Hypovolemia Clinical Trial
Official title:
Effects of Supplemental Oxygen on Systemic and Cerebral Hemodynamics in Experimental Hypovolemia
Supplemental oxygen is frequently administered in acutely and critically ill patients, specifically, it is often administered in trauma patients to avoid arterial hypoxemia and tissue hypoxia. There is also an increasing focus on potentially deleterious effects of hyperoxia. Further, the hemodynamic response to hyperoxia in hypovolemia is poorly understood. The present study aims to investigate the effects of supplemental oxygen on systemic and cerebral hemodynamics in simulated hypovolemia in healthy volunteers.
The overriding goal for the resuscitation of any critically ill patient is to ensure adequate oxygen delivery. In critically ill patients, SaO2 and PaO2 may be reduced due to lung dysfunction (e.g. atelectasis and shunt flow). Under normal circumstances, SaO2 is near to 100%, and supplemental oxygen can not increase this further. Thus, in this circumstance, providing supplemental oxygen will only increase a small, dissolved proportion. Although this proportion may be a significant fraction in some circumstances, the intention of giving supplemental oxygen is in most circumstances to ensure a high SaO2. Supplemental oxygen has been extensively used in acutely critically ill patients to avoid hypoxemia, and is recommended in severely injured trauma patients, as given by the statement: "Supplemental oxygen must be administered to all severely injured trauma patients." in the ATLS (Advanced Trauma Life Support) guidelines. Accordingly, supplemental oxygen is often given to trauma patients, often resulting in hyperoxia. The clinical evidence for providing supplemental oxygen in all trauma patients is however scarce. The liberal use of supplemental oxygen has also largely been founded on a perception that supplemental oxygen is harmless, and that it is safer to err on the side of hyperoxia. There is however an increasing focus on possible deleterious effects of hyperoxia, especially in specific clinical circumstances. This has led to recommendations of more restrictive use of supplemental oxygen, often titrated to no more than what is necessary to achieve an adequate arterial oxygen saturation (e.g. in the range 94-98%). In the initial treatment of trauma patients, detection and treatment of hypovolemia is of paramount importance. Hypovolemia leads to reduced cardiac filling and stroke volume. Under normal circumstances in unanesthetized humans, this is compensated by an increase in systemic vascular resistance and heart rate to maintain a normal or near-normal mean arterial pressure (MAP). At some point, these compensatory mechanisms are exhausted, and MAP typically falls abruptly. Lower body negative pressure (LBNP) is a model of central hypovolemia where negative pressure is applied to the body from the waist-down. Thereby, blood is displaced from the central compartment of the upper body to the lower extremities and pelvis. The model has been used for more than half a century and is considered useful model for studying hypovolemia in conscious volunteers. Normobaric hyperoxia induces vasoconstriction and reduced blood flow to several organs, including the brain, heart and skeletal muscle. One could therefore hypothesize hyperoxia leading to both an increased tolerance to hypovolemia mediated by vasoconstriction as well as a reduced tolerance mediated by reduced cerebral blood flow. One study using the LBNP-model did not find that supplemental oxygen significantly affected the hemodynamic response to simulated hypovolemia. This study did however only apply one level of LBNP and did not specifically study cerebral circulation. Based on the above, there is a need for studies on the effects of normobaric hyperoxia on the hemodynamic response to hypovolemia. In the present study, we will study the effect of supplemental oxygen in the LBNP-model of hypovolemia in a crossover study on healthy volunteers. In the present study, 15 healthy volunteers will be exposed to LBNP with oxygen or room air in randomized order in a crossover fashion. We will measure cardiac outout, stroke volume and middle cerebral artery blood velocity to explore effects of oxygen on these variables during hypovolemia. ;
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