Articles: extravascular-lung-water.
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In patients with multiple injuries, the development of permeability edema can be assumed. However, no uniform shape of this fluid accumulation can be found even in the presence of severe injuries. Based on the first clinical observations, our aim was to search for correlations between the development of extravascular lung water (EVLW) and the individual injury pattern in severely traumatized ICU patients. ⋯ Increase of EVLW at a later time (day 7), as observed in groups B and C, is possibly the expression of a mediator and activator-induced "septiformal" injury of the microvascular endothelium. This may be caused by the underlying massive peripheral soft-tissue trauma. Specific elevations of EVLW subsequent to the individual injury pattern can indicate that that process has begun and is responsible for the origin of the microvascular injuries.
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Acta Anaesthesiol Scand · Jul 1990
Lung fluid balance evaluated by the rate of change of extravascular lung water content.
Lung fluid balance was studied in 27 mongrel dogs by measuring changes in extravascular lung water content (EVLW). The expression delta EVLWi, which is the difference in EVLWi per kilo bodyweight per hour between two measurement occasions, was used as an estimate of the rate of change of EVLW. EVLW was measured by a double-indicator dilution technique (EVLWi) using iced glucose and indocyanine green. ⋯ OA-induced oedema caused a mean maximum delta EVLWi of 5.1 ml/kg/h, indicating capillary leakage which, however, was self-limiting within 2 h after OA injection. In hydrostatic oedema there was a maximum delta EVLWi of 16.0 ml/kg/h. Delta EVLWi was negative after deflation of the left atrial balloon, indicating reabsorption of oedema.
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Extravascular lung water (EVLW) can be measured using the double indicator dilution technique (DD). However, because this method is highly invasive and complicated, its clinical used has been limited. In theory, changes in thoracic conductivity, or bioimpedance (BI), can reflect changes in EVLW. ⋯ In early sepsis (30 min), BI overestimated EVLW when compared with DD (P less than 0.05). However, at 1, 2, and 4 hr there was no significant difference between the two methods. In conclusion, the use of bioimpedance and a volumetric catheter may provide a relatively simple and reliable method for continuously monitoring changes in EVLW in the intensive care setting.
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J Cardiothorac Anesth · Feb 1990
Randomized Controlled Trial Clinical TrialLung management during cardiopulmonary bypass: influence on extravascular lung water.
Progressive respiratory insufficiency secondary to cardiopulmonary bypass (CPB) is still a hazard after cardiac surgery. Pathophysiologically, impaired capillary endothelial integrity seems to be the fundamental lesion, followed by increased interstitial fluid accumulation. The reasons for this pulmonary damage are controversial; however, management of the nonperfused lungs during CPB has been widely neglected and may be partly responsible. ⋯ Measurements were performed after induction of anesthesia, before onset of CPB, and immediately after weaning from bypass, as well as 60 minutes and 5 hours after termination of CPB. Pulmonary gas exchange (PaO2) and intrapulmonary shunting (Qs/Qt) were also measured. Starting from comparable, normal baseline values, EVLW was increased in all groups after weaning from CPB, with the most pronounced increase in group 4 (maximum, +35%) and group 5 (+40%).(ABSTRACT TRUNCATED AT 250 WORDS)
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Intensive care medicine · Jan 1990
Measurement of extravascular lung water by thermal-dye dilution technique: mechanisms of cardiac output dependence.
The extent to which extravascular lung water (EVLW) is dependent on cardiac output was analysed in anaesthetized and mechanically ventilated pigs. EVLW was measured by thermal-dye dilution technique, by a fibreoptic thermistor catheter system (system 1), and by a thermistor catheter-external optical cuvette system (system 2). During baseline conditions, at which cardiac output was 3.65 l/min, and EVLW was 11.7 and 7.7 ml/kg b.w. with systems 1 and 2 respectively. ⋯ With system 1 the CO dependence was due to different time constants in thermistor and optical systems, and with appropriate phasing the dependence could be eliminated. With system 2 a large overestimation of the mean transit time difference between the two indicators was seen when cardiac output was low, resulting in overestimation of EVLW. It is concluded that the dependence of EVLW volume on cardiac output is an artefact due to technical problems in the design of the recording equipment rather than a reflection of pulmonary or vascular effects.