SUN-166 FACTORS THAT CONFOUND THE PREDICTION OF RENAL MEDULLARY OXYGENATION AND RISK OF ACUTE KIDNEY INJURY FROM MEASUREMENT OF BLADDER URINE OXYGEN TENSION.

Introduction: Urinary oxygen tension (PO2) may provide a useful estimate of renal medullary PO2 and thus risk of acute kidney injury (AKI). However, the relationship between urinary PO2 and medullary PO2 could be confounded by variations in urine flow and arterial PO2. In the current study we exploited data we had previously generated, from experimental studies in ovine septic AKI and in patients undergoing cardiac surgery requiring cardiopulmonary bypass (CPB), to perform a detailed analysis of the influences of urine flow and arterial PO2 on urinary PO2. We also investigated the potential for simultaneous measurement of urine flow and urinary PO2, during CPB, to improve prediction of AKI over that provided by measurement of each variable on its own. Method(s): In ovine septic AKI urine flow, urinary PO2, arterial PO2, and medullary PO2 were measured. In human patients undergoing cardiac surgery requiring CPB urinary PO2 and arterial PO2 were measured continuously and urine flow was estimated every 5 minutes. Result(s): In 28 conscious septic sheep breathing room air, urinary PO2 was more closely correlated with medullary PO2 (r2=0.29) than with arterial PO2 (r2=0.06) or urine flow (r2=0.03). The difference between medullary PO2 and urinary PO2 varied little with urine flow or arterial PO2. In 20 patients, urine flow increased abruptly from 2.81 +/- 0.24 mL/min to 6.53 +/- 0.30 mL/min upon commencement of CPB, usually coincident with a fall in urinary PO2 (Fig. 1). During hyperoxic CPB high values of urinary PO2 were often observed at low urine flow. In 65 patients, low urinary PO2 during CPB (<10 mmHg at any time during CPB) was associated with greater (4.5-fold) risk of AKI. However, the level of urine flow on bypass was not significantly associated with risk of AKI. [Figure presented] Conclusion(s): We developed a method for virtually continuous measurement of urine flow in the operating theatre. We found that urinary PO2 provides a relatively robust estimate of