Abstract
Distinct patterns of circulating microRNAs (miRNAs) were found to be involved in misguided thrombus resolution. Thus, we aimed to investigate dysregulated miRNA signatures during the acute phase of pulmonary embolism (PE) and test their diagnostic and predictive value for future diagnosis of chronic thromboembolic pulmonary hypertension (CTEPH). Microarray screening and subsequent validation in a large patient cohort (n = 177) identified three dysregulated miRNAs as potential biomarkers: circulating miR-29a and miR-720 were significantly upregulated and miR-let7a was significantly downregulated in plasma of patients with PE. In a second validation study equal expression patterns for miR-29a and miR-let7a regarding an acute event of recurrent venous thromboembolism (VTE) or deaths were found. MiR-let7a concentrations significantly correlated with echocardiographic and laboratory parameters indicating right ventricular (RV) dysfunction. Additionally, circulating miR-let7a levels were associated with diagnosis of CTEPH during follow-up. Regarding CTEPH diagnosis, ROC analysis illustrated an AUC of 0.767 (95% CI 0.54–0.99) for miR-let7a. Using logistic regression analysis, a calculated patient-cohort optimized miR-let7a cut-off value derived from ROC analysis of ≥ 11.92 was associated with a 12.8-fold increased risk for CTEPH. Therefore, miR-let7a might serve as a novel biomarker to identify patients with haemodynamic impairment and as a novel predictor for patients at risk for CTEPH.
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Introduction
Pulmonary embolism (PE) is the third most common cardiovascular disease with an annual incidence of 39–115 per 100,000 person-years and is associated with serious short- and long-term complications including recurrence, chronic thromboembolic pulmonary hypertension (CTEPH) and death1,2. CTEPH is a rare disease, but is associated with high mortality rates and poor prognosis if left untreated3,4. In recent years, microRNAs (miRNAs) emerged as novel biomarkers and distinct patterns were found to exhibit diagnostic and prognostic value for different disease settings, including various cardiovascular diseases5,6. Studies have proven the existence of dysbalanced miRNA concentrations with disease-specific changes in different cell types and can thus reflect many different pathological conditions. Moreover, miRNAs are stable in the circulation (including blood, urine, saliva breast milk) and thus are promising diagnostic and prognostic markers7,8.
Little is known about the miRNA profiles in patients with acute PE and CTEPH. Therefore, we evaluated whether there are common miRNA expression patterns among patients suffering from acute PE as compared to healthy control patients and assessed the diagnostic and prognostic value of specific miRNAs on different pre-defined short-term and long-term outcomes.
Results
Screening for circulating miRNAs in plasma of PE patients and baseline characteristics
Between October 2005 and September 2012, we included 177 patients (52.9% women; median age 70 [IQR, 52–76] years) with acute PE. The baseline characteristics of the study patients are shown in Table 1. We randomly selected 20 PE patients and 20 sex- and age-matched healthy controls and screened for significantly dysregulated circulating miRNAs in plasma of acute PE vs. healthy controls using microarray-PCR-based global expression profiling (Fig. 1a,b).
Out of 754 miRNAs on the TaqMan miRNA Array 223 miRNAs were detectable in PE patients and 221 in controls with sufficient detection levels (ct < 30). After filtering steps according to stringent selection criteria (fold-change more than 2; significance level p ≤ 0.05) 53 miRNAs were significantly deregulated and were considered for further validation. We chose the top 10 dysregulated miRNAs (Supplemental Table 1) and from these 3 miRNAs showed sufficient amplification plots in plasma: miR-29a, miR-720 and miR-let7a (Fig. 1c). Of those, circulating miR-29a and miR-720 were significantly upregulated and miR-let7a was significantly downregulated (Fig. 2). Thereby, the nomenclature of miR-720 is still under debate and it seems that miR-720 is not a classical miRNA, but likely a fragment of a t-RNA.
Presence of miR-29a, miR-720 and miR-let7a in patients with acute PE
Next, we profiled these three promising miRNAs in 177 patients with confirmed acute PE and 177 sex- and age-matched healthy controls (Fig. 1d). MiR-29a levels could be detected in 158 PE patients with abundancy over a certain threshold (ct < 30) and ranged from 0.1 to 378.1 (median, 0.3 [IQR, 0.1–1.3]). MiR-720 levels were detectable in 174 PE patients and ranged from 0.1 to 6.9 (median, 0.1 [IQR, 0.1–0.2]) and miR -let7a levels in 153 PE patients ranging from − 6.1 to 19.8 (median, 10.3 [IQR, 8.8–12.3]). We confirmed that circulating miR-29a levels were significantly increased and miR-let7a levels were significantly decreased in PE patients compared to matched healthy control patients (Fig. 3a,b and supplemental Fig. 1a,b), suggesting that circulating miR-29a and miR-let7a might serve as novel biomarkers for acute PE. Circulating miR-720 levels were downregulated in PE patients (Fig. 3c) (miR-29a in 109 matched healthy controls: median, 0.11 [IQR 0.05–0.25], difference − 0.26 ± 0.69, p = 0.001; miR-720 in 167 matched healthy controls: median, 0.05 [IQR 0.02–0.23], difference 0.47 ± 1.52, p < 0.001; miR-let7a in 126 matched healthy controls: median, 0.30 [IQR, 0.00–0.25], difference 0.18 ± 0.56, p = 0.002). For miR-29a and miR-720 only one parameter in each case was found to be associated with higher levels (hyperlipoproteinaemia for miR-29a: OR 2.8 [1.2–6.5]; p = 0.013 and the history of previous PE for miR-720: OR 2.6 [1.0–6.8]; p = 0.050). Interestingly, predictors for high levels of miR-let7a were only parameters regarding right ventricular (RV) compromise such as RV/LV ratio ≥ 1 on transthoracic echocardiography (TTE) (OR 3.9 [1.4–10.8]; p = 0.009) or CT (OR 2.3 [1.0–4.9]; p = 0.042) as well as elevated troponin (hsTnT) ≥ 14 pg/ml (OR 3.6 [1.8–7.1]; p < 0.001) indicating a potential pathomechanistic role for miR-let7a in PE.
Association between miR-29a and miR-let7a levels and adverse outcome in independent validation cohort
Next, we validated our findings in an independent patient cohort. In this cohort, 117 study participants experienced a recurrent event or died (first event recurrent VTE, n = 53; death n = 64). The median time to event was 2.6 years (interquartile range [IQR]: 0.7–3.2), and the maximum follow-up time was 7.9 years. Expression levels of miRNA-29a(-3p) were positively related to incidence of the combined endpoint (Table 2), with a 29% risk increase per standard deviation increase of expression (age and sex-adjusted HR: 1.29 [95% CI 1.06–1.55], p = 0.009). Conversely, levels of miR-let7a were inversely related to the same endpoint (age and sex-adjusted HR per standard deviation increase: 0.72 [95% CI 0.60–0.86], p = 0.0003).
Correlation of miR-let7a levels and haemodynamic impairment in the acute phase and with diagnosis of CTEPH during follow-up
No correlation with echocardiographic and laboratory parameters indicating haemodynamic RV impairment were observed for circulating miR-29a and miR-720, but for miR-let7a (estimated systolic PA pressure on TTE, r = 0.336, p = 0.012; NT-proBNP, r = 0.216, p = 0.008), highlighting this specific miRNA to be of clinical interest. For investigation of the prognostic value of miRNAs regarding short-term outcomes, ROC analyses illustrated an AUC of 0.43 (95% CI 0.24–0.63) for miR-29a, an AUC of 0.44 (95% CI 0.24–0.64) for miR-720 and an ROC of 0.42 (95% CI 0.28–0.67) for miR-let7a with regard to an adverse outcome. Using logistic regression analyses, no miRNA or other parameter such as clinical findings (mild hypotension [OR 5.4 [0.5–57.1]; p = 0.158] or syncope [OR 1.7 [0.3–8.6]; p = 0.508]), laboratory (NT-proBNP ≥ 600 pg/ml [OR 1.2 [0.4–4.2]; p = 0.731]) or imaging parameter (RV dysfunction on CT [OR 4.0 [0.5–32.9]; p = 0.198]) was associated with short-term prognosis (adverse outcome) in normotensive patients with acute PE.
However, regarding the diagnosis of CTEPH (n = 6; 3.9%) during follow-up, ROC analysis illustrated a relevant AUC for miR-let7a (0.767 [95% CI 0.54–0.99]; p = 0.027]) (Fig. 4). The calculated optimal cut-off value for miR-let7a on admission of ≥ 11.92 was associated with a sensitivity of 78%, a specificity of 31%, a PPV of 7% and a NPV of 96%. By using univariate logistic regression analysis, the calculated patient-cohort optimized miR-let7a cut-off value derived from ROC analysis was associated with a 12.8-fold increased risk (1.5–112.9, p = 0.002) for a diagnosis of CTEPH during follow-up. Those results were not affected by performing a multivariable logisitic regression analysis with adjusting age and sex (OR 14.5 [1.6–131.9]; p = 0.017). Of note, miR-29a and miR-720 levels and calculated patient-cohort optimized cut-off values were not associated with an increased risk for a diagnosis of CTEPH during follow-up. The baseline characteristics of the PE patients with miR-let7a measurement are demonstrated in Table 3.
Discussion
Acute pulmonary embolism remains a substantial and leading contributor to total mortality, even if in the last years the management and treatment of this preventable thrombotic disorder was evolving2,9,10. Patients with acute PE are characterized by a heterogeneous short-term and long-term prognosis; thus, estimation of the individual risk of death related to acute PE or from its associated complications is of paramount interest for initiating individual risk-adapted diagnostic and therapeutic strategies.
In the present study, we investigated the potential role of miRNA signatures in patients with PE and CTEPH. In summary, our findings suggest that miR-let7a plasma levels were strongly associated with an increased risk of CTEPH diagnosis during follow-up.
To date only a handful of studies investigated miRNA signatures in patients with PE. Nonetheless, these studies have shown that miRNAs may be used as diagnostic tools in the context of acute PE. Xiao et al. identified miR-134 as a potential biomarker for acute PE11. Another study by Zhou and colleagues observed increased circulating miR-28-3p levels in PE patients12. In a further study, Liu et al. found miR-221 as a novel diagnostic marker for PE and observed that plasma levels could be correlated with BNP, troponin I and D-dimer13. In 2015, Starikova et al. evaluated the miRNA expression profile in the plasma of 20 patients with a first unprovoked VTE and 20 age- and sex-matched healthy controls. This study revealed that five miRNAs were upregulated, and four miRNAs were downregulated in VTE patients versus controls14. In addition, other studies strengthened the clinical significance of specific miRNAs to serve as diagnostic markers for PE as it was shown that miRNAs may distinguish PE from other differential diagnosis such as myocardial infarction or non ST-segment elevation myocardial infarction15,16. The number of studies exploring the use of miRNAs as biomarkers in PE patients substantially increased during the past few years. However, most of the reports were case–control studies appearing to be limited by the small number of PE patients included and most did not use heparinase pre-treatment making interpretation of those studies difficult. To our knowledge, our current study is the first report identifying dysregulated circulating miRNAs in a larger patient cohort (n = 177) and using an optimized heparinase-pretreatment. In our study, we analyzed miRNA patterns in plasma samples derived from patients with acute PE via array-PCR-based profiling identifying novel blood-based biomarkers for the diagnosis of PE. We found significantly increased levels of miR-29a and significantly decreased plasma levels of miR-let7a and miR-720 in patients with PE suggesting that these miRNAs might serve as novel diagnostic tools. Neither miR-29a nor miR-720 correlated with the acute phase in patients with acute PE. Only miR-let7a predicted haemodynamic compromise in patients with acute PE and has not yet described in this context. In our validation cohort, we demonstrated the same expression pattern for miR-29a and miR-let7a regarding the outcome of death or recurrent event of acute VTE.
However, the expression of several haemostatic factors has been reported to be regulated by miRNAs including key procoagulant factors and inhibitors of the coagulation pathway17. Defective angiogenesis, incomplete thrombus revascularisation and fibrosis are considered critical pathomechanisms of CTEPH after PE18. The miR-29 family is known as key regulators of fibrosis in the heart and other organs. The members of the miR-29 family target at least 16 genes related to ECM (extracellular matrix), such as collagens, fibrillins, and elastin, and are known as key regulator of fibrosis by regulation of the profibrotic activities of fibroblasts and SMCs (smooth muscle cells). Previously, it was shown that transforming growth factor-beta (TGF-β)-mediated downregulation of miR-29 enhances profibrotic activities of mesenchymal-derived cells19. Angiogenesis and an intact angiogenic response after acute thrombosis or thromboembolism, are key mediators of normal thrombus resolution20,21. Direct upregulation of endothelial miR-29a by TGF-ß/Smad 4 signaling is a mediator of angiogenesis via increasing tube formation and human endothelial cell (EC) migration. In fresh thrombi TGF-ß-mRNA is increased compared to CTEPH specimens, suggesting TGF-ß mediated upregulated miR-29a expression in ECs to be involved in the early physiologic angiogenic response necessary for thrombus resolution. Previous reports have also found that miR-let‐7a plays a role in regulating angiogenesis22. A recent study demonstrated that miR-let‐7a regulated angiogenesis by concomitantly downregulating the TGF-ß-receptor type III (TGFBR3). Overexpression of miR-let‐7a or a knockdown of TGFBR3 in cell culture inhibited the tube formation and reduced migration rate23. In the present study, 3.4% patients with acute PE were diagnosed with CTEPH at follow-up. miR-29a and miR-720 levels were not considerable elevated in those patients and thus calculated patient-cohort optimized cut-off values were not associated with an increased risk for a diagnosis of CTEPH during follow-up. In contrast, we found that miR-let7a levels were significantly upregulated in patients at the time of PE diagnosis who diagnosed with CTEPH during follow-up compared to PE patients who did not develop CTEPH. Moreover, miR-let7a plasma concentrations above the calculated optimal cut-off value were associated with a 12.8-fold increased risk for the diagnosis of CTEPH at follow-up. In context with previous studies, which demonstrated that miR-let7a overexpression may contribute to defective angiogenesis and persistent vascular occlusion, our study results add relevant associations for miR-let7a for patients with acute PE with an increased risk for CTEPH. The present study has limitations that need consideration: first, although we were able to demonstrate an increased risk for subsequent diagnosis of CTEPH patients with pulmonary embolism and high miR-let7a plasma levels, further research is needed to determine whether miR-let7a may help in clinical decision making and prognostic assessment of individual patients. Second, CTEPH is a rare disease, therefore the number of CTEPH cases is limited and thus also the statistically power.
In summary, we found in our derivation and validation cohort significantly increased levels of miR-29a and significantly decreased plasma levels of miR-let7a in patients with an acute event of PE or recurrent VTE suggesting that these miRNAs might serve as novel diagnostic tools. Circulating miR-let7a levels were associated with haemodynamic compromise in patients with acute PE and additionally miR-let7a levels on admission were associated with high risk for the diagnosis of CTEPH during follow-up. Thus, miR-let7a might serve as a novel biomarker to identify patients with haemodynamic impairment and as a novel prediction marker for patients, who had a higher risk to develop CTEPH or for pre-existing CTEPH. Further studies are indispensable to evaluate if these miRNAs are specifically regulated in the acute phase of PE or also in the progression of the chronic disease.
Methods
Patients with acute pulmonary embolism
Consecutive patients aged ≥ 18 years with confirmed acute PE were prospectively included in a single center prospective cohort study (Pulmonary Embolism Registry of Göttingen, PERGO, supplemental Figs. 2 , 3)) at the University Medical Center Goettingen, Germany. The study protocol has been described in detail elsewhere24. The study protocol was conducted in accordance with the amended Declaration of Helsinki and was approved by the local independent Ethic Committee of the Medical University Goettingen, Germany (AZ 14/6/10). All patients gave informed written consent for participation in the study.
Patients were excluded from the present study if PE was asymptomatic and/or an accidental finding obtained during the diagnostic workup for another suspected disease; or if consent for participation in the study was denied or withdrawn.
Thirty-day clinical follow-up data were obtained from all patients included in the study and an adverse 30-day outcome was defined as PE-related death, need for mechanical ventilation, cardiopulmonary resuscitation or the administration of catecholamines. Long-term follow-up data were collected 6 months after the initial PE event during a routine clinical follow-up (outpatient) visit as part of standard clinical care at the Clinic for Cardiology and Pulmonology, University Medical Center Goettingen, Germany or by contacting the treating general practitioner. Diagnosis of CTEPH was confirmed according to current guideline recommendations25. All study outcomes were independently adjudicated by two researchers.
Control group
The control group consisted of sex- and age-matched patients (based on SPSS case–control matching) apparently healthy volunteers without a history of chronic disease.
Plasma sampling and RNA isolation
Venous blood samples for subsequent biomarker measurements were collected from patients with acute PE. Blood samples were processed using standard operating procedures, immediately stored at − 80 °C and analysed in batches after a single thaw. Routine laboratory parameters were measured as part of the clinical routine at the Department of Clinical Chemistry of the University Medical Centre Goettingen, Germany. For RNA isolation the miRNeasy Serum/Plasma Kit (Qiagen) was used according to the manufacturer´s instructions. For subsequent normalization synthetic Caenorhabditis elegans miR-39 (5 μl of 1 fmol/μl) was added as spike-in control during RNA isolation to the Qiazol/chloroform/plasma mixture26.
Heparinase pre-treatment
To remove heparin in RNA samples after RNA isolation, samples were treated with heparinase according to previous studies27. Briefly, 3.5 µl of RNA was mixed with 0.19 µl RNase inhibitor (20 U/µl), 1 µl 10 × RT buffer (Applied Biosystem), 0.9 µl MgCl2 (25 mM, Qiagen) and 0.3 µl heparinase (1U/µl) and filled up to 10 µl with RNase-free H2O. The reaction mixture was incubated for 1 h at 25 °C.
TaqMan ArrayCard miRNA screening
A panel of 754 miRNAs was analysed in plasma of 20 out of 177 randomly selected patients with acute PE and 20 sex- and age-matched healthy volunteers via human TaqMan array MicroRNA A + B Cards Set (Applied Biosystems) following the manufacturer’s recommendation. Prior to polymerase chain reactions (PCR), two steps consisting of reverse transcription (RT) and pre-amplification were conducted. The Megaplex PreAmp Primers, consisting of two pools of gene-specific forward and reverse primers (Pool A and Pool B) were used to enable the unbiased pre-amplification of the miRNA cDNA target by PCR.
Validation of findings using quantitative real-time PCR
After heparinase treatment, TaqMan MicroRNA Reverse Transcription Kit (Applied Biosystems) was used for cDNA synthesis following the manufacturer´s instructions. Primers hsa-miR-720, hsa-miR-29a, hsa-let7a and cel-miR-39 were used in this study. Quantification of specific miRNA levels was performed via quantitative RT-PCR using TaqMan MicroRNA Assays (Applied Biosystems). The qPCR was performed in a 384-well PCR plate using the ViiA™ 7 Real-Time PCR System (Thermo Fisher Scientific). The qRT-PCR reaction mix was run at 95 °C for 15 min, followed by 45 cycles of denaturation at 95 °C for 15 s and combined annealing/elongation at 60 °C for 1 min. Relative quantification was performed using the Delta-delta CT method28.
External validation in an independent cohort
MicroRNAs of interest were evaluated in relation to the combined endpoint of recurrent event or death in an independent external cohort, the Genotyping and Molecular Phenotyping in Venous ThromboEmbolism (GMP-VTE) project29. GMP-VTE is an investigator-initiated, prospective, multi-centre cohort study of VTE patients enrolled in the acute phase, with collection of biomaterial and long-term follow-up (up to 8 years). Quantitative determination of circulating miRNAs was performed in a subsample of 181 individuals. Small RNA isolation and library preparation was performed by GenXPro GmbH (Frankfurt am Main, Germany) in 200 µl of once-thawed ethylenediaminetetraacetic acid (EDTA)-treated plasma using the NucleoSpin RNA Mini kit (Machery & Nagel, Düren, Germany), and Small RNA Next Generation Sequencing (NGS)-libraries were prepared using the TrueQuant smallRNA-Seq kit (GenXPro GmbH) according to the manual of the respective manufacturers. Sequencing was performed on an Illumina NextSeq500 instrument with 75 cycles for sequencing. Low quality reads were trimmed and adapters were removed by the ‘cutadapt’ algorithm. PCR duplicates were removed based on the TrueQuant molecular identifiers, i.e. poly-N nucleotides incorporated in the template molecules prior to amplification such that each has a unique sequence (GenXPro GmbH). Reads were mapped and annotated using the OmiRas pipeline. Read data were normalized to counts per million (CPM) format. Data were subsequently transformed to normality by inverse normal transformation30.
Statistics
The Fisher´s exact test or χ2 test was used to compare categorical variables, which were expressed as absolute numbers or percentage. Continuous variables were found not to follow a normal distribution when tested with the modified Kolmogorov–Smirnov test (Lilliefors test); therefore, these variables are expressed as medians with the corresponding interquartile range (IQR) and were compared using the unpaired Mann–Whitney-U test. Receiver operating characteristics (ROC) curve analysis was performed to determine the area under the curve (AUC)31. Youden-index quantification was used to identify the optimal cut-off values for miRNA-based prediction of the study outcomes. Comparison of the prognostic performance of biomarker levels was performed by calculation of sensitivity, specificity, positive predictive value (PPV) and negative predictive value (NPV), and positive and negative likelihood ratios (LR). The prognostic relevance of biomarker cut-off values as well as single predictors with regard to study outcomes was tested using univariable logistic regression analysis and presented as Odds ratios (OR) with the corresponding 95% confidence intervals (CI). A two-sided significance level of α < 0.05 was defined appropriate to indicate statistical significance. All statistical analyses were performed using the SPSS software (version 21.0, SPSS Inc., Chicago, Illinois, USA).
For analyzing the regulation of miRNAs between the different patient groups an unpaired student´s t-test was used. Analysis and illustrative presentations of expression data was conducted by Graphpad prism.
Data availability
The datasets generated during and/or analysed during the current study are available in the GEO repository with the accession number GSE247365 and the link https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE247365.
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Acknowledgements
GMP-VTE: We are indebted to all study participants, without whom this study would not have been possible. We extend our thanks to all members of the study teams involved.
Funding
Open Access funding enabled and organized by Projekt DEAL. The GMP-VTE project was funded by the German Federal Ministry of Education and Research (BMBF 01EO1003 and 01EO1503), internal funds of Clinical Epidemiology and Systems Medicine (Center for Thrombosis and Hemostasis, Mainz, Germany), and a grant from Bayer AG. The analyses were supported by the DFG (KFO311 and CRC1470 to TT).
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Contributions
F.K. contributed to the experimental design of the study, performance of experiments, analysis and interpretation of data and writing of the manuscript. L.H. contributed to analysis and interpretation of data and writing of the manuscript. C.B. contributed to the experimental design of the study, performance of experiments and analysis. S.K.G. contributed to the experimental design and analysis. K.X. contributed to array data analysis. S.T. contributed to experimental performance. V.T.C., S.R., G.H., P.W., S.K., R.W., contributed to study design analysis. M.L. and T.T. contributed to the concept and design of the study, critical revising of the draft and supervision. All authors gave final approval of the manuscript.
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F. K. reports no disclosures. L. H. reports lecture/ consultant fees from MSD and Actelion, outside the submitted work. C. B. reports no disclosures. S.K.G. has filed and granted patents in the field of non-coding RNAs, outside the submitted work. K. X. reports no disclosures. S. T. reports no disclosures. V.T. C. reports no disclosures. S. R. reports no disclosures. G. H. reports having received consultancy and lecture honoraria from AstraZeneca, Bayer, Impulse Dynamics, Novartis, Pfizer, Servier, Vifor Pharma, all outside the submitted work. P. W. reports grants from Bayer AG, Bayer Healthcare, Bayer Vital, Daiichi-Sankyo, Novartis, Boehringer Ingelheim, Sanofi-Aventis and consulting fees from DiaSorin, AstraZeneca, all outside the submitted work. S. K. reports grants and personal fees from Bayer AG; grants from Boehringer Ingelheim, grants and personal fees from Actelion, grants and personal fees from Daiichi-Sankyo, grants and personal fees from Biocompatibles Group UK, personal fees from Pfizer-Bristol-Myers Squibb, grants and personal fees from MSD, all outside the submitted work. R. W. reports grants from Medtronic, DFG, EU, Bundesministerium für Bildung und Forschung, Deutsches Zentrum fürHerz-/Kreislaufforschung and personal fees from Boehringer Ingelheim, Pfizer, Bayer, CVRx, Medtronic, BMS, Vifor, Novartis, all outside the submitted work. M. L. reports having received consultancy and lecture honoraria from Actelion, Bayer, BRAHMS—Thermo Fisher scientific, Daiichi-Sankyo, MSD, and Pfizer—Bristol-Myers Squibb and research funding from BRAHMS—Thermo Fisher scientific. T. T. filed and licensed patents about noncoding RNAs. TT is founder and shareholder of Cardior Pharmaceuticals GmbH.
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Kenneweg, F., Hobohm, L., Bang, C. et al. Circulating miR-let7a levels predict future diagnosis of chronic thromboembolic pulmonary hypertension. Sci Rep 14, 4514 (2024). https://doi.org/10.1038/s41598-024-55223-1
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DOI: https://doi.org/10.1038/s41598-024-55223-1
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