO extraction, (2) the effects of LV unloading devices, and (3) types and dosages of inodilator agents as facilitators of weaning from VA ECMO.
While the number of VA ECMO applications has surged in recent years, many patients still cannot be weaned from VA ECMO support and 1-year mortality remains approximately 50 percent. Here, we have provided an overview of pivotal factors that potentially prevent successful weaning of VA ECMO. A structured approach (ABCDE) and evaluation could help to identify factors of importance in a specific patient. Future work should expand our understanding of VA ECMO weaning failure and identify therapeutic interventions to optimize these factors and improve weaning success rates.
Availability data and materials
Acute respiratory distress syndrome
Biventricular assist device
Beats per minute
Extracorporeal membrane oxygenation
Extracorporeal Life Support Organization
Inhaled nitric oxide
Left ventricular assist device
Left ventricular outflow tract obstruction
Mechanical circulatory support
Pulmonary capillary wedge pressure
Positive end-expiratory pressure
Pulmonary vascular resistance
Systolic anterior motion of the mitral valve
Ventricular septal rupture
Meuwese CL, Hermens JA, de Haan M, Braithwaite SA, Ramjankhan F, Buijsrogge MP, et al. Twelve years of circulatory extracorporeal life support at the university medical centre Utrecht. Neth Heart J. 2021;29(7–8):394–401.
Combes A, Price S, Slutsky AS, Brodie D. Temporary circulatory support for cardiogenic shock. Lancet. 2020;396(10245):199–212.
Meuwese CL, Ramjankhan FZ, Braithwaite SA, de Jonge N, de Jong M, Buijsrogge MP, et al. Extracorporeal life support in cardiogenic shock: indications and management in current practice. Netherlands Heart J Monthly J Netherlands Soc Cardiol Netherlands Heart Found. 2018;26(2):58–66.
Aso S, Matsui H, Fushimi K, Yasunaga H. In-hospital mortality and successful weaning from venoarterial extracorporeal membrane oxygenation: analysis of 5,263 patients using a national inpatient database in Japan. Critical Care. 2016;20:80.
Ortuno S, Delmas C, Diehl JL, Bailleul C, Lancelot A, Naili M, et al. Weaning from veno-arterial extra-corporeal membrane oxygenation: which strategy to use? Annal Cardiothorac Surg. 2019;8(1):E1-e8.
Heunks LM, van der Hoeven JG. Clinical review: the ABC of weaning failure–a structured approach. Critical Care. 2010;14(6):245.
Sawada K, Kawakami S, Murata S, Nishimura K, Tahara Y, Hosoda H, et al. Predicting parameters for successful weaning from veno-arterial extracorporeal membrane oxygenation in cardiogenic shock. ESC heart failure. 2021;8(1):471–80.
Aissaoui N, Luyt CE, Leprince P, Trouillet JL, Léger P, Pavie A, et al. Predictors of successful extracorporeal membrane oxygenation (ECMO) weaning after assistance for refractory cardiogenic shock. Intensive Care Med. 2011;37(11):1738–45.
Lee W, Kim Y, Choi H, Kim H, Lee S, Lee H, et al. Advanced age as a predictor of survival and weaning in venoarterial extracorporeal oxygenation: a retrospective observational study. Biomed Res Int. 2017;2017:3505784.
Chang WW, Tsai FC, Tsai TY, Chang CH, Jenq CC, Chang MY, et al. Predictors of mortality in patients successfully weaned from extracorporeal membrane oxygenation. PLoS ONE. 2012;7(8): e42687.
Guilherme E, Jacquet-Lagrèze M, Pozzi M, Achana F, Armoiry X, Fellahi JL. Can levosimendan reduce ECMO weaning failure in cardiogenic shock?: a cohort study with propensity score analysis. Critical Care. 2020;24(1):442.
Distelmaier K, Roth C, Schrutka L, Binder C, Steinlechner B, Heinz G, et al. Beneficial effects of levosimendan on survival in patients undergoing extracorporeal membrane oxygenation after cardiovascular surgery. Br J Anaesth. 2016;117(1):52–8.
Lüsebrink E, Stremmel C, Stark K, Joskowiak D, Czermak T, Born F, et al. Update on weaning from veno-arterial extracorporeal membrane oxygenation. J Clin Med. 2020. https://doi.org/10.3390/jcm9040992.
Makhoul M, Heuts S, Mansouri A, Taccone FS, Obeid A, Mirko B, et al. Understanding the “extracorporeal membrane oxygenation gap” in veno-arterial configuration for adult patients: timing and causes of death. Artif Organs. 2021;45(10):1155–67.
Meuwese CL, Hermens JA, de Haan M, Braithwaite SA, Ramjankhan F, Buijsrogge MP, et al. Twelve years of circulatory extracorporeal life support at the university medical centre Utrecht. Netherlands Heart J Monthly J Netherlands Soc Cardiol Netherlands Heart Found. 2021. https://doi.org/10.1007/s12471-021-01552-z.
Rossong H, Debreuil S, Yan W, Hiebert BM, Singal RK, Arora RC, et al. Long-term survival and quality of life after extracorporeal membrane oxygenation. J Thorac Cardiovasc Surg. 2022. https://doi.org/10.1016/j.jtcvs.2021.10.077.
Fried JA, Masoumi A, Takeda K, Brodie D. How I approach weaning from venoarterial ECMO. Critical Care. 2020;24(1):307.
Saeed D, Potapov E, Loforte A, Morshuis M, Schibilsky D, Zimpfer D, et al. Transition from temporary to durable circulatory support systems. J Am Coll Cardiol. 2020;76(25):2956–64.
Mastoris I, Tonna JE, Hu J, Sauer AJ, Haglund NA, Rycus P, et al. Use of extracorporeal membrane oxygenation as bridge to replacement therapies in cardiogenic shock: insights from the extracorporeal life support organization. Circ Heart Fail. 2022;15(1): e008777.
Dorent R, Jasseron C, Audry B, Bayer F, Legeai C, Cantrelle C, et al. New French heart allocation system: comparison with eurotransplant and US allocation systems. Am J Transplant Off J Am Soc Transplant Am Soc Transplant Surg. 2020;20(5):1236–43.
Shaver CM, Chen W, Janz DR, May AK, Darbar D, Bernard GR, et al. Atrial fibrillation Is an independent predictor of mortality in critically Ill patients. Crit Care Med. 2015;43(10):2104–11.
Hékimian G, Paulo N, Waintraub X, Bréchot N, Schmidt M, Lebreton G, et al. Arrhythmia-induced cardiomyopathy: a potentially reversible cause of refractory cardiogenic shock requiring venoarterial extracorporeal membrane oxygenation. Heart Rhythm. 2021;18(7):1106–12.
Baratto F, Pappalardo F, Oloriz T, Bisceglia C, Vergara P, Silberbauer J, et al. Extracorporeal membrane oxygenation for hemodynamic support of ventricular tachycardia ablation. Circ Arrhythmia Electrophysiol. 2016. https://doi.org/10.1161/CIRCEP.116.004492.
Prinzen FW, Auricchio A, Mullens W, Linde C, Huizar JF. Electrical management of heart failure: from pathophysiology to treatment. European Heart J. 2022. https://doi.org/10.1093/eurheartj/ehac088.
Lim K, Choi JO, Yang JH, Park SJ, Kim SH, Kang J, et al. Cardiac resynchronization therapy device implantation in a patient with cardiogenic shock under percutaneous mechanical circulatory support. Korean Circ J. 2017;47(1):132–5.
Broomé M, Donker DW. Individualized real-time clinical decision support to monitor cardiac loading during venoarterial ECMO. J Transl Med. 2016;14:4.
Donker DW, Brodie D, Henriques JPS, Broomé M. Left ventricular unloading during veno-arterial ECMO: a simulation study. ASAIO Journal. 2019;65(1):11–20.
Burkhoff D, Sayer G, Doshi D, Uriel N. Hemodynamics of mechanical circulatory support. J Am Coll Cardiol. 2015;66(23):2663–74.
Ostadal P, Mlcek M, Kruger A, Hala P, Lacko S, Mates M, et al. Increasing venoarterial extracorporeal membrane oxygenation flow negatively affects left ventricular performance in a porcine model of cardiogenic shock. J Transl Med. 2015;13:266.
Massart N, Mansour A, Ross JT, Ecoffey C, Aninat C, Verhoye JP, et al. Epinephrine administration in venoarterial extracorporeal membrane oxygenation patients is associated with mortality: a retrospective cohort study. ESC heart failure. 2021;8(4):2899–906.
Kaddoura R, Omar AS, Ibrahim MIM, Alkhulaifi A, Lorusso R, Elsherbini H, et al. The effectiveness of levosimendan on veno-arterial extracorporeal membrane oxygenation management and outcome: a systematic review and meta-analysis. J Cardiothorac Vasc Anesth. 2021;35(8):2483–95.
Brugts JJ, Manintveld O, Constantinescu A, Donker DW, van Thiel RJ, Nieman K, et al. Preventing LVAD implantation by early short-term mechanical support and prolonged inodilator therapy: a case series with acute refractory cardiogenic shock treated with veno-arterial extracorporeal membrane oxygenation and optimised medical strategy. Netherlands Heart J Monthly J Netherlands Soc Cardiol Netherlands Heart Found. 2014;22(4):176–81.
Ducrocq G, Gonzalez-Juanatey JR, Puymirat E, Lemesle G, Cachanado M, Durand-Zaleski I, et al. Effect of a restrictive vs liberal blood transfusion strategy on major cardiovascular events among patients with acute myocardial infarction and anemia: the reality randomized clinical trial. JAMA. 2021;325(6):552–60.
Basílio C, Fontoura A, Fernandes J, Roncon-Albuquerque R Jr, Paiva JA. Cardiac tamponade complicating extracorporeal membrane oxygenation: a single-centre experience. Heart Lung Circ. 2021;30(10):1540–4.
Kondo T, Morimoto R, Yokoi T, Yamaguchi S, Kuwayama T, Haga T, et al. Hemodynamics of cardiac tamponade during extracorporeal membrane oxygenation support in a patient with fulminant myocarditis. J Cardiol Cases. 2019;19(1):22–4.
Slater J, Brown RJ, Antonelli TA, Menon V, Boland J, Col J et al. Cardiogenic shock due to cardiac free-wall rupture or tamponade after acute myocardial infarction: a report from the SHOCK trial registry. Should we emergently revascularize occluded coronaries for cardiogenic shock? J Am College Cardiol. 2000;36(3 Suppl A):1117–22
Matteucci M, Fina D, Jiritano F, Meani P, Raffa GM, Kowalewski M, et al. The use of extracorporeal membrane oxygenation in the setting of postinfarction mechanical complications: outcome analysis of the extracorporeal life support organization registry. Interact Cardiovasc Thorac Surg. 2020;31(3):369–74.
Elhussein TA, Hutchison SJ: Acute mitral regurgitation: unforeseen new complication of the Impella LP 5.0 ventricular assist device and review of literature. Heart, lung & circulation. 2014;23(3):e100–4.
Maybauer MO, El Banayosy A, Hooker RL, Vanhooser DW, Harper MD, Mihu MR, et al. Percutaneous venoarterial extracorporeal membrane oxygenation as a bridge to double valve implantation in acute biventricular heart failure with profound cardiogenic shock. J Card Surg. 2019;34(12):1664–6.
Staudacher DL, Bode C, Wengenmayer T. Severe mitral regurgitation requiring ECMO therapy treated by interventional valve reconstruction using the MitraClip. Cathet Cardiovasc Intervent Off J Soc Cardiac Angiography Intervent. 2015;85(1):170–5.
Caniato F, Andrei V, Bernardo P, Agostini C, Cappelli F, Stefano PL, et al. Cardiogenic shock in obstructive hypertrophic cardiomyopathy plus apical ballooning: management with VA-ECMO and myectomy. JACC Case Rep. 2021;3(3):433–7.
Bonacchi M, Maiani M, Harmelin G, Sani G. Intractable cardiogenic shock in stress cardiomyopathy with left ventricular outflow tract obstruction: is extra-corporeal life support the best treatment? Eur J Heart Fail. 2009;11(7):721–7.
Amado-Rodríguez L, Del Busto C, López-Alonso I, Parra D, Mayordomo-Colunga J, Arias-Guillén M, et al. Biotrauma during ultra-low tidal volume ventilation and venoarterial extracorporeal membrane oxygenation in cardiogenic shock: a randomized crossover clinical trial. Ann Intensive Care. 2021;11(1):132.
Justus A, Burrell A, Anstey C, Cornmell G, Brodie D, Shekar K. The association of oxygenation, carbon dioxide removal, and mechanical ventilation practices on survival during venoarterial extracorporeal membrane oxygenation. Front Med. 2021;8: 756280.
Brodie D, Slutsky AS, Combes A. Extracorporeal life support for adults with respiratory failure and related indications: a review. JAMA. 2019;322(6):557–68.
Demondion P, Fournel L, Golmard JL, Niculescu M, Pavie A, Leprince P. Predictors of 30-day mortality and outcome in cases of myocardial infarction with cardiogenic shock treated by extracorporeal life support. European J Cardio-thorac Surg Off J European Assoc Cardio-thorac Surg. 2014;45(1):47–54.
Boulate D, Luyt CE, Pozzi M, Niculescu M, Combes A, Leprince P, et al. Acute lung injury after mechanical circulatory support implantation in patients on extracorporeal life support: an unrecognized problem. European J Cardio-thorac Surg Off J European Assoc Cardio-thorac Surg. 2013;44(3):544–9.
Distelmaier K, Wiedemann D, Lampichler K, Toth D, Galli L, Haberl T, et al. Interdependence of VA-ECMO output, pulmonary congestion and outcome after cardiac surgery. Eur J Intern Med. 2020;81:67–70.
Lee HE, Yi ES, Rabatin JT, Bohman JK, Roden AC. Histopathologic findings in lungs of patients treated with extracorporeal membrane oxygenation. Chest. 2018;153(4):825–33.
Voll M, Øystese KA, Høiskar E, Johansen O, Nyvold C, Norheim I, et al. Case report: a patient with thyroid storm, refractory cardiogenic shock, and cardiac arrest treated with Lugol’s iodine solution and veno-arterial extra corporal membrane oxygenation support. European Heart J Case Rep. 2021. https://doi.org/10.1093/ehjcr/ytab017.
Kang MS, Sandhu CS, Singh N, Evans T. Initiation of levothyroxine in a patient with hypothyroidism inducing adrenal crisis requiring VA ECMO: a tale of preventable disaster. BMJ Case Rep. 2019. https://doi.org/10.1136/bcr-2019-230601.
Fliers E, Bianco AC, Langouche L, Boelen A. Thyroid function in critically ill patients. Lancet Diabetes Endocrinol. 2015;3(10):816–25.
Ikegami Y, Fukuda T, Jo R, Momiyama Y. Reversible cardiomyopathy accompanied by secondary adrenal insufficiency. Circ Heart Fail. 2016;9(3): e002919.
Doshi S, Roy A, Ramamoorthy A, Kothari SS, Bahl VK. Dilated cardiomyopathy: a ghost from the past. Circ Heart Fail. 2013;6(2):e19-21.
Lüsebrink E, Krieg K, Massberg S, Orban M. Venoarterial extracorporeal membrane oxygenation as bridge to effective treatment in a 19-year-old woman with acute adrenal crisis: a case report. European Heart J Case Rep. 2021. https://doi.org/10.1093/ehjcr/ytab031.
Hekimian G, Kharcha F, Bréchot N, Schmidt M, Ghander C, Lebreton G, et al. Extracorporeal membrane oxygenation for pheochromocytoma-induced cardiogenic shock. Ann Intensive Care. 2016;6(1):117.
Cheng R, Hachamovitch R, Kittleson M, Patel J, Arabia F, Moriguchi J, et al. Complications of extracorporeal membrane oxygenation for treatment of cardiogenic shock and cardiac arrest: a meta-analysis of 1,866 adult patients. Ann Thorac Surg. 2014;97(2):610–6.
Schmidt M, Bréchot N, Hariri S, Guiguet M, Luyt CE, Makri R, et al. Nosocomial infections in adult cardiogenic shock patients supported by venoarterial extracorporeal membrane oxygenation. Clinical Infect Dis Off Publ Infect Dis Soc Am. 2012;55(12):1633–41.
Kim D, Na SJ, Cho YH, Chung CR, Jeon K, Suh GY, et al. Predictors of survival to discharge after successful weaning from venoarterial extracorporeal membrane oxygenation in patients With cardiogenic shock. Circ J. 2020;84(12):2205–11.
Bansal B, Bansal M, Bajpai P, Garewal HK. Hypocalcemic cardiomyopathy-different mechanisms in adult and pediatric cases. J Clin Endocrinol Metab. 2014;99(8):2627–32.
Válek M, Roblová L, Raška I Jr, Schaffelhoferová D, Paleček T. Hypocalcaemic cardiomyopathy: a description of two cases and a literature review. ESC Heart Failure. 2020;7(3):1291–301.
Gupta P, Tomar M, Radhakrishnan S, Shrivastava S. Hypocalcemic cardiomyopathy presenting as cardiogenic shock. Ann Pediatr Cardiol. 2011;4(2):152–5.
Shapira N, Schaff HV, White RD, Pluth JR. Hemodynamic effects of calcium chloride injection following cardiopulmonary bypass: response to bolus injection and continuous infusion. Ann Thorac Surg. 1984;37(2):133–40.
Urban MK, Hines R. The effect of calcium on pulmonary vascular resistance and right ventricular function. J Thorac Cardiovasc Surg. 1992;104(2):327–32.
El-Sherif N, Turitto G. Electrolyte disorders and arrhythmogenesis. Cardiol J. 2011;18(3):233–45.
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CLM reports having received research funding from ‘Stichting Gezondheidszorg Spaarneland (SGS)’ foundation. DB receives research support from ALung Technologies. He has been on the medical advisory boards for Abiomed, Xenios, Medtronic, Inspira, and Cellenkos. He is the President-elect of the Extracorporeal Life Support Organization (ELSO) and the Chair of the Executive Committee of the International ECMO Network (ECMONet). DWD reports personal fees from Getinge-Maquet, Xenios NovaLung Fresenius, and Abiomed and research funding from ‘Stichting Gezondheidszorg Spaarneland (SGS)’ foundation, and consultancy and research cooperation with Getinge-Maquet.
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Meuwese, C.L., Brodie, D. & Donker, D.W. The ABCDE approach to difficult weaning from venoarterial extracorporeal membrane oxygenation. Crit Care 26, 216 (2022). https://doi.org/10.1186/s13054-022-04089-8
- Extracorporeal membrane oxygenation
- Weaning failure