Left atrium veno-arterial extra corporeal membrane oxygenation as temporary mechanical support for cardiogenic shock: A case report.

BACKGROUND: Veno-arterial extra corporeal membrane oxygenation (VA-ECMO) support is commonly complicated with left ventricle (LV) distension in patients with cardiogenic shock. We resolved this problem by transeptally converting VA-ECMO to left atrium veno-arterial (LAVA)-ECMO that functioned as a temporary paracorporeal left ventricular assist device to resolve LV distension. In our case LAVA-ECMO was also functioning as a bridge-to-transplant device, a technique that has been scarcely reported in the literature. CASE SUMMARY: A 65 year-old man suffered from acute myocardial injury that required percutaneous stents. Less than two weeks later, noncompliance to antiplatelet therapy led to stent thrombosis, cardiogenic shock, and cardiac arrest. Femoro-femoral VA-ECMO support was started, and the patient underwent a second coronary angiography with re-stenting and intra-aortic balloon pump placement. The VA-ECMO support was complicated by left ventricular distension which we resolved via LAVA-ECMO. Unfortunately, episodes of bleeding and sepsis complicated the clinical picture and the patient passed away 27 d after initiating VA-ECMO. CONCLUSION: This clinical case demonstrates that LAVA-ECMO is a viable strategy to unload the LV without another invasive percutaneous or surgical procedure. We also demonstrate that LAVA-ECMO can also be weaned to a left ventricular assist device system. A benefit of this technique is that the procedure is potentially reversible, should the patient require VA-ECMO support again. A transeptal LV venting approach like LAVA-ECMO may be indicated over ImpellaTM in cases where less LV unloading is required and where a restrictive myocardium could cause LV suctioning. Left ventricular over-distention is a well-known complication of peripheral VA-ECMO in cardiogenic shock and LAVA ECMO through transeptal cannulation offers a novel and safe approach for treating LV overloading, without the need of an additional percutaneous access.

Ethylene glycol poisoning requiring veno-arterial ECMO: A case report.

Supportive care is the cornerstone of the poisoned patient's treatment, waiting for eventual antidotes to act. We recently treated a case of a severe Ethylene Glycol intoxication with early-onset veno-arterial ECMO. The patient was taken to our Emergency Department with the suspicion of acute cerebrovascular accident, since he was found unconscious at home. The arterial blood gas and blood tests showed a severe metabolic acidosis with high serum lactates and creatinine levels. The cerebral Computed Tomography was negative. The rapid increase in serum lactates suggested Ethylene Glycol intoxication. Although the patient was not in shock yet, arterial and venous introducers were placed in to the femoral vessels so that when the patient showed the first signs of cardiogenic shock, veno-arterial ECMO could be initiated in a very short time. The hemodynamic state progressively improved and V-A ECMO was removed after 16 h of support with complete recovery.

Sars-Cov 2 versus Flu: ECMO-associated bloodstream infections.

SARS-CoV-2 and flu may lead to severe acute respiratory distress syndrome (ARDS) requiring extracorporeal membrane oxygenation (ECMO). The aim of the present study is to compare the incidence of bloodstream infections (BSIs) and outcome in patients with flu and SARS-CoV-2 infection hospitalized in ICU and undergoing ECMO. This study is a retrospective analysis of the San Matteo COVID-19 Registry (SMACORE) cohort. The study was conducted from January 2018 to April 2020. Demographic data and microbiological data were recorded during hospitalization. BSIs occurring during ECMO were analyzed. Eighteen patients treated with ECMO, 22 subjects with SARS-CoV-2 infection and 7 with flu, median age 61years for SARS-CoV-2 and 50 for flu (p=NS). Median ECMO duration was similar in the two pathologies. Median time to bloodstream infection from ECMO initiation was similar. Bloodstream infection incidence rate was 2.65 per 100 patients/days for flu and 2.2 per 100 patients/days for SARS-CoV-2. Global infection rate was 5 per 100 patients/days for SARS-CoV-2 patients and 5.3 per 100 patients/days for flu. Mortality during ECMO was 40.9% (5 out of 22 patients) for SARS-CoV-2 infection while none died among flu patients. ECMO-associated mortality was higher in SARS-CoV-2 infection compared with flu infection.

Extracorporeal Membrane Oxygenation for COVID-19 Respiratory Distress Syndrome: An Italian Society for Cardiac Surgery Report.

An increased need of extracorporeal membrane oxygenation (ECMO) support is going to become evident as treatment of SARS-CoV-2 respiratory distress syndrome. This is the first report of the Italian Society for Cardiac Surgery (SICCH) on preliminary experience with COVID-19 patients receiving ECMO support. Data from 12 Italian hospitals participating in SICCH were retrospectively analyzed. Between March 1 and September 15, 2020, a veno-venous (VV) ECMO system was installed in 67 patients (94%) and a veno-arterio-venous ECMO in four (6%). Five patients required VA ECMO after initial weaning from VV ECMO. Thirty (42.2%) patients were weaned from ECMO, while 39 (54.9%) died on ECMO, and six (8.5%) died after ECMO removal. Overall hospital survival was 36.6% (n = 26). Main causes of death were multiple organ failure (n = 14, 31.1%) and sepsis (n = 11, 24.4%). On multivariable analysis, predictors of death while on ECMO support were older age (p = 0.048), elevated pre-ECMO C-reactive protein level (p = 0.048), higher positive end-expiratory pressure on ventilator (p = 0.036) and lower lung compliance (p = 0.032). If the conservative treatment is not effective, ECMO support might be considered as life-saving rescue therapy for COVID-19 refractory respiratory failure. However warm caution and thoughtful approaches for timely detection and treatment should be taken for such a delicate patients population.

An experimental model of veno-venous arterial extracorporeal membrane oxygenation.

INTRODUCTION: Veno-venous arterial extracorporeal membrane oxygenation is a hybrid-modality of extracorporeal membrane oxygenation combining veno-venous and veno-arterial extracorporeal membrane oxygenation. It may be applied to patients with both respiratory and cardio-circulatory failure. AIM: To describe a computational spreadsheet regarding an ex vivo experimental model of veno-venous arterial extracorporeal membrane oxygenation to determine the return of cannula pairs in a single pump-driven circuit. METHODS: We developed an ex vivo model of veno-venous arterial extracorporeal membrane oxygenation with a single pump and two outflow cannulas, and a glucose solution was used to mimic the features of blood. We maintained a fixed aortic impedance and physiological pulmonary resistance. Both flow and pressure data were collected while testing different pairs of outflow cannulas. Six simulations of different cannula pairs were performed, and data were analysed by a custom-made spreadsheet, which was able to predict the flow partition at different flow levels. RESULTS: In all simulations, the flow in the arterial cannula gradually increased differently depending on the cannula pair. The best cannula pair was a 19-Fr/18-cm arterial with a 17-Fr/50-cm venous cannula, where we observed an equal flow split and acceptable flow into the arterial cannula at a lower flow rate of 4 L/min. CONCLUSION: Our computational spreadsheet identifies the suitable cannula pairing set for correctly splitting the outlet blood flow into the arterial and venous return cannulas in a veno-venous arterial extracorporeal membrane oxygenation configuration without the use of external throttles. Several limitations were reported regarding fixed aortic impedance, central venous pressure and the types of cannulas tested; therefore, further studies are mandatory to confirm our findings.

A brief clinical case of monitoring of oxygenator performance and patient-machine interdependency during prolonged veno-venous extracorporeal membrane oxygenation.

Monitoring veno-venous extracorporeal membrane oxygenation (vvECMO) during 76 days of continuous support in a 42-years old patient with end-stage pulmonary disease, listed for double-lung transplantation. Applying a new monitor (Landing®, Eurosets, Medolla, Italy) and describing how measured and calculated parameters can be used to understand the variable interdependency between artificial membrane lung (ML) and patient native lung (NL). During vvECMO, in order to understand how the respiratory function is shared between ML and NL, ideally we should obtain data about oxygen transfer and CO2 removal, both by ML and NL. Measurements for NL can be made on the mechanical ventilator. Measurements for ML are typically made from gas analysis on blood samples drawn from the ECMO system before and after the oxygenator, and therefore are non-continuous. Differently, the Landing monitor provides a continuous measurement of the oxygen transfer from the ML, combined with hemoglobin level, saturation of drained blood and saturation of reinfused blood. Moreover, the Landing monitor provides hemodynamics data about circulation through the ECMO system, with blood flow, pre-oxygenator pressure and post-oxygenator pressure. Of note, measurements include the drain negative pressure, whose monitoring may be particularly useful to prevent hemolysis. Real-time monitoring of vvECMO provides data helpful to understand the complex picture of a patient with severely damaged lungs on one side and an artificial lung on the other side. Data from vvECMO monitoring may help to adapt the settings of both mechanical ventilator and vvECMO. Data about oxygen transfer by the oxygenator are important to evaluate the performance of the device and may help to avoid unnecessary replacements, thus reducing risks and costs.

[The perfusion technologist: extracorporeal circulation and hemodialysis]. / Il tecnico perfusionista: la circolazione extracorporea e l'emodialisi.

In 1812, the French physiologist Le Gallois hypothesized a device for obtaining extracorporeal circulation (ECC), although it wasn't until 1939 that Gibbon described in detail a machine that could substitute both heart and lungs. In 1954, the US Cardiac Surgeon Lillhei invented 'cross circulation', and the era of open heart surgery began. The development of ECC has created a new profession in medicine, the 'Perfusion Technologist' who is not only responsible for ECC, but also for hemodialysis equipment when this is also required. The present review aims to summarize all issues related to this medical profession.

Minimally invasive heart-port assisted technique as standard first choice approach for left ventricle endoplasty: a ten-year single-center experience.

BACKGROUND: Although the port-access technique has been shown to be an effective and safe approach for cardiac surgery procedures it has never become routine practice, and it is still limited to few and selected centers. Furthermore, such technique has rarely been applied to treat left ventricle disease. In 1999 we introduced left ventricle aneurysm repair through a left minithoracotomy using the port-access technique. Here we present the results in terms of early and medium-term follow-up using such technique as a routine first choice approach for left ventricle endoplasty. METHODS: From 1999 to date, out of 38 patients undergoing left ventricle endoplasty (+/-associate procedures), mini-left thoracotomy and port-access techniques have been used in 32 patients (84%). All patients underwent endoventricular patch-repair with ventricular reshaping and associated procedures were performed in 8 patients. RESULTS: All patients survived the operation and were discharged from the hospital (30 days mortality 0%). Two patients (6.2%) experienced prolonged mechanical ventilations and 3 patients (9.3%) prolonged intensive care unit stay. Mean follow-up was 40+/-34 months (range, 2 to 105). One patient died during follow-up (cumulative mortality 3.3%). Follow-up revealed an improvement of hemodynamic performances (left ventricular ejection fraction 0.44+/-0.09 compared with 0.34+/-0.09 preoperatively, p=0.004) and improved clinical conditions (New York Heart Association class 1.4+/-0.5 compared with 2.3+/-1 preoperatively, p=0.003). CONCLUSIONS: The port-access technique can be safely applied to perform left ventricle endoplasty through a left minithoracotomy. Such approach allows optimal surgical view and therefore optimal surgical correction. Based on our satisfactory experience we support left minithoracotomy as a valuable alternative approach for left ventricle endoplasty in view of an extended use of minimally invasive techniques.

The axillary artery as an alternative site of cannulation for redo port access-assisted minimally invasive mitral valve surgery: early report of 2 cases.

The minimally invasive Heartport (HP)-assisted technique has become first choice option for mitral valve surgery in many centres.The pool of patients potentially treated using HP techniques, however, is still limited by the presence of peripheral vessel disease, expecially in the elderly population. Alternative approaches to using the HP technique safely in such a subset of patients, therefore, should be evaluated. Here, we present our preliminary experience using the axillary artery as an alternative site of cannulation for HP-assisted redo mitral valve surgery in patients with concomitant peripheral vessel disease.