https://orcid.org/0009-0002-3723-3206
Figures
Abstract
Background
Dilated cardiomyopathy (DCM) is a major cause of heart failure and sudden cardiac death (SCD), with a 5-year survival rate of approximately 45%–50%. Current risk stratification is predominantly dependent on left ventricular ejection fraction (LVEF), which has limited sensitivity and specificity. Hence, more effective biomarkers should be used in late gadolinium enhancement (LGE)-negative patients.
Methods
A total of 378 consecutive patients with LGE-negative DCM were enrolled from four hospitals between December 2016 and December 2022. Cardiac magnetic resonance imaging-derived strain parameters (global radial strain, global circumferential strain, and global longitudinal strain [GLS]) were assessed against the primary (SCD and related events) and secondary (heart failure, appropriate implantable cardioverter-defibrillator therapy) endpoints. Internal validation was performed using stratified bootstrap resampling with Harrell’s optimism correction to report the optimism-corrected C-index. Data were accessed for research purposes from 15/06/2023–30/12/2023, and all records were de-identified prior to analysis.
Results
Over a median follow-up of 59.78 months, 35 (9.26%) and 72 (19.0%) patients presented with the primary and secondary endpoints, respectively. Based on the multivariate Cox analysis, GLS, LVEF, and age were independent prognostic factors. However, only GLS (HR = 1.37; P = 0.041) remained significant in the LVEF <20% subgroup. A model integrating GLS and LVEF had a better discrimination ability for SCD than LVEF strata alone (apparent C-index 0.756 vs 0.714, P < 0.001). This advantage persisted after bootstrap internal validation (B = 1000; optimism-corrected C-index 0.754 vs 0.711, Holm adjusted P = 0.048). Further inclusion of age and New York Heart Association (NYHA) classification enhanced the model’s performance (model 4): apparent C-index 0.801; optimism-corrected C-index 0.785).
Conclusion
GLS is an independent predictor of SCD-related events in LGE-negative DCM. Incorporating GLS with conventional indicators such as age, NYHA classification, and LVEF significantly enhances prognostic discrimination and model robustness, indicating potential value for future clinical risk stratification.
Citation: Zhang T-Y, Lan T, Wang L-L, Zheng Y-C, Feng X-Y, Wang F-Y, et al. (2026) Prognostic value of cardiac magnetic resonance–derived global longitudinal strain in LGE-negative dilated cardiomyopathy. PLoS One 21(3): e0345077. https://doi.org/10.1371/journal.pone.0345077
Editor: Vincenzo Lionetti, Scuola Superiore Sant'Anna, ITALY
Received: December 18, 2025; Accepted: March 2, 2026; Published: March 27, 2026
Copyright: © 2026 Zhang et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: Owing to ethical restrictions concerning patient privacy and the presence of potential indirect identifiers in the dataset, the data are not publicly available. Data are available from the Ethics Committee of Affiliated Hospital of North Sichuan Medical College. (contact via cbyxyfsyykjb@126.com) for researchers who meet the criteria for access to confidential data.
Funding: Supported by Health Commission of Sichuan Province Medical Science and Technology Program (No. 24WXXT10), National Natural Science Foundation of China (No. 82102022) and Sichuan Province Science and Technology Support Program (No. 2021YJ0242). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
1. Introduction
Dilated cardiomyopathy (DCM), which is characterized by left ventricular dysfunction, affects approximately 0.04% of adults, and it is the most common type of cardiomyopathy [1]. However, the prognostic outcomes of DCM vary widely among individuals, with 5-year mortality rates of 20%–50% [2,3], thereby underscoring the urgent need for reliable risk stratification markers [3]. Replacement myocardial fibrosis, as detected on late gadolinium enhancement (LGE) on cardiac magnetic resonance imaging (CMR), is a major contributor to adverse cardiovascular events, particularly ventricular arrhythmias (VAs) and sudden cardiac death (SCD) [4–7]. Nevertheless, LGE is only detectable in approximately 40% of patients with DCM [8,9], highlighting the need for alternative prognostic indicators in a substantial proportion of LGE-negative individuals who remain at substantial risk and require precise risk assessment. Currently, left ventricular ejection fraction (LVEF) remains a key parameter for risk stratification in patients with DCM [10–12], reflecting global cardiac function and contractile performance. However, LVEF has significant limitations, particularly its reduced predictive power for adverse events in patients with preserved ejection fraction, which requires the development of more comprehensive assessment approaches. Importantly, a significant reduction in LVEF has not been observed in the majority of patients with DCM who experienced SCD events over the last 15 years, indicating that reliance on LVEF alone does not yield highly precise prognostic information [13,14]. In a multicenter cohort study, Di Marco et al. used a multiparametric stratification model integrating both LVEF strata (≤20%, 21%–35%, > 35%) and LGE status. Results showed that even among patients with severely reduced LVEF (≤20%), those who are LGE negative still exhibited a significant residual risk (annual event rate: 2.7% vs. 8.1% in LGE-positive counterparts). Based on this study, two important needs were identified: improved risk discrimination among patients with preserved LVEF via myocardial tissue characterization and more refined substratification in populations with severely reduced LVEF using advanced phenotypic profiling [14].
In recent years, cardiac magnetic resonance feature tracking (CMR-FT) has facilitated the assessment of myocardial deformation using conventional cine cardiac sequences. Myocardial strain parameters derived from CMR-FT can detect subtle myocardial injuries even before the appearance of LGE [15–17]. Hence, CMR-FT can be a valuable tool for the early evaluation of myocardial dysfunction—an independent risk factor for adverse events in patients with DCM [18,19]. However, with increasing research advancements, it has become clear that relying on a single parameter for prognostic assessment in DCM is insufficient, as it fails to comprehensively identify patient outcomes. In particular, a few studies have addressed the prognosis of LGE-negative patients, a subgroup that requires special attention due to the absence of conventional fibrosis markers typically used in risk stratification. To address this unmet need, the current study aimed to explore the prognostic value of myocardial strain parameters in patients with LGE-negative DCM. Further, novel risk stratification models were developed by integrating myocardial strain measurements with different LVEF strata, thereby offering a more refined approach to prognostic evaluation in this clinically important population.
2. Materials and Methods
2.1. Study population
Newly diagnosed DCM inpatients were consecutively enrolled from four hospitals between December 2016 and December 2022 (Fig 1). All participants underwent baseline CMR during the index hospitalization as part of the initial diagnostic work-up. The local ethics committee approved the study protocol (approval no. 2021ER134−1) and waived the need for informed consent due to the study’s retrospective design. Data were accessed for research purposes from 15/06/2023–30/12/2023, and all records were de-identified prior to analysis. DCM was diagnosed according to the 2023 ESC guidelines [1], requiring an LVEF <45%, LV dilation (LV end-diastolic volume index >117% of predicted), and exclusion of other causes (e.g., coronary artery disease with ≥50% stenosis, primary valvular heart disease, hypertension, and tachyarrhythmia). The exclusion criteria included ischemic cardiomyopathy, acute/subacute myocarditis, other types of cardiomyopathies, and MRI contraindications. Patients were also excluded if CMR image quality was insufficient for reliable feature-tracking/strain quantification (e.g., severe respiratory motion, arrhythmia-related ECG-gating artifacts, or device/metal-related artifacts, including cases with low signal-to-noise or incomplete LV coverage) (Fig 1).
DCM = dilated cardiomyopathy, LGE = late gadolinium enhancement, CMR = cardiac magnetic resonance.
2.2. CMR protocols and image analysis
In all cases, CMR imaging was performed using 3.0-T scanners equipped with vector electrocardiography and respiratory gating systems. A balanced steady-state free precession sequence was used to acquire cine images in the short-axis, two-chamber, three-chamber, and four-chamber views of the left ventricle. LGE imaging was conducted 10–15 min after the intravenous administration of gadolinium-based contrast agents, utilizing a phase-sensitive inversion recovery sequence to obtain short-axis and four-chamber images. Images were analyzed offline using a dedicated software (CVI 42, Circle Cardiovascular Imaging, Inc., Calgary, Canada) by two blinded, experienced radiologists (*.*. and *.*.*.). The presence of LGE was evaluated across long-axis, short-axis, and four-chamber views. The myocardial strain analysis was based on manual delineation of endocardial and epicardial borders at end-diastole, excluding the papillary muscles and chordae. Then, the software automatically generated global myocardial strain parameters and corresponding “bull’s-eye” maps (Fig 2).
Inter- and intra-observer variability for strain measurements was assessed by comparing the analyses of two independent observers with at least 2-week interval between readings, thereby maintaining blinding to previous results. The coefficient of variation (CV) was calculated using the following formula: CV (%) = (s/X) × 100, where s represents the standard deviation and X indicates the mean of the measurements. Precision was expressed as the average %CV. If the CV was < 15%, the initial measurements were considered final.
2.3. Follow-up
Follow-up data were collected by reviewing hospital records, outpatient clinic visits, or telephone interviews conducted by a committee of radiologists who were blinded to the CMR findings. Duration of disease was defined as the time interval from the documented diagnosis of dilated cardiomyopathy to the baseline CMR examination (the first CMR performed after diagnostic confirmation). As baseline CMR was acquired as part of the initial diagnostic work-up, the timing of CMR relative to initiation and subsequent optimization of guideline-directed medical therapy was not predefined or standardized. Follow-up duration was defined as the interval from the initial CMR examination to the occurrence of an endpoint event or the last recorded patient contact. The primary endpoints were SCD, aborted SCD, and cardiac arrest secondary to ventricular fibrillation or sustained ventricular tachycardia. The secondary endpoint was a composite of all-cause mortality, heart failure-related rehospitalization, heart transplantation, and appropriate implantable cardioverter-defibrillator (ICD) therapy.
2.4. Statistical analysis
Statistical analyses were conducted using the Statistical Package for the Social Sciences software (version 26.0; IBM Corp., Armonk, NY, the USA) and R Studio (version 4.3.3). Continuous variables were presented as the mean ± standard deviation or the median with interquartile range (IQR), as appropriate. Meanwhile, categorical variables were expressed as the frequencies and percentages. Group comparisons for continuous variables were made using the independent Student’s t-test, one-way analysis of variance, or Mann–Whitney U test. The χ² test was used for categorical variables. The survival analysis included Kaplan–Meier curves with log-rank tests and univariate Cox regression to identify the risk factors of the primary and secondary outcomes. Significant variables from the univariate analysis and clinically relevant factors were included in the multivariate Cox models, with multicollinearity assessed using the variance inflation factor.
Four Cox models were developed and internally validated on complete-case data: model 1 (GLS), model 2 (LVEF), model 3 (GLS+LVEF), and model 4 (GLS+LVEF+age+NYHA). Model discrimination was evaluated using the Harrell’s C-index, reported as apparent and optimism-corrected (via stratified bootstrap, B = 1,000). Pairwise comparisons of ΔC used the same resamples with two-sided sign tests and Holm correction. A two-sided P-value of <0.05 indicated statistically significant differences. In parallel, hierarchical (block-entry) Cox models were used to test the incremental value of GLS beyond established clinical and conventional remodeling indices for both endpoints. We evaluated GLS on top of (i) Age + NYHA class (III/IV vs I/II) plus left atrial diameter (LAD), left ventricular mass index (LVMassi), or left ventricular end-diastolic volume index (LVEDVi), and (ii) logNT-proBNP plus LAD/LVMi/LVEDVi. The incremental value of GLS was assessed using likelihood-ratio tests comparing nested models; discrimination was reported using Harrell’s C-index.
3. Results
3.1. Characteristics of the patients and CMR parameters
The current study included 378 patients (76.5% men, mean age: 38.65 ± 14.20 years). At baseline, 40.2% of the patients were classified as having NYHA class III or higher disease. The mean LVEF was 24.61% ± 10.25%, with 68 patients having LVEF >35%, 175 with LVEF 20%–35%, and 135 with LVEF <20%. Patients with LVEF <20% had a significantly lower body surface area and resting systolic blood pressure, and a higher heart rate and log N-terminal pro–B-type natriuretic peptide (NT-proBNP) levels than those with LVEF >35% (all P < 0.005; Table 1). The intra- and inter-observer CVs for myocardial strain measurements were 5.54%–9.32% for global radial strain (GRS), 8.48%–9.72% for global circumferential strain (GCS), and 8.43%–8.95% for global longitudinal strain (GLS), indicating good reproducibility. Initial strain measurements were used for the final analysis. The median GRS, GCS, and GLS values were 12.04%, −11.40%, and −8.87%, respectively. Patients with an LVEF <20% had a significantly lower GRS and more impaired (i.e., less negative) GCS and GLS values than those with LVEF >35% and those with LVEF 20%–35% (all P < 0.001; Table 1 and Fig 3). During follow-up, the patients who experienced endpoint events had a shorter median follow-up time (58.47 months, IQR: 40.99–84.27 months) than those without events (60.23 months, IQR: 40.48–91.73 months).
3.2. Association between CMR, clinical variables and the primary endpoints
During a median follow-up of 59.78 (IQR: 40.70–89.86) months, 35 (9.26%) patients reached the primary endpoints (29 SCD/aborted SCD, 6 VA events). According to the univariate Cox regression analysis, the significant predictors of the primary endpoints included age, body surface area, heart rate, history of left bundle branch block, log-transformed NT-proBNP levels, NYHA functional class III/IV, and creatine kinase levels (all P < 0.05; Table 2). In the overall cohort, GRS (hazard ratio [HR] = 0.81, 95% confidence interval [CI]: 0.74–0.90, P < 0.001), GCS (HR = 1.29, 95% CI: 1.15–1.45, P < 0.001), and GLS (HR = 1.49, 95% CI: 1.23–1.80, P < 0.001) were strongly associated with the primary endpoints. These associations remained significant in the LVEF-based subgroup analyses (including LVEF <35% and <20%; Table 3). The receiver operating characteristic curve analysis revealed that the optimal cutoff values for predicting the primary endpoints were as follows: 11.37% for GRS, −9.93% for GCS, and −9.61% for GLS, with the corresponding area under the curve, sensitivity, and specificity values detailed in Table 4. Based on the multivariate Cox regression analysis, GLS (HR = 1.29, 95% CI: 1.04–1.59, P = 0.019), LVEF (HR = 0.93, 95% CI: 0.89–0.98, P = 0.004), and age (HR = 1.03, 95% CI: 1.01–1.06, P = 0.035) were independent predictors of the primary endpoints in the overall cohort. These associations remained significant in patients with LVEF <35%. However, only GLS (HR = 1.37, 95% CI: 1.01–1.85, P = 0.041) retained its prognostic value in the LVEF <20% subgroup (Table 3).
In additional hierarchical Cox analyses, GLS remained independently associated with the primary endpoint and significantly improved model fit when added to models including Age+NYHA plus LAD/LVmassi/LVEDVi, as well as models including log NT-proBNP plus LAD/LVmassi/LVEDVi (all likelihood-ratio test P < 0.001; S1 and S2 Table in S1 File).
3.3. Association between CMR, clinical variables and the secondary endpoint
During follow-up, 72 patients reached the composite secondary endpoint (n = 29 all-cause deaths; n = 33, heart failure-related hospitalizations; n = 2, heart transplants; and n = 8, appropriate ICD therapies). The univariate Cox regression analysis showed that the significant predictors of the secondary endpoint included age, male sex, left bundle branch block, NYHA functional class III/IV, high log-transformed NT-proBNP levels, and the presence of mitral insufficiency. In addition, myocardial strain parameters including GRS (HR = 0.89, 95% CI: 0.85–0.94, P < 0.001), GCS (HR = 1.16, 95% CI: 1.09–1.24, P < 0.001), and GLS (HR = 1.25, 95% CI: 1.13–1.39, P < 0.001) were significantly associated with the composite outcome. In the multivariate analysis, after adjusting for age, LVEF, and NYHA functional class III/IV (vs. I/II), only GLS remained an independent predictor of the secondary endpoint. In particular, each unit increase in GLS was associated with a 1.14-fold higher risk (HR = 1.14, 95% CI: 1.01–1.29, P = 0.037; Table 5).
A similar incremental value of GLS was observed for the secondary endpoint across all hierarchical models (all likelihood-ratio test P ≤ 0.008; S3 and S4 Table in S1 File).
3.4. Novel prediction models combining strain and LVEF strata
Based on the strong association between myocardial strain and adverse outcomes, we evaluated different LVEF stratification schemes for discriminating the risk of SCD, aborted SCD, or VA in this cohort, and assessed predictive models combining strain with LVEF strata.
According to a previous research, an LVEF of 35% is the recognized threshold in major clinical guidelines for considering primary prevention ICD therapy. Conversely, an LVEF of 20% indicates extremely severe ventricular systolic dysfunction, and it is consistently associated with a significantly elevated risk of adverse clinical events [20,21]. Our study revealed that the incidence of the primary endpoint was low in patients with an LVEF of >35% (n = 1, 1.5%; annual rate: 0.3%). However, it was substantially high in the LVEF <20% subgroup (n = 27, 20.0%; annual rate: 5.9%), with an intermediate event rate observed in the LVEF 20%–35% group (n = 7, 4.0%; annual rate: 1.5%). Based on these findings, three LVEF strata were defined as follows: > 35% (n = 68), 20%–35% (n = 175), and <20% (n = 135). A significant stepwise increase in the incidence of SCD, aborted SCD, or VA was observed across the three LVEF categories (P < 0.001; Fig 4a). To improve risk discrimination, a predictive model combining the optimal cutoff value of GLS with LVEF stratification was developed.
The bar graph of annual primary events rate among low-risk, intermediate-risk, and high-risk groups (b).
Based on this approach, the patients were stratified into three risk groups: low-risk (LVEF >35% or LVEF 20%–35% with GLS <−9.61%; annual event rate: 0.2%), intermediate-risk (LVEF 20%–35% with GLS ≥ −9.61% or LVEF <20% with GLS <−9.61%; annual event rate: 1.3%), and high-risk (LVEF <20% with GLS ≥ −9.61%; annual event rate: 4.6%) (Fig 4b). The Kaplan–Meier analysis showed a significantly reduced event-free survival rate across these groups (Fig 5a–c). Compared with the low-risk group, the patients in the intermediate- and high-risk groups had progressively increased risks of the primary endpoints, with HRs of 5.45 (95% CI: 1.13–26.26; P = 0.035) and 20.33 (95% CI: 4.82–85.72; P < 0.001), respectively. In addition, the high-risk group had a significantly higher adjusted risk of SCD or aborted SCD than the intermediate-risk group (HR = 4.11, 95% CI: 1.69–9.99, P = 0.002).
Using the cut off values obtained from ROC curve analysis, Kaplan-Meier curves were constructed for each LVEF subgroup (a). Kaplan-Meier curve analysis of survival free from primary endpoints, incorporating both stratification by LVEF groups and assessment of strain measurements (b). Kaplan-Meier curve analysis of survival free from primary endpoints among low-risk, intermediate-risk, and high-risk groups (c).
To evaluate performance, the following three schemes were compared: (1) a GLS cutoff of −9.61% (model 1), (2) LVEF strata (>35%, 20%–35%, < 20%; model 2), and (3) a combined risk-group classification using both markers (model 3), with the addition of age and NYHA to create model 4. Model 3 was more effective in discriminating the primary endpoint than models 1 or 2 (C-index = 0.756 vs 0.681 and 0.714; P < 0.001). Adding age and NYHA classification further improved discrimination (model 4: apparent C-index = 0.801, 95% CI: 0.729–0.873) and outperformed model 3 (0.801 vs 0.756; P = 0.010). Model 4 (0.785, 95% CI: 0.719–0.858) had the highest optimism-corrected C-indices, followed by model 3 (0.754, 95% CI: 0.689–0.822), model 2 (0.711, 95% CI: 0.640–0.791), and model 1 (0.681, 95% CI: 0.636–0.734). Paired bootstrap comparisons (B = 1,000) confirmed that model 3 outperformed models 1 and 2 after correction (Holm-adjusted P = 0.048). However, the advantage of model 4 over model 3 did not reach statistical significance, even though the corrected C-index was numerically higher. S5 and S6 Table in S1 File show further details.
4. Discussion
In this multicenter cohort of patients with DCM who did not exhibit LGE on cardiac MRI, GLS had a substantial prognostic value beyond conventional structural and clinical markers. It remained an independent predictor of SCD-related events after controlling for LVEF, age, and NYHA classification, thereby emphasizing its sensitivity in detecting early myocardial dysfunction that may not manifest as volumetric decline or overt fibrosis. When incorporated into LVEF-based models, GLS significantly improved discriminative accuracy, and these enhancements remained consistent after bootstrap internal validation. Notably, among patients with severely impaired systolic function (LVEF <20%), GLS was the only independent risk marker. This finding underscores its unique value in identifying high-risk individuals in a group where traditional metrics provide limited stratification.
Previous literature has established the prognostic relevance of mid-wall fibrosis on LGE, especially for arrhythmic events and SCD in nonischemic DCM [4,22–24].However, some patients do not present with visible LGE despite having significant arrhythmic risk [3,5], thereby creating an important clinical blind spot. Previous studies have established the prognostic value of CMR feature tracking, including GLS. However, these analyses typically included mixed cohorts of LGE-positive and LGE-negative patients. Therefore, it is challenging to draw conclusions about the LGE-negative subgroup [25,26]. Our study directly addresses this gap by evaluating a relatively large, exclusively LGE-negative population, thereby offering a clearer understanding of residual risk when fibrosis cannot be detected on standard imaging. Consistent with earlier observations indicating that longitudinal dysfunction can precede circumferential impairment, we found that GLS—but not GCS—was associated with adverse outcomes, which is in accordance with previous data showing that GCS is less prognostically significant in LGE-negative DCM [6,27–29].
These findings can be explained by the distinct vulnerability of subendocardial longitudinal fibers, which are disproportionately susceptible to early interstitial fibrosis, microvascular dysfunction, inflammation, and cytoskeletal alterations—which are pathophysiologic processes commonly observed in patients with DCM even in the absence of macroscopic scar [30–32]. Such microstructural abnormalities may significantly impair longitudinal deformation, thereby contributing to electrical instability and arrhythmogenesis. This mechanism offers a compelling explanation for why GLS continues to predict malignant arrhythmic events even if traditional structural measurement parameters, such as LVEF, fail to completely identify the underlying risk. The strong association between GLS and adverse outcomes in patients with LVEF <20% further underscores its role in detecting disease severity and arrhythmic vulnerability that are not captured by global systolic function alone [33,34].
By integrating GLS cutoff values with established LVEF categories, this study developed a practical multiparametric risk stratification system that clearly distinguished low-, intermediate-, and high-risk groups using Kaplan–Meier survival curves. This approach may be valuable for LGE-negative individuals who often fall into a management “gray zone” regarding eligibility for ICD implantation or the need for intensified rhythm monitoring. Our findings support the notions that arrhythmic risk in nonischemic DCM cannot be fully identified by LVEF alone and that incorporating additional functional biomarkers may facilitate more individualized therapeutic decision-making, which is consistent with newer conceptual frameworks in DCM management [3,35,36]. Our study did not directly evaluate treatment modification based on GLS. Nevertheless, the observed stratification patterns indicated that GLS may help refine follow-up strategies, optimize timing for electrophysiological assessment, or contribute to shared decision-making regarding device therapy, particularly in intermediate-risk patients.
Considering that strain parameters predominantly capture functional impairment, combining GLS with tissue-level markers, such as T1 mapping and extracellular volume, may offer further incremental value. T1 mapping has a strong prognostic performance even among patients without replacement fibrosis [37–39]. However, heterogeneity in acquisition protocols, scanner platforms, and cutoff values currently limits its widespread adoption. As emphasized in recent methodological analyses, harmonized multicenter studies and validation of standardized thresholds will be essential to integrating T1-based diffuse fibrosis assessment into clinical risk models. Such integration may eventually lead to the development of a more comprehensive imaging-based risk classification system that simultaneously captures structural, functional, and tissue-level abnormalities [40].
The current study has several limitations. First, although consecutive patients from multiple centers were included, the retrospective design may introduce selection and information bias. The number of primary endpoint events was relatively modest, which constrained the complexity of multivariable models; therefore, we prespecified parsimonious models and applied bootstrap internal validation to reduce the risk of overfitting. Second, outcomes were analyzed using time-to-first event, and competing-risk analyses were not performed. Third, CMR-FT strain analysis was conducted using a single vendor-specific platform, and reproducibility assessments relied on CV rather than intraclass correlation, which might have restricted generalizability across imaging systems.
Fourth, baseline CMR was performed as part of the initial diagnostic work-up during the index hospitalization; therefore, the timing of CMR relative to initiation and subsequent optimization of guideline-directed medical therapy was not predefined or standardized across patients. In addition, although baseline medication use was recorded, treatment initiation, dose titration, adherence, and therapy modifications during follow-up (as well as variations in follow-up intensity) were not systematically captured and could have influenced clinical outcomes. Fifth, advanced CMR tissue characterization parameters (e.g., native T1 and extracellular volume mapping), which may further refine risk stratification in LGE-negative DCM, were not available. In addition, due to the retrospective nature of the study and heterogeneity in acquisition protocols, right ventricular volume/function and LV sphericity metrics were not consistently available; thus, their independent prognostic value and incremental contribution could not be evaluated. Finally, high-sensitivity cardiac troponin was not routinely measured in the earlier period of our cohort; therefore, creatine kinase (CK) was used as a surrogate marker. In our inpatient cohort, elevated CK may reflect acute myocardial injury and/or clinical decompensation at the index hospitalization, which may partly explain its prognostic association.
In conclusion, GLS has a robust incremental prognostic value beyond LVEF in LGE-negative DCM. Moreover, it enhances risk stratification when combined with age, NYHA classification, and LVEF. These findings underscore the clinical value of myocardial deformation analysis in a subgroup of patients where conventional imaging markers may be insufficient, thereby providing a pathway toward a more precise and individualized arrhythmic risk assessment. Nevertheless, prospective multicenter studies incorporating advanced tissue characterization and evaluating GLS-guided management strategies should be conducted to further define the role of GLS in routine clinical practice.
Supporting information
S1 File. Supplementary Tables (including Tables S1–S6).
https://doi.org/10.1371/journal.pone.0345077.s001
(DOCX)
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