Mechanical Ventilation Based on Driving Pressure in Lateral Position

Summary

Participation Requirements

Description

There may be physiologic and pathologic pulmonary changes because of inflammatory cytokine release during total hip replacement surgery due to surgical invasivity or advanced age, comorbidities, perioperative immobility of patients. Also intraoperative mechanical ventilation can cause volutrauma, ba...

There may be physiologic and pathologic pulmonary changes because of inflammatory cytokine release during total hip replacement surgery due to surgical invasivity or advanced age, comorbidities, perioperative immobility of patients. Also intraoperative mechanical ventilation can cause volutrauma, barotrauma or atelectrauma risk because of lateral position during hip replacement surgery. All these factors can cause pulmonary complications and vascular permeability increase in dependent and independent regions due to neutrophil response increase. Intraoperative hypovolemia is often observed in this group patients because of preoperative prolonged fasting periods, insufficient fluid intake due to preoperative delirium and depression. Also mechanical ventilation with positive pressure slightly decreases venous return to the heart resulting decrease in cardiac output. It is more obvious in the presence of hypovolemia. Providing continuous sufficient intravascular volume is necessary for prevention of tissue hypoxia and providing optimal cardiac output. It is known that intra operative hemodynamic optimisation, has positive effects on mortality ratio. But proper intravascular volume is not always easy to maintain, and it is not always easy for anaesthetists to identify deficiency or overload of intra operative intravascular volume. In recent years, intravascular volume therapies are goal directed by the reflections of respiratory mechanics on arterial pressure and pulse oximetry. Plethysmographic wave changes observed in pulse oximetry induced by positive pressure ventilation is accepted as indicator of hypovolemia. Hemodynamic changes induced by respiratory mode can be measured by invasive arterial monitorization. This dynamic variable is called as pulse pressure variation index and is correlated with amplitude changes observed in pulse oximetry signals. These variations are based on changes observed in pulse wavelength due to the changes in intrathoracic pressure. In some pulse oximetry devices, this is done as standard function as path variability index (PVI). PVI is measurement of dynamic changes of perfusion index during a whole respiratory cycle. Pulse oximetry wave length changes enables the evaluate hypovolemia noninvasively. PVI is gaining importance as a dynamic parameter in evaluating fluid treatment during surgery. Goal directed fluid therapy has shown positive effects on results on patient survival. In a study which fluid therapy was guided by PVI changes and it was reported that, goal directed fluid therapy had positive results.The investigators also, use some invasive and noninvasive monitorization techniques, including PVI and CVP, to monitor static and dynamic hemodynamic parameters during hip replacement surgery and we apply fluids according to our fluid therapy protocols. The investigators use blood gas analysis to monitor the efficiency of this treatment. In this study, in both groups the investigators will apply fluid according to PVI values, so if any difference detected is observed between groups will be because of the differences of respiratory parameters between groups. And the investigators can detect, PVI stability and less fluid needs differences between groups. PETCO2 is, another parameter which will be evaluated in this study, is a factor of tissue CO2 production (VCO2), alveolar ventilation and cardiac output (mainly pulmonary blood flow). It is known that, when CO2 produced at the tissues and formed in lungs are constant, the changes of etCO2 are due to the blood flow differences and it is related to changes of cardiac output. For this reason, PETCO2 is suggested as a noninvasive measure for continuous assessment of cardiac output. At the same time, it is possible to comment about changes of dead space by measuring arterial CO2 pressure. Decrease of PETCO2, resulted from cardiac output decrease, can not be explained only with the decrease rate of excretion of CO2, but also can be explained by the changes of production of CO2 caused by dependency to oxygen supply. On the contrary, when cardiac output is high, pulmonary blood flow is no longer a limiting factor for PETCO2 formation, and PETCO2 is related to sufficiency of alveolar ventilation. As a result, etCO2 measurement has some advantages; it is simple noninvasive and does not require a invasive hemodynamic measurement.

Tracking Information