Skip to main content

REVIEW article

Front. Cardiovasc. Med., 17 January 2023
Sec. Heart Failure and Transplantation
This article is part of the Research Topic The Endless Quest for Optimal Pacing Support in Failing Hearts View all 10 articles

Risk scores in cardiac resynchronization therapy–A review of the literature

  • 1Heart and Vascular Center, Semmelweis University, Budapest, Hungary
  • 2Heart and Vascular Centre, Mater Private Hospital, Dublin, Ireland
  • 3Royal College of Surgeons in Ireland, Dublin, Ireland

Cardiac resynchronization therapy (CRT) for selected heart failure (HF) patients improves symptoms and reduces morbidity and mortality; however, the prognosis of HF is still poor. There is an emerging need for tools that might help in optimal patient selection and provide prognostic information for patients and their families. Several risk scores have been created in recent years; although, no literature review is available that would list the possible scores for the clinicians. We identified forty-eight risk scores in CRT and provided the calculation methods and formulas in a ready-to-use format. The reviewed score systems can predict the prognosis of CRT patients; some of them have even provided an online calculation tool. Significant heterogeneity is present between the various risk scores in terms of the variables incorporated and some variables are not yet used in daily clinical practice. The lack of cross-validation of the risk scores limits their routine use and objective selection. As the number of prognostic markers of CRT is overwhelming, further studies might be required to analyze and cross-validate the data.

Introduction

According to the most recent guidelines, cardiac resynchronization therapy (CRT) is recommended for symptomatic heart failure patients in sinus rhythm with a QRS duration ≥150 ms and left bundle branch block (LBBB) QRS morphology and with left ventricular ejection fraction (LVEF) ≤35% despite optimal medical therapy to improve symptoms and reduce morbidity and mortality (1, 2). However, mortality is still high; and approximately one-third of the patients do not respond to CRT as adequately as expected, in whom no quality of live improvement or reverse remodeling of the left ventricle is seen (3).

Consequently, there is a great need for tools that might help in optimal patient selection and provide prognostic information for the patients and their families. Ever since the first implementation of CRT, several clinical factors and biomarkers have been tested in prediction models to identify those patients who might benefit the most from the therapy (4, 5). Prediction models are useful to reveal which parameters are statistically significant in the outcome prediction by giving the hazard and odds ratios, but they are not interpretable at the level of the individual patient in the clinical practice. Therefore, risk scores have been developed that constitute predominantly categorized variables with attributed points. The sum of the points reveals the exact risk of the individual; so that, patients can be easily and quickly grouped into risk categories with meaningful information.

Several risk scores have been created in CRT in recent years; however, no literature review is available that would list the possible scores for the clinicians.

Therefore, we aimed to systematically review the risk scores in CRT and provide the calculation methods and formulas in a ready-to-use format.

Materials and methods

The literature search was performed in November 2021 and then updated in September 2022 by using the search engine PubMed.gov1 with the input of the following equation: (((cardiac resynchronization) OR (cardiac resynchronization therapy)) OR (biventricular pacing))) AND (((prediction model)) OR (predictive model) OR (risk model) OR (score))). The flowchart of the review process is presented by Figure 1.

FIGURE 1
www.frontiersin.org

Figure 1. Flowchart of the review process.

Since we applied no language or publication date restrictions, the result was 1,314 possible papers. Two investigators (AB and PP) independently pre-screened the abstracts of these manuscripts by considering further inclusion criteria: original research article, and ready-to-use format. This resulted in a sum of 100 records that were further assessed by full-text review. A total of 52 papers were excluded based on the following reasons: external validation of previously described score systems (n = 18), prediction models without score systems (n = 18), machine learning algorithms without online interfaces (n = 8), miscellaneous endpoints (n = 5), and lack of CRT (n = 3). Consequently, forty-eight CRT risk scores were incorporated into the present review.

Results

To date, we identified 48 ready-to-use risk scores in heart failure patients with CRT Table 1. Summarizes the details of the models with the interpretation of the results and presents the formulas or the calculation methods of the scores Figure 2. Overviews the risk scores and helps in the selection of the appropriate risk score by considering the available data about the patient.

TABLE 1
www.frontiersin.org

Table 1. Risk scores in cardiac resynchronization therapy.

FIGURE 2
www.frontiersin.org

Figure 2. Heat map of the predictors used in the risk scores of cardiac resynchronization therapy.

The primary endpoint of the models was all-cause death or a composite of death in the majority of the cases (n = 33, 69%), otherwise, it was echocardiographic or clinical response to CRT (n = 15, 32%). The most commonly used variables in the models were ischemic etiology (n = 21, 44%), renal function (n = 21, 44%), age (n = 20, 42%), New York Heart Association classification (n = 18, 38%), LVEF (n = 15, 33%), QRS morphology (n = 15, 31%), QRS width (n = 14, 30%), atrial fibrillation (n = 13, 27%), gender (n = 13, 27%), and left ventricular dimensions (n = 12, 25%).

Discussion

The very first risk score in CRT was developed by Heist et al. (6). It investigated the immediate hemodynamic response (improved contractility as assessed by the dP/dt of the mitral regurgitation jet) to CRT by using echocardiographic and electrophysiologic parameters (6). Following that, the Charlson comorbidity index (CCI) from Charlson et al. (7), was tested in 463 heart failure patients with CRT; a CCI score ≥5, meaning several comorbidities and worse overall state, reflected a more than 3 times mortality risk (8). In parallel, the MADIT-CRT score was created by Goldenberg et al. (9) by using the data of the 1,761 patients enrolled in the Multicenter Automatic Defibrillator Implantation Trial With Cardiac Resynchronization Therapy (MADIT-CRT). The MADIT-CRT identified the most relevant routine clinical risk factors that affect mortality in CRT: gender, etiology of heart failure, the presence of left bundle-branch block and wide QRS, prior heart failure hospitalizations, and left ventricular and atrial dimensions. The MADIT-CRT score has been served as a gold standard and used as a reference in many validation studies (1012).

The Seattle Heart Failure Model (SHFM) is a well-known risk estimation tool to predict the 1-, 2-, and 5-year mortality in chronic heart failure patients with conservative therapy (13). Perrotta et al. (14) applied the SHFM to patients who received a CRT, or a CRT-D and the model showed a good discrimination capacity in the mortality prediction. In the same year, the SHFM was validated in CRT populations by others as well (15, 16). Park et al. (17) were the first who developed a risk score, the EchoCG score, by using echocardiographic strain analysis to predict the reverse remodeling after CRT implantation. Strain analysis was included in many models later (11, 1820). Similarly, to strain analysis, electrophysiologic modalities were also used in risk score development, such as sophisticated ECG analysis (2123), vectorcardiography (24), or heart rate histogram analysis (25).

However, simplicity and availability are the keys to risk score development. The EAARN (26), the VALID-CRT (27), the HF-CRT (28), the CRT-SCORE (29), the AL-FINE (30), the ScREEN (31), the CRT-D Futility score (32), the MAGGIC (33), and many others can be calculated with routine laboratory and clinical parameters. Incorporating these principal concepts, machine learning algorithms can provide personalized risk predictions and online calculators are also available (3436).

Conclusion

This is the first systematic review of risk scores in cardiac resynchronization therapy. The scores show a great diversity in terms of used predictors and endpoints. As we demonstrated, the number of the different scoring systems has drastically increased in the past few years and a very marked heterogeneity can be observed among them. Unfortunately, this makes their translation and transition into everyday clinical practice difficult. Furthermore, the majority of studies were conducted prior to the current era of quadruple HFrEF therapy. These limitations must be considered before the routine application of the score systems.

Rickard et al. have shown in a prior review that classic markers (native LBBB, non-ischemic etiology, wide QRS, female gender and sinus rhythm) predict outcomes after CRT-D (4). However, there is growing evidence available on novel risk factors for CRT response, incorporated into the numerous risk score systems. The predictors can be categorized into the following different groups: co-morbidities, clinical state, echocardiographic, electrocardiographic, routine blood markers, and novel biomarkers as shown in the present review; the overlap of the markers in the various models is minimal. Some biomarkers are not yet incorporated into the daily routine clinical practice and their widespread use is therefore limited. Moreover, the lack of cross-validation across the risk scores limits the ability to objectively determine which of them should be incorporated into daily practice.

Although all the listed risk scores have the potential to predict outcomes after CRT, more data is required to enable us to select which will be appropriate to use in the daily clinical practice to predict the prognosis of severe heart failure patients, who undergo CRT. As the number of possible predictors and combinations is overwhelming, machine learning based algorithms or the help of artificial intelligence might be required to develop a uniform CRT risk score system.

It must be emphasized that, currently, the decision of CRT implantation is based on the ejection fraction, the width of the QRS, and the presence of LBBB; none of the guidelines do endorse any risk score to be applied in the process. Therefore, risk scores are useful to give information regarding the prognosis after implantation but should not influence the implantation itself.

Author contributions

AB and GS contributed to the conception and design of the study and wrote the first draft of the manuscript. GS and BM provided the institutional background to the study. AB and PP collected data and performed the statistical analysis. All authors contributed to manuscript revision, read, and approved the submitted version.

Conflict of interest

GS reports personal fees from Abbott, Bayer, Boston Scientific, and Johnson and Johnson Medical outside the submitted work.

The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.

Publisher’s note

All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.

Footnotes

  1. ^ https://www.ncbi.nlm.nih.gov/

References

1. Ponikowski P, Voors A, Anker S, Bueno H, Cleland J, Coats A, et al. 2016 ESC Guidelines for the diagnosis and treatment of acute and chronic heart failure: the task force for the diagnosis and treatment of acute and chronic heart failure of the European society of cardiology (ESC)developed with the special contribution of the heart failure association (HFA) of the ESC. Eur Heart J. (2016) 37:2129–200.

Google Scholar

2. McDonagh T, Metra M, Adamo M, Gardner R, Baumbach A, Böhm M, et al. 2021 ESC Guidelines for the diagnosis and treatment of acute and chronic heart failure. Eur Heart J. (2021) 42:3599–726.

Google Scholar

3. Fornwalt B, Sprague W, BeDell P, Suever J, Gerritse B, Merlino J, et al. Agreement is poor among current criteria used to define response to cardiac resynchronization therapy. Circulation. (2010) 121:1985–91.

Google Scholar

4. Rickard J, Michtalik H, Sharma R, Berger Z, Iyoha E, Green A, et al. Predictors of response to cardiac resynchronization therapy: a systematic review. Int J Cardiol. (2016) 225:345–52.

Google Scholar

5. Heggermont W, Auricchio A, Vanderheyden M. Biomarkers to predict the response to cardiac resynchronization therapy. Europace. (2019) 21:1609–20.

Google Scholar

6. Heist E, Taub C, Fan D, Arzola-Castaner D, Alabiad C, Reddy V, et al. Usefulness of a novel “response score” to predict hemodynamic and clinical outcome from cardiac resynchronization therapy. Am J Cardiol. (2006) 97:1732–6.

Google Scholar

7. Charlson M, Pompei P, Ales K, MacKenzie CR. A new method of classifying prognostic comorbidity in longitudinal studies: development and validation. J Chronic Dis. (1987) 40:373–83.

Google Scholar

8. Theuns D, Schaer B, Soliman O, Altmann D, Sticherling C, Geleijnse M, et al. The prognosis of implantable defibrillator patients treated with cardiac resynchronization therapy: comorbidity burden as predictor of mortality. Europace. (2011) 13:62–9.

Google Scholar

9. Goldenberg I, Moss A, Hall W, Foster E, Goldberger J, Santucci P, et al. Predictors of response to cardiac resynchronization therapy in the multicenter automatic defibrillator implantation trial with cardiac resynchronization therapy (MADIT-CRT). Circulation. (2011) 124:1527–36.

Google Scholar

10. Spinale F, Meyer T, Stolen C, Van Eyk J, Gold M, Mittal S, et al. Development of a biomarker panel to predict cardiac resynchronization therapy response: results from the SMART-AV trial. Heart Rhythm. (2019) 16:743–53.

Google Scholar

11. Seo Y, Ishizu T, Machino-Ohtsuka T, Yamamoto M, Machino T, Kuroki K, et al. Incremental value of speckle tracking echocardiography to predict cardiac resynchronization therapy (CRT) responders. J Am Heart Assoc. (2016) 5:e003882.

Google Scholar

12. Younis A, Goldberger J, Kutyifa V, Zareba W, Polonsky B, Klein H, et al. Predicted benefit of an implantable cardioverter-defibrillator: the MADIT-ICD benefit score. Eur Heart J. (2021) 42:1676–84.

Google Scholar

13. Levy W, Mozaffarian D, Linker D, Sutradhar S, Anker S, Cropp A, et al. The Seattle heart failure model: prediction of survival in heart failure. Circulation. (2006) 113:1424–33.

Google Scholar

14. Perrotta L, Ricciardi G, Pieragnoli P, Chiostri M, Pontecorboli G, De Santo T, et al. Application of the Seattle heart failure model in patients on cardiac resynchronization therapy. Pacing Clin Electrophysiol. (2012) 35:88–94.

Google Scholar

15. Clemens M, Szegedi Z, Kardos L, Nagy-Baló E, Sándorfi G, Edes I, et al. The Seattle heart failure model predicts survival in patients with cardiac resynchronization therapy: a validation study. J Card Fail. (2012) 18:682–7.

Google Scholar

16. Smith T, Levy W, Schaer B, Balk A, Sticherling C, Jordaens L, et al. Performance of the Seattle heart failure model in implantable defibrillator patients treated with cardiac resynchronization therapy. Am J Cardiol. (2012) 110:398–402.

Google Scholar

17. Park J, Negishi K, Grimm R, Popovic Z, Stanton T, Wilkoff B, et al. Echocardiographic predictors of reverse remodeling after cardiac resynchronization therapy and subsequent events. Circ Cardiovasc Imaging. (2013) 6:864–72.

Google Scholar

18. Kydd A, Khan F, Ring L, Pugh P, Virdee M, Dutka D. Development of a multiparametric score to predict left ventricular remodelling and prognosis after cardiac resynchronization therapy. Eur J Heart Fail. (2014) 16:1206–13.

Google Scholar

19. Kang Y, Cheng L, Cui J, Li L, Qin S, Su Y, et al. A new score system for predicting response to cardiac resynchronization therapy. Cardiol J. (2015) 22:179–87.

Google Scholar

20. Orszulak M, Filipecki A, Wróbel W, Berger-Kucza A, Orszulak W, Urbańczyk-Swić D, et al. Regional strain pattern index-a novel technique to predict CRT response. Int J Environ Res Public Health. (2021) 18:926.

Google Scholar

21. Bani R, Checchi L, Cartei S, Pieragnoli P, Ricciardi G, Paoletti Perini A, et al. Simplified selvester score: a practical electrocardiographic instrument to predict response to CRT. J Electrocardiol. (2015) 48:62–8.

Google Scholar

22. Végh E, Kandala J, Januszkiewicz L, Ren J, Miller A, Orencole M, et al. A new simplified electrocardiographic score predicts clinical outcome in patients treated with CRT. Europace. (2018) 20:492–500.

Google Scholar

23. Liu X, Hu Y, Hua W, Yang S, Gu M, Niu H, et al. A predictive model for super-response to cardiac resynchronization therapy: the QQ-LAE score. Cardiol Res Pract. (2020) 2020:3856294.

Google Scholar

24. Maass A, Vernooy K, Wijers S, van ’T Sant J, Cramer M, Meine M, et al. Refining success of cardiac resynchronization therapy using a simple score predicting the amount of reverse ventricular remodelling: results from the markers and response to CRT (MARC) study. Europace. (2018) 20:e1–10.

Google Scholar

25. Wilkoff B, Richards M, Sharma A, Wold N, Jones P, Perschbacher D, et al. a device histogram-based simple predictor of mortality risk in ICD and CRT-D patients: the heart rate score. Pacing Clin Electrophysiol. (2017) 40:333–43.

Google Scholar

26. Khatib M, Tolosana J, Trucco E, Borràs R, Castel A, Berruezo A, et al. EAARN score, a predictive score for mortality in patients receiving cardiac resynchronization therapy based on pre-implantation risk factors. Eur J Heart Fail. (2014) 16:802–9.

Google Scholar

27. Gasparini M, Klersy C, Leclercq C, Lunati M, Landolina M, Auricchio A, et al. Validation of a simple risk stratification tool for patients implanted with cardiac resynchronization therapy: the VALID-CRT risk score. Eur J Heart Fail. (2015) 17:717–24.

Google Scholar

28. Nauffal V, Tanawuttiwat T, Zhang Y, Rickard J, Marine J, Butcher B, et al. Predictors of mortality, LVAD implant, or heart transplant in primary prevention cardiac resynchronization therapy recipients: the HF-CRT score. Heart Rhythm. (2015) 12:2387–94.

Google Scholar

29. Höke U, Mertens B, Khidir M, Schalij M, Bax J, Delgado V, et al. Usefulness of the CRT-SCORE for shared decision making in cardiac resynchronization therapy in patients with a left ventricular ejection fraction of =35. Am J Cardiol. (2017) 120:2008–16.

Google Scholar

30. Kisiel R, Fijorek K, Sondej T, Pavlinec C, Kukla P, Czarnecka D, et al. Risk stratification in patients with cardiac resynchronisation therapy: the AL-FINE CRT risk score. Kardiol Pol. (2018) 76:1441–9.

Google Scholar

31. Providencia R, Marijon E, Barra S, Reitan C, Breitenstein A, Defaye P, et al. Usefulness of a clinical risk score to predict the response to cardiac resynchronization therapy. Int J Cardiol. (2018) 260:82–7.

Google Scholar

32. Maille B, Bodin A, Bisson A, Herbert J, Pierre B, Clementy N, et al. Predicting outcome after cardiac resynchronisation therapy defibrillator implantation: the cardiac resynchronisation therapy defibrillator futility score. Heart. (2022) 108:1186–93.

Google Scholar

33. Manlucu J, Sharma V, Koehler J, Warman E, Wells G, Gula L, et al. Incremental value of implantable cardiac device diagnostic variables over clinical parameters to predict mortality in patients with mild to moderate heart failure. J Am Heart Assoc. (2019) 8:e010998.

Google Scholar

34. Feeny A, Rickard J, Patel D, Toro S, Trulock K, Park C, et al. Machine learning prediction of response to cardiac resynchronization therapy: improvement versus current guidelines. Circ Arrhythm Electrophysiol. (2019) 12:e007316.

Google Scholar

35. Tokodi M, Schwertner W, Kovács A, Tösér Z, Staub L, Sárkány A, et al. Machine learning-based mortality prediction of patients undergoing cardiac resynchronization therapy: the SEMMELWEIS-CRT score. Eur Heart J. (2020) 41:1747–56.

Google Scholar

36. Liang Y, Ding R, Wang J, Gong X, Yu Z, Pan L, et al. Prediction of response after cardiac resynchronization therapy with machine learning. Int J Cardiol. (2021) 344:120–6.

Google Scholar

37. Vidal B, Delgado V, Mont L, Poyatos S, Silva E, Angeles Castel M, et al. Decreased likelihood of response to cardiac resynchronization in patients with severe heart failure. Eur J Heart Fail. (2010) 12:283–7.

Google Scholar

38. Shen X, Nair C, Aronow W, Holmberg M, Reddy M, Anand K, et al. A new baseline scoring system may help to predict response to cardiac resynchronization therapy. Arch Med Sci. (2011) 7:627–33.

Google Scholar

39. Brunet-Bernard A, Maréchaux S, Fauchier L, Guiot A, Fournet M, Reynaud A, et al. Combined score using clinical, electrocardiographic, and echocardiographic parameters to predict left ventricular remodeling in patients having had cardiac resynchronization therapy six months earlier. Am J Cardiol. (2014) 113:2045–51.

Google Scholar

40. Rickard J, Cheng A, Spragg D, Cantillon D, Baranowski B, Varma N, et al. A clinical prediction rule to identify patients at heightened risk for early demise following cardiac resynchronization therapy. J Cardiovasc Electrophysiol. (2014) 25:278–82.

Google Scholar

41. Paoletti Perini A, Bartolini S, Pieragnoli P, Ricciardi G, Perrotta L, Valleggi A, et al. CHADS2 and CHA2DS2-VASc scores to predict morbidity and mortality in heart failure patients candidates to cardiac resynchronization therapy. Europace. (2014) 16:71–80.

Google Scholar

42. Barra S, Looi K, Gajendragadkar P, Khan F, Virdee M, Agarwal S. Applicability of a risk score for prediction of the long-term benefit of the implantable cardioverter defibrillator in patients receiving cardiac resynchronization therapy. Europace. (2016) 18:1187–93.

Google Scholar

43. Nauffal V, Zhang Y, Tanawuttiwat T, Blasco-Colmenares E, Rickard J, Marine J, et al. Clinical decision tool for CRT-P vs. CRT-D implantation: findings from PROSE-ICD. PLoS One. (2017) 12:e0175205. doi: 10.1371/journal.pone.0175205

PubMed Abstract | CrossRef Full Text | Google Scholar

44. Nevzorov R, Goldenberg I, Konstantino Y, Golovchiner G, Strasberg B, Souleiman M, et al. Developing a risk score to predict mortality in the first year after implantable cardioverter defibrillator implantation: data from the Israeli ICD Registry. J Cardiovasc Electrophysiol. (2018) 29:1540–7.

Google Scholar

45. Biton Y, Costa J, Zareba W, Baman J, Goldenberg I, McNitt S, et al. Predictors of long-term mortality with cardiac resynchronization therapy in mild heart failure patients with left bundle branch block. Clin Cardiol. (2018) 41:1358–66.

Google Scholar

46. Bakos Z, Chatterjee N, Reitan C, Singh J, Borgquist R. Prediction of clinical outcome in patients treated with cardiac resynchronization therapy - the role of NT-ProBNP and a combined response score. BMC Cardiovasc Disord. (2018) 18:70. doi: 10.1186/s12872-018-0802-8

PubMed Abstract | CrossRef Full Text | Google Scholar

47. Theuns D, Van Boven N, Schaer B, Hesselink T, Rivero-Ayerza M, Umans V, et al. Predicting early mortality among implantable defibrillator patients treated with cardiac resynchronization therapy. J Card Fail. (2019) 25:812–8.

Google Scholar

48. Weber D, Koller M, Theuns D, Yap S, Kühne M, Sticherling C, et al. Predicting defibrillator benefit in patients with cardiac resynchronization therapy: a competing risk study. Heart Rhythm. (2019) 16:1057–64.

Google Scholar

49. Cai M, Hua W, Zhang N, Yang S, Hu Y, Gu M, et al. A prognostic nomogram for event-free survival in patients with atrial fibrillation before cardiac resynchronization therapy. BMC Cardiovasc Disord. (2020) 20:221. doi: 10.1186/s12872-020-01502-4

PubMed Abstract | CrossRef Full Text | Google Scholar

50. Patel D, Trulock K, Moennich L, Kiehl E, Kumar A, Toro S, et al. Predictors of long-term outcomes greater than 10 years after cardiac resynchronization therapy implantation. J Cardiovasc Electrophysiol. (2020) 31:1182–6.

Google Scholar

51. Yang S, Liu Z, Hu Y, Jing R, Gu M, Niu H, et al. A novel risk model for mortality and hospitalization following cardiac resynchronization therapy in patients with non-ischemic cardiomyopathy: the alpha-score. BMC Cardiovasc Disord. (2020) 20:205. doi: 10.1186/s12872-020-01460-x

PubMed Abstract | CrossRef Full Text | Google Scholar

52. Milner A, Braunstein ED, Umadat G, Ahsan H, Lin J, Palma E. Utility of the modified frailty index to predict cardiac resynchronization therapy outcomes and response. Am J Cardiol. (2020) 125:1077–82.

Google Scholar

53. Theuns D, Schaer B, Caliskan K, Hoeks S, Sticherling C, Yap S, et al. Application of the heart failure meta-score to predict prognosis in patients with cardiac resynchronization defibrillators. Int J Cardiol. (2021) 330:73–9.

Google Scholar

54. Zoni-Berisso M, Martignani C, Ammendola E, Narducci M, Caruso D, Miracapillo G, et al. Mortality after cardioverter-defibrillator replacement: results of the DECODE survival score index. Heart Rhythm. (2021) 18:411–8.

Google Scholar

55. Yamada S, Kaneshiro T, Yoshihisa A, Nodera M, Amami K, Nehashi T, et al. Albumin-bilirubin score for prediction of outcomes in heart failure patients treated with cardiac resynchronization therapy. J Clin Med. (2021) 10:5378.

Google Scholar

56. Ikeya Y, Saito Y, Nakai T, Kogawa R, Otsuka N, Wakamatsu Y, et al. Prognostic importance of the controlling nutritional status (CONUT) score in patients undergoing cardiac resynchronisation therapy. Open Heart. (2021) 8:e001740.

Google Scholar

57. Saito Y, Nakai T, Ikeya Y, Kogawa R, Otsuka N, Wakamatsu Y, et al. Prognostic value of the MELD-XI score in patients undergoing cardiac resynchronization therapy. ESC Heart Fail. (2022) 9:1080–9.

Google Scholar

Keywords: CRT, cardiac resynchronization therapy, prediction model, risk scores, mortality, response

Citation: Boros AM, Perge P, Merkely B and Széplaki G (2023) Risk scores in cardiac resynchronization therapy–A review of the literature. Front. Cardiovasc. Med. 9:1048673. doi: 10.3389/fcvm.2022.1048673

Received: 19 September 2022; Accepted: 28 December 2022;
Published: 17 January 2023.

Edited by:

Maciej M. Sterlinski, National Institute of Cardiology, Poland

Reviewed by:

Ludmila Danilowicz-Szymanowicz, Medical University of Gdańsk, Poland
Rajiv Sankaranarayanan, Liverpool University Hospitals NHS Foundation Trust, United Kingdom

Copyright © 2023 Boros, Perge, Merkely and Széplaki. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.

*Correspondence: Gábor Széplaki, www.frontiersin.org c3plcGxha2kuZ2Fib3JAZ21haWwuY29t

Disclaimer: All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.