1. Extracorporeal gas exchange: when to start and how to end?
- Author
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Michael Quintel, Federica Romitti, Francesco Vassalli, Luciano Gattinoni, Eleonora Duscio, Iacopo Pasticci, and Francesco Vasques
- Subjects
medicine.medical_specialty ,Extracorporeal Circulation ,medicine.medical_treatment ,Hemodynamics ,Review ,Critical Care and Intensive Care Medicine ,Extracorporeal ,Artificial lung ,03 medical and health sciences ,0302 clinical medicine ,Extracorporeal Membrane Oxygenation ,Internal medicine ,Extracorporeal membrane oxygenation ,medicine ,Humans ,Lung ,business.industry ,lcsh:Medical emergencies. Critical care. Intensive care. First aid ,030208 emergency & critical care medicine ,Blood flow ,Oxygenation ,Venous blood ,lcsh:RC86-88.9 ,Respiration, Artificial ,medicine.anatomical_structure ,Cardiology ,business ,Respiratory Insufficiency - Abstract
In the last decade, primarily following the H1N1 pandemics [1], the extracorporeal respiratory assist is increasingly used [2, 3]. The acronym “ECMO”, i.e., ExtraCorporeal Membrane Oxygenation, is, however, somehow misleading as the artificial extracorporeal assist may affect both oxygenation and CO2 removal, as well as the hemodynamics, depending on how it is applied. In this commentary, we will limit our discussion to the respiratory extracorporeal support in veno-venous mode, primarily discussing the aspects, which are usually under-evaluated. Various options for extracorporeal support Table 1 was first published more than 40 years ago [4] and summarizes the main characteristics and options through which the extracorporeal support may be applied. As shown, all the possible application were foreseen and most of them actually tested in the following years. As shown, two main features characterize the extracorporeal support: cannulation (veno-venous vs veno-arterial) and extracorporeal blood flow. In the veno-venous configuration, the artificial and the natural lung are connected in series, as the blood flow entering the membrane lung is re-directed into the natural lung, after the artificial gas exchange. The hemodynamics are not affected by this configuration, which works solely as a respiratory support. In contrast, in the veno-arterial configuration, the artificial and the natural lung are arranged in parallel: the flow leaving the artificial lung is diverted in the arterial section and the natural lung is proportionally under-perfused. The greatest difference between veno-venous and veno-arterial approach is not related to the gas exchange, as the amount of oxygen transferred and CO2 removed are exactly the same (if the operating conditions of the membrane lung are the same), but to the hemodynamic impact, as the veno-arterial configuration provides both respiratory and cardiac support. The second feature is the amount of blood flow and gas flow used to ventilate the artificial lung: to oxygenate venous blood entering the membrane lung, the gas flow required equals the oxygen sufficient to fully saturate the hemoglobin passing through the artificial lung. As an example, if 1 l of venous blood with10 g/dL of hemoglobin and saturation 70% enters the membrane lung every minute, a transfer of 42 ml of 100% oxygen per minute from the gas compartment of the membrane lung would be sufficient to fully saturate the blood leaving the membrane lung. Therefore, being the possibility to “charge” oxygen limited by the hemoglobin concentration and its saturation in the venous blood, the oxygen transfer to the membrane lung is primarily function of the extracorporeal blood flow. In the previous example, 4 l of extracorporeal blood flow, in the absence of re-circulation, would provide fully saturated blood with a gas flow into the membrane lung of only 168 ml/min. All the gas is absorbed, and no gas leaves the membrane lung Table 1 Comparative technical difficulty of hemodialysis, extracorporeal removal of carbon dioxide, and extracorporeal oxygenation
- Published
- 2019