We aimed to test whether the use of novel pulse oximetry sounds (sonifications) better informs listeners when a neonate’s oxygen saturation (SpO2) deviates from the recommended range.
Background
Variable-pitch pulse oximeters do not accurately inform clinicians via sound alone when SpO2 is outside the target range of 90% to 95% for neonates on supplemental oxygen. Risk of blindness, organ damage, and death increase if SpO2 remains outside the target range. A more informative sonification may improve clinicians’ ability to maintain the target range.
Method
In two desktop experiments, nonclinicians’ ability to detect SpO2 range and direction of change was tested with novel versus conventional sonifications of simulated patient data. In Experiment 1, a “shoulder” sonification used larger pitch differences between adjacent saturation percentages for SpO2 values outside the target range. In Experiment 2, a “beacon” sonification used equal-appearing pitch differences, but when SpO2 was outside the target range, a fixed-pitch reference tone from the center of the target SpO2 range preceded every fourth pulse tone.
Results
The beacon sonification improved range identification accuracy over the control display (85% vs. 60%; p < .001), but the shoulder sonification did not (55% vs. 52%).
Conclusion
The beacon provided a distinct auditory alert and reference that significantly improved nonclinical participants’ ability to identify SpO2 range.
Application
Adding a beacon to the variable-pitch pulse oximeter sound may help clinicians identify when, and by how much, a neonate’s SpO2 deviates from the target range, particularly during patient transport situations when auditory information becomes essential.
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