ObjectivesTechnical complications are a known hazard in veno-venous extracorporeal membrane oxygenation (vvECMO). Identifying these complications and predictive factors indicating a developing system-exchange was the goal of the study.MethodsRetrospective study on prospectively collected data of technical complications including 265 adult patients (Regensburg ECMO Registry, 2009-2013) with acute respiratory failure treated with vvECMO. Alterations in blood flow resistance, gas transfer capability, hemolysis, coagulation and hemostasis parameters were evaluated in conjunction with a system-exchange in all patients with at least one exchange (n = 83).ResultsValues presented as median (interquartile range). Patient age was 50(36–60) years, the SOFA score 11(8–14.3) and the Murray lung injury Score 3.33(3.3–3.7). Cumulative ECMO support time 3411 days, 9(6–15) days per patient. Mechanical failure of the blood pump (n = 5), MO (n = 2) or cannula (n = 1) accounted for 10% of the exchanges. Acute clot formation within the pump head (visible clots, increase in plasma free hemoglobin (frHb), serum lactate dehydrogenase (LDH), n = 13) and MO (increase in pressure drop across the MO, n = 16) required an urgent system-exchange, of which nearly 50% could be foreseen by measuring the parameters mentioned below. Reasons for an elective system-exchange were worsening of gas transfer capability (n = 10) and device-related coagulation disorders (n = 32), either local fibrinolysis in the MO due to clot formation (increased D-dimers [DD]), decreased platelet count; n = 24), or device-induced hyperfibrinolysis (increased DD, decreased fibrinogen [FG], decreased platelet count, diffuse bleeding tendency; n = 8), which could be reversed after system-exchange. Four MOs were exchanged due to suspicion of infection.ConclusionsThe majority of ECMO system-exchanges could be predicted by regular inspection of the complete ECMO circuit, evaluation of gas exchange, pressure drop across the MO and laboratory parameters (DD, FG, platelets, LDH, frHb). These parameters should be monitored in the daily routine to reduce the risk of unexpected ECMO failure.
The development of vessel-like structures in vitro to mimic as well as to realize the possibility of tissue-engineered small vascular networks presents a major challenge to cell biologists and biotechnologists. We aimed to establish a three-dimensional (3-D) culture system with an endothelial network that does not require artificial substrates or ECM compounds. By using human skin fibroblasts and endothelial cells (ECs) from the human umbilical vein (HUVECs) in diverse spheroid coculture strategies, we verified that fibroblast support and modulate EC migration, viability, and network formation in a 3-D tissue-like stromal environment. In mixed spheroid cultures consisting of human ECs and fibroblasts, a complex 3-D network with EC tubular structures, lumen formation, pinocytotic activity, and tight junction complexes has been identified on the basis of immunohistochemical and transmission electron microscopic imaging. Tubular networks with extensions up to 400 m were achieved. When EC suspensions were used, EC migration and network formation were critically affected by the status of the fibroblast. However, the absence of EC migration into the center of 14-day, but not 3-day, precultured fibroblast spheroids could not be attributed to loss of F viability. In parallel, it was also confirmed that migrated ECs that entered cluster-like formations became apoptotic, whereas the majority of those forming vessel-like structures remained viable for Ͼ8 days. Our protocols allow us to study the nature of tubule formation in a manner more closely related to the in vivo situation as well as to understand the basis for the integration of capillary networks in tissue grafts and develop methods of quantifying the amount of angiogenesis in spheroids using fibroblast and other cells isolated from the same patient, along with ECs. endothelium; angiogenesis; human umbilical vein endothelial cell; multicellular spheroid; coculture; tubular structures ANGIOGENESIS IS A COMPLEX morphogenetic process initiated primarily by sprouting of endothelial capillaries from existing blood vessels to form an endothelial plexus. After being remodeled, the vasculature matures by recruitment of perivascular cells and smooth muscle cells. Vascular maturation attenuates the rate of vascular sprouting and prevents vascular collapse and regression (18,24), which is partly reflected by contact inhibition of endothelial cell (EC) proliferation in coculture systems with pericytes or smooth muscle cells (7,12,29,47). In adults, the angiogenic process is essential during wound healing, tissue repair, and remodeling and for female reproductive cycles, among many normal and pathological conditions. Mechanistic studies designed to gain a better understanding of, and an ability to manipulate, the angiogenic process in health and disease have intensified during the past 30 years, having been stimulated by Folkman's (2,16,19,25,27) initial hypotheses regarding the angiogenic switch during tumor cell growth and the development of the concept of antiangiogenic ther...
The aim of the study was to explore the prevalence and risk factors for technical-induced hemolysis in adults supported with veno-venous extracorporeal membrane oxygenation (vvECMO) and to analyze the effect of hemolytic episodes on outcome. This was a retrospective, single-center study that included 318 adult patients (Regensburg ECMO Registry, 2009–2014) with acute respiratory failure treated with different modern miniaturized ECMO systems. Free plasma hemoglobin (fHb) was used as indicator for hemolysis. Throughout a cumulative support duration of 4,142 days on ECMO only 1.7% of the fHb levels were above a critical value of 500 mg/l. A grave rise in fHb indicated pumphead thrombosis (n = 8), while acute oxygenator thrombosis (n = 15) did not affect fHb. Replacement of the pumphead normalized fHb within two days. Neither pump or cannula type nor duration on the first system was associated with hemolysis. Multiple trauma, need for kidney replacement therapy, increased daily red blood cell transfusion requirements, and high blood flow (3.0–4.5 L/min) through small-sized cannulas significantly resulted in augmented blood cell trauma. Survivors were characterized by lower peak levels of fHb [90 (60, 142) mg/l] in comparison to non-survivors [148 (91, 256) mg/l, p≤0.001]. In conclusion, marked hemolysis is not common in vvECMO with modern devices. Clinically obvious hemolysis often is caused by pumphead thrombosis. High flow velocity through small cannulas may also cause technical-induced hemolysis. In patients who developed lung failure due to trauma, fHb was elevated independantly of ECMO. In our cohort, the occurance of hemolysis was associated with increased mortality.
Bioline-coated polymethylpentene (PMP) membrane oxygenators (MO) are used for extracorporeal membrane oxygenation (ECMO) to improve gas exchange in patients with severe acute respiratory distress syndrome (ARDS). However, in some patients, long-term durability is limited due to fibrous and cellular accumulations on the gas exchange surface which can increase resistance to blood flow and diffusion path. These surface deposits of PMP MO after removal were studied with scanning electron and fluorescence microscopy techniques. Three of 31 patients supported by a PMP MO in an ECMO setting required a replacement of the oxygenator after a mean support interval of 11 +/- 7 days due to an increase in flow resistance and an impairment of the gas exchange capacity. The membrane surface of the MO was covered with a fibrous network with imbedded platelets and red blood cells. A membranous structure composed of single cells and clusters of cells covered large areas of the PMP fibers. We assume that these cellular deposits lower the efficacy of ECMO. The identification of these cells could be a key for future therapeutic interventions and improvements in the development of MO.
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