Background We investigated the clinical significance of derivatives of reactive oxygen metabolites (DROMs), a new marker of reactive oxygen species, in patients with nonischemic heart failure (HF) and compared them among new categories of HF. Methods and Results We recruited 201 consecutively hospitalized patients with HF and measured DROM under stable conditions. Then, we divided them according to new categories of HF (HF with reduced ejection fraction [EF], HF with midrangeEF, and HF with preserved EF) without coronary artery disease. In subgroup analysis, we followed EF changes in patients with HF with reduced EF and classified them into HF with recovered EF or nonrecovered EF according to whether EF had improved to >40%. DROMs are significantly and independently associated with HF-related events in patients with NIHF. There were no significant differences in DROM and the probability of HF-related events among HF categories in Kaplan-Meier analysis. However, patients with HF with reduced EF and HF with preserved EF but not HF with midrange EF with HF-related events had higher DROM than those without HF-related events. In subgroup analysis, Kaplan-Meier analysis demonstrated that the probabilities of HF-related events in HF with recovered EF were dramatically decreased. DROM were significantly higher in patients with HF with nonrecovered EF than in HF with recovered EF. In receiver operating characteristic analysis, the cutoff level of DROM for predicting improvements in HF with recovered EF was 347 Carratelli units. Furthermore, the C-statistic value for predicting EF improvement for the DROM levels was 0.703. In multivariable logistic regression analysis, DROM was independently and significantly associated with the prediction of HF with recovered EF. Conclusions DROM measurements can provide important prognostic information for risk stratification in any category of NIHF. Registration URL: https://www.umin.ac.jp/ctr/; Unique identifier: UMIN000035827.
Keywords: follow‐up studies; nonischemic heart failure; prognosis; reactive oxygen species.