Publication Description
Aims/Introduction
Cardiovascular autonomic neuropathy (CAN) is a predictor of cardiovascular disease and mortality. Cardiovascular reflex tests (CARTs) are the gold standard for the diagnosis of CAN, but might not be feasible in large research cohorts or in clinical care. We investigated whether measures of heart rate variability obtained from standard electrocardiogram (ECG) recordings provide a reliable measure of CAN.
Materials and Methods
Standardized CARTs (R‐R response to paced breathing, Valsalva, postural changes) and digitized 12‐lead resting ECGs were obtained concomitantly in Diabetes Control and Complications Trial/Epidemiology of Diabetes Interventions and Complications participants (n = 311). Standard deviation of normally conducted R‐R intervals (SDNN) and the root mean square of successive differences between normal‐to‐normal R‐R intervals (rMSSD) were measured from ECG. Sensitivity, specificity, probability of correct classification and Kappa statistics evaluated the agreement between ECG‐derived CAN and CARTs‐defined CAN.
Results
Participants with CARTs‐defined CAN had significantly lower SDNN and rMSSD compared with those without CAN (P < 0.001). The optimal cut‐off points of ECG‐derived CAN were <17.13 and <24.94 ms for SDNN and rMSSD, respectively. SDNN plays a dominant role in defining CAN, with an area under the curve of 0.73, indicating fair test performance. The Kappa statistic for SDNN was 0.41 (95% confidence interval 0.30–0.51) for the optimal cut‐off point, showing fair agreement with CARTs‐defined CAN. Combining SDNN and rMSSD optimal cut‐off points does not provide additional predictive power for CAN.
Conclusions
These analyses are the first to show the agreement between indices of heart rate variability derived from ECGs and the gold standard CARTs, thus supporting potential use as a measure of CAN in clinical research and clinical care.
Participants with cardiovascular reflex tests‐defined cardiovascular autonomic neuropathy (CAN) had significantly lower standard deviation of normally conducted R‐R intervals and root mean square of successive differences between normal‐to‐normal R‐R intervals compared to those without CAN (P < 0.001). standard deviation of normally conducted R‐R intervals plays a dominant role in defining CAN, with an area under the curve of 0.73, indicating fair test performance. The Kappa statistics for standard deviation of normally conducted R‐R intervals was 0.41 (95% confidence interval 0.30–0.51) for the optimal cut‐off point, showing fair agreement with cardiovascular reflex tests‐defined CAN.