[1] T.G. Weiser, A.B. Haynes, G. Molina, S.R. Lipsitz, M.M. Esquivel, T. Uribe-Leitz, R. Fu, T. Azad, T.E. Chao, W.R. Berry, A.A. Gawande, Estimate of the global volume of surgery in 2012: an assessment supporting improved health outcomes, LANCET, 385 Suppl 2 (2015) S11.
[2] J.R. Prowle, E.P. Kam, T. Ahmad, N.C. Smith, K. Protopapa, Preoperative renal dysfunction and mortality after non-cardiac surgery.
[3] D.A. Watters, M.J. Hollands, R.L. Gruen, K. Maoate, H. Perndt, R.J. McDougall, W.W. Morriss, V. Tangi, K.M. Casey, K.A. McQueen, Perioperative mortality rate (POMR): a global indicator of access to safe surgery and anaesthesia, WORLD J SURG, 39 (2015) 856-864.
[4] J.B. Cywinski, E.J. Mascha, A. Kurz, D.I. Sessler, Estimated glomerular filtration rate better predicts 30-day mortality after non-cardiac surgery than serum creatinine: a retrospective analysis of 92,888 patients, Canadian Journal of Anesthesia/Journal canadien d'anesthésie, 62 (2015) 745-752.
[5] D.G. Warnock, Estimated Glomerular Filtration Rate: Fit for What Purpose? NEPHRON, 134 (2016) 43-49.
[6] C. Thongprayoon, W. Cheungpasitporn, M.A. Mao, N. Srivali, W. Kittanamongkolchai, A.M. Harrison, K.L. Greason, K.B. Kashani, Persistent acute kidney injury following transcatheter aortic valve replacement, J CARDIAC SURG, 32 (2017) 550-555.
[7] M. Yamamoto, K. Hayashida, G. Mouillet, T. Hovasse, B. Chevalier, A. Oguri, Y. Watanabe, J. Dubois-Randé, M. Morice, T. Lefèvre, E. Teiger, Prognostic Value of Chronic Kidney Disease After Transcatheter Aortic Valve Implantation, J AM COLL CARDIOL, 62 (2013) 869-877.
[8] M.S. Jang, J.S. Nam, J.Y. Jo, C.H. Kang, S.A. Ryu, E.H. Lee, I.C. Choi, The relationship of preoperative estimated glomerular filtration rate and outcomes after cardiovascular surgery in patients with normal serum creatinine: a retrospective cohort study, BMC ANESTHESIOL, 19 (2019) 88.
[9] A. Dardashti, S. Nozohoor, L. Algotsson, P. Ederoth, H. Bjursten, The predictive value of s-cystatin C for mortality after coronary artery bypass surgery, The Journal of Thoracic and Cardiovascular Surgery, 152 (2016) 139-146.
[10] D. Bissacco, V. Catanese, A. Fossati, S. Salvati, G. Zanella, M. Carmo, P. Settembrini, Role of preoperative serum creatinine and estimated glomerular filtration rate values in asymptomatic patients undergoing carotid endarterectomy, J Cardiovasc Surg (Torino), 59 (2018) 412-418.
[11] J.F. Mooney, B.L. Croal, S. Cassidy, V.W. Lee, C.K. Chow, B.H. Cuthbertson, G.S. Hillis, Relative value of cystatin C and creatinine-based estimates of glomerular filtration rate in predicting long-term mortality after cardiac surgery: a cohort study, BMJ OPEN, 9 (2019) e029379.
[12] W. Wang, Y. Wang, R. Xu, J. Chai, W. Zhou, H. Chen, K. Wang, X. Kong, Outcomes Following Coronary Artery Bypass Graft Surgery in Patients with Mild Preoperative Renal Insufficiency, Braz J Cardiovasc Surg, 33 (2018) 155-161.
[13] M.H. Bernardi, D. Schmidlin, A. Schiferer, R. Ristl, T. Neugebauer, M. Hiesmayr, W. Druml, A. Lassnigg, Impact of preoperative serum creatinine on short- and long-term mortality after cardiac surgery: a cohort study, BRIT J ANAESTH, 114 (2015) 53-62.
[14] K. Kim, J. Bang, S. Kim, S. Kim, J.U. Kim, J. Song, Association of preoperative hypoalbuminemia with postoperative acute kidney injury in patients undergoing brain tumor surgery: a retrospective study, J NEUROSURG, 128 (2018) 1115-1122.
[15] C.T. Martin, A.J. Pugely, Y. Gao, S.A. Mendoza-Lattes, S.L. Weinstein, The Impact of Renal Impairment on Short-term Morbidity Risk Following Lumbar Spine Surgeries, SPINE, 40 (2015) 909-916.
[16] High and low estimated glomerular filtration rates are associated with adverse outcomes in patients undergoing surgery for gastrointestinal malignancies.
[17] Derivation and Prospective Validation of a Simple Index for Prediction of Cardiac Risk of.
[18] L.G. Glance, S.J. Lustik, E.L. Hannan, T.M. Osler, D.B. Mukamel, F. Qian, A.W. Dick, The Surgical Mortality Probability Model, ANN SURG, 255 (2012) 696-702.
[19] S.D. Kristensen, J. Knuuti, A. Saraste, S. Anker, H.E. Bøtker, S. De Hert, I. Ford, J.R.G. Juanatey, B. Gorenek, G.R. Heyndrickx, A. Hoeft, K. Huber, B. Iung, K.P. Kjeldsen, D. Longrois, T.F. Luescher, L. Pierard, S. Pocock, S. Price, M. Roffi, P.A. Sirnes, M.S. Uva, V. Voudris, C. Funck-Brentano, 2014 ESC/ESA Guidelines on non-cardiac surgery, EUR J ANAESTH, 31 (2014) 517-573.
[20] D.X.H. Chan, Y.E. Sim, Y.H. Chan, R. Poopalalingam, H.R. Abdullah, Development of the Combined Assessment of Risk Encountered in Surgery (CARES) surgical risk calculator for prediction of postsurgical mortality and need for intensive care unit admission risk: a single-center retrospective study, BMJ OPEN, 8 (2018) e019427.
[21] A.S. Levey, K. Eckardt, Y. Tsukamoto, A. Levin, J. Coresh, J. Rossert, D.D.E. Zeeuw, T.H. Hostetter, N. Lameire, G. Eknoyan, Definition and classification of chronic kidney disease: A position statement from Kidney Disease: Improving Global Outcomes (KDIGO), KIDNEY INT, 67 (2005) 2089-2100.
[22] Y.E. Sim, H.E. Wee, A.L. Ang, N. Ranjakunalan, B.C. Ong, H.R. Abdullah, Prevalence of preoperative anemia, abnormal mean corpuscular volume and red cell distribution width among surgical patients in Singapore, and their influence on one year mortality, PLOS ONE, 12 (2017) e0182543.
[23] WHO_TRS_405.
[24] E.J.A. Fitchett, A.C. Seale, S. Vergnano, M. Sharland, P.T. Heath, S.K. Saha, R. Agarwal, A.I. Ayede, Z.A. Bhutta, R. Black, K. Bojang, H. Campbell, S. Cousens, G.L. Darmstadt, S.A. Madhi, A.S. Meulen, N. Modi, J. Patterson, S. Qazi, S.J. Schrag, B.J. Stoll, S.N. Wall, R.D. Wammanda, J.E. Lawn, Strengthening the Reporting of Observational Studies in Epidemiology for Newborn Infection (STROBE-NI): an extension of the STROBE statement for neonatal infection research, The Lancet Infectious Diseases, 16 (2016) e202-e213.
[25] ratio is an independent risk factor for diabetes mellitus: results from a.
[26] T.A. Sargut, P. Pergantis, C. Knosalla, J. Knierim, M. Hummel, V. Falk, F. Schoenrath, Adjusting preoperative risk models of post heart transplant survival to a European cohort in the age of a new cardiac allocation score in Europe, The Heart Surgery Forum, 21 (2018) E527-E533.
[27] S. Padhy, Prediction of Major Adverse Cardiovascular and Cerebrovascular Events (MACCE) after Thoracic Surgery- The Role of Estimated GFR, JOURNAL OF CLINICAL AND DIAGNOSTIC RESEARCH, (2017).
[28] Association of estimated glomerular filtration rate and albuminuria with all-cause and cardiovascular mortality in general population cohorts: a collaborative meta-analysis, The Lancet, 375 (2010) 2073-2081.
[29] M. Tonelli, S.W. Klarenbach, A.M. Lloyd, M.T. James, A.K. Bello, B.J. Manns, B.R. Hemmelgarn, Higher estimated glomerular filtration rates may be associated with increased risk of adverse outcomes, especially with concomitant proteinuria, KIDNEY INT, 80 (2011) 1306-1314.
[30] K. Matsushita, B.K. Mahmoodi, M. Woodward, J.R. Emberson, T.H. Jafar, S.H. Jee, K.R. Polkinghorne, A. Shankar, D.H. Smith, M. Tonelli, D.G. Warnock, C. Wen, J. Coresh, R.T. Gansevoort, B.R. Hemmelgarn, A.S. Levey, F.T. Chronic Kidney Disease Prognosis Consortium, Comparison of Risk Prediction Using the CKD-EPI Equation and the MDRD Study Equation for Estimated Glomerular Filtration Rate, JAMA, 307 (2012).
[31] A.S. Levey, C. Becker, L.A. Inker, Glomerular Filtration Rate and Albuminuria for Detection and Staging of Acute and Chronic Kidney Disease in Adults, JAMA, 313 (2015) 837.