ISSN : 1301-5680
e-ISSN : 2149-8156
Turkish Journal of Thoracic and Cardiovascular Surgery     
The effect of time between angiography and coronary artery bypass grafting on postoperative acute kidney injury in patients with diabetes mellitus
Cem Doğan1, Tanıl Özer2, Rezan Aksoy2, Rezzan Deniz Acar1, Zübeyde Bayram1, Taylan Adademir2, Kaan Kırali2, Nihal Özdemir1
1Department of Cardiology, University of Health Sciences, Kartal Koşuyolu Yüksek İhtisas Training and Research Hospital, İstanbul, Turkey
2Department of Cardiovascular Surgery, University of Health Sciences, Kartal Koşuyolu Yüksek İhtisas Training and Research Hospital, İstanbul, Turkey
DOI : 10.5606/tgkdc.dergisi.2019.16216

Abstract

Background: This study aims to investigate the effect of time interval between coronary angiography and coronary artery bypass grafting surgery on postoperative acute kidney injury in patients with diabetes mellitus.

Methods: Between December 2013 and November 2016, a total of 421 diabetic patients (274 males, 147 females; mean age 60±9.2 years; range, 31 to 84 years) who underwent coronary artery bypass grafting were included in the study. Data including demographic characteristics of the patients, comorbidities, medical, and surgical histories, previous coronary angiographies, and operative and laboratory results were retrospectively analyzed. The patients were divided into two groups as those with acute kidney injury (n=108) and those without acute kidney injury (n=313). The Risk, Injury, Failure, Loss, End-Stage Kidney Disease (RIFLE) criteria were used to define acute kidney injury. The patients were further classified into three subgroups according to the time interval: 0-3 days, 4-7 days, and >7 days.

Results: There was no statistically significant difference in the median time between coronary angiography and coronary artery bypass grafting between the patients with and without acute kidney injury (11.5 and 12.0 days; respectively p=0.871). There was no significant difference in the risk factors for acute kidney injury among the subgroups. Multivariate analysis revealed that previous myocardial infarction (odds ratio [OR]: 5.192, 95% confidence interval [CI]: 2.176-12.38; p<0.001) and the increase in the creatinine levels in the first postoperative day (OR: 4.102 and 95% CI: 1.278- 13.17; p=0.018) were independent predictors of acute kidney injury.

Conclusion: Coronary artery bypass grafting can be performed without any delay after coronary angiography without an increase in the postoperative risk of acute kidney injury in patients with diabetes mellitus.

Diabetes mellitus (DM) is known to be one of the most important risk factors for coronary artery disease (CAD). Coronary angiography (CA), which utilizes contrast agents, is the gold standard method in the diagnosis and estimation of the prevalence of CAD. One of the treatment methods for patients with CAD is coronary artery bypass grafting (CABG) and about 20 to 50% of DM patients undergo CABG.[1-3]

Diabetes mellitus may also lead to acute kidney injury (AKI) either during the diagnosis of CAD with CA due to contrast-induced nephropathy (CIN) or during the treatment period for CAD with CABG. The frequency of AKI due to CIN is reported as 3% in the general population; however, it is claimed to be 20% in patients with severe cardiac pathologies and this figure may increase up to 50%.[4] Diabetes mellitus and diabetic nephropathy are two major risk factors for CIN.[5] The presence of DM has been estimated to double the risk of CIN, and multivariate analysis of a database has shown that having DM is an independent risk factor for CIN with an odds ratio (OR) of 1.9.[6,7]

Acute kidney injury, which may occur after CABG, is a serious problem with an incidence of 7.6 to 48.5% in previous studies.[8-10] It may lead to several complications including prolonged length of stay in hospital, an increased risk of hemodialysis and persistent kidney failure, and increased mortality rates.[11] Review of the risk factors reveals that DM plays an important role in the development of AKI.

It is well-established that CA and CABG have an additive effect on AKI in patients with DM and several studies have been conducted to identify the optimal time between CA and CABG to inhibit this additive effect; however, the results have been inconclusive.[12,13] In the present study, we aimed to investigate the effect of time between CA and CABG on postoperative AKI in patients with DM.

Methods

Medical data of a total of 421 diabetic patients (274 males, 147 females; mean age 60±9.2 years; range, 31 to 84 years) who underwent CABG between December 2013 and November 2016 were retrospectively analyzed from the database of the University of Health Sciences, Kartal Kosuyolu Training and Research Hospital. Data including demographic characteristics of the patients, comorbidities, medical and surgical histories, CA findings, and operative and laboratory results were recorded. The patients were divided into two groups depending on creatinine levels as those with AKI (n=108) and those without AKI (n=313) using the Risk, Injury, Failure, Loss, End-Stage Kidney Disease (RIFLE) criteria.

Inclusion criteria were as follows: age between 18 and 80 years, DM, creatinine level <1.5 mg/dL on admission, and stable angina pectoris and unstable acute coronary syndrome which could not be treated percutaneously. The patients with CIN due to CA in which preoperative creatinine levels returned to pre-CABG levels were also included in the study. Exclusion criteria were as follows: creatinine level ≥1.5 mg/dL before CA and before CABG, previous treatment for renal insufficiency, history of previous of cardiac surgery, history of nephrotoxic drugs other than renin angiotensin inhibitors, urgent or emergency CABG, ST-elevation myocardial infarction, cardiogenic shock, inotropic or mechanical circulatory device requirement before surgery, decompensated heart failure according to the New York Heart Association (NYHA) functional Class III-IV, multiple organ dysfunction, history of systemic disease affecting kidneys other than DM, and recent imaging study using a contrast agent. Patients with CIN due to CA in which preoperative creatinine levels were not regressed spontaneously or which regressed with renal replacement therapy, such as hemodialysis, were also excluded. Patients who required an additional intervention or treatment during CA or CABG, except for standard procedures, and those whose CA and other percutaneous interventions prior to CABG were performed in external centers were also excluded from the study.

A written informed consent was obtained from each patient. The study protocol was approved by the Kartal Koşuyolu Yüksek İhtisas Training and Research Hospital Ethics Committee. The study was conducted in accordance with the principles of the Declaration of Helsinki.

Definitions of DM, AKI and CIN
Diabetes mellitus was defined as a fasting plasma glucose of >126 mg/dL or 2-h plasma glucose of >200 mg/dL during an oral glucose tolerance test; or in a patient with classical symptoms of hyperglycemia or hyperglycemic crisis. A random plasma glucose of >200 mg/dL and previously established diagnosis or treatment of DM were also accepted.

Creatinine levels in all patients before CA, for two consecutive days after CA, and for five consecutive days before and after CABG were recorded from our database. Acute kidney injury was defined according to the RIFLE consensus.[14] The patients w ith AKI were further stratified into subgroups according to the increase in serum creatinine levels: those with a serum creatinine increase of 1.5 fold were classified as Stage R, those with a two-fold increase as Stage I, a three-fold increase as Stage F, those with complete loss of function for four weeks were classified as Stage L, and end-stage kidney disease for longer than three months as Stage E. Since there was no data on the pre- or postoperative hourly urine output for the entire duration of the study, the urine output definitions in the RIFLE criteria were not employed. Primary definition of AKI was the occurrence of RIFLE Class R or greater (a >50% increase in the creatinine levels from baseline) during the first five postoperative days.

In addition, CIN was defined according to the European Society of Urogenital Radiology as an increase in the serum creatinine concentration of 0.5 mg/dL or a 25% increase from the baseline within 48 h after contrast agent administration.

Coronary angiography was performed after the cessation of nephrotoxic medications and following hydration with 0.9% saline infusion. During CA, six images for the left coronary artery system and two images for the right coronary artery system were obtained, and similar amounts of contrast agents were used. The time of surgery was decided depending-on the clinical status of the patient and the availability of the operating room. Coronary artery bypass grafting was typically performed with preoperative preparation and physical examination by an anesthesiologist, while the surgical method and postoperative follow-up were conducted according to the current guidelines. The patients were further classified into three subgroups according to the time interval: 0-3 days, 4-7 days, and >7 days.

Statistical analysis
Statistical analyses were performed using the IBM SPSS version 21.0 software (IBM Corp., Armonk, NY, USA). Continuous variables with normal distribution were presented in mean ± standard deviation (SD), while non-homogeneous data were presented in median (interquartile range) and categorical variables were presented in percentage. Univariate comparisons between the groups of patients with or without AKI were performed using the chi-square test for categorical variables, while the Student"s t-test or the Mann-Whitney rank-sum test were used for continuous variables, as appropriate. For the comparisons of patients with AKI of Stage R to E, analysis of variance (ANOVA) or the Kruskal- Wallis test was used for numerical variables, while the chi-square was used for categorical variables. Multiple logistic regression analysis was performed including variables for which p<0.05 was found in the univariate analyses to predict the independent predictors of postoperative AKI development. The receiver operating characteristic (ROC) curves were plotted for the estimation of the optimal cut-off values for individual parameters to predict AKI and to establish the optimal cut-off points for use in clinical decision making. A p value of <0.05 was considered statistically significant.

Results

Of all patients, 15% were in Stage R, 5.5% in Stage I, and 1% were in Stage F. Contrast-induced nephropathy was found in 7.2% of all patients. However, a total of 91 patients (21.6%) were not included in the study, as either they did not have spontaneous resolution and required hemodialysis or their preoperative creatinine levels did not return to normal. Demographic and clinical characteristics of the patients with and without AKI after CABG are shown in Table 1.

Table 1: Demographic and clinical characteristics of patients with and without AKI after CABG

There were no significant differences in cardiopulmonary bypass (CPB) time and the amount of postoperative blood product used between the two groups. The median time interval between CA and CABG was not significantly different between the patients with and without AKI (11.5 [range, 7 to 16] days and 12 [range, 7 to 17] days, respectively; p=0.871). Logistic regression analysis showed no significant differences in the risk factors for AKI such as age, gender, hypertension, left ventricular ejection fraction, baseline urea and creatinine, albumin, and hemoglobin levels, CPB time, and the amount of postoperative blood products among the three subgroups as stratified according to the time interval between CA and CABG. The risk for AKI after CABG was not statistically significant high among the three groups (Table 2).

Table 2: Logistic regression analysis of risk for development of postoperative AKI as time interval between CA and CABG

According to the univariate analyses carried out to predict the risk factors for AKI, female gender, higher Body Mass Index, previous myocardial infarction, hypertension, elevated sedimentation rates, lower hemoglobin and red cell distribution width levels, higher postoperative creatinine and urea levels, lower albumin levels during the postoperative period, and increased creatinine kinase-myocardial band (MB) levels after the procedure were found to be associated with an increased risk (Table 2). However, our study findings did not indicate that the time interval between CA and CABG was a risk factor for the development of AKI.

Multiple logistic regression analysis was performed to predict the independent risk factors for AKI after CABG. Previous myocardial infarction (OR: 5.192, 95% CI: 2.176-12.38; p<0.001) and increased creatinine levels (OR: 4.102, 95% CI: 1.278-13.17; p=0.018) on the first day of the postoperative period were found to be independent predictors of AKI development (Table 3).

Table 3: Univariate and multivariate analysis of variables associated with development of postoperative AKI

In the ROC analysis, a creatinine level of 1.5 mg/dL as a cut-off value on the first day of the postoperative period showed 40% sensitivity and 90% specificity in predicting AKI (AUC: 0.718, 95% CI: 0.660-0.777; p<0.001) (Figure 1).

Figure 1: ROC curve analysis for postoperative first day creatinine level cut-off value in predicting development of postoperative AKI according to RIFLE criteria.
ROC: Receiver operating characteristics; AKI: Acute kidney injury; RIFLE: Risk, Injury, Failure, Loss, End-Stage Kidney Disease.

Discussion

In this study, we analyzed the data of diabetic patients who underwent isolated CABG and found no association between the time interval between CA and CABG and the risk of development of postoperative AKI defined according to the RIFLE criteria.

In several studies, it has been suggested that the development of postoperative AKI as an important risk factor for mortality and morbidity may be seen in 7.6 to 48.5% of cases.[1,15-20] Risk factors for AKI include female gender, DM, hypertension, heart failure, low left ventricular ejection fraction, peripheral vascular disease, the need for intra-aortic balloon pump, urgent or emergency surgery, preoperative nephropathy, use of diuretics, prolonged cross-clamp time, use of aprotinin, blood transfusion, CPB time, preoperative anemia, increased blood albumin, elevated blood uric acid levels, re-exploration, multiple grafts, mechanical ventilation time, preoperative angiography, and the use of contrast dye.[15-20] In our study, the rate of the patients with postoperative AKI was 25%, consistent with previous reports.[1-3,8,9]

As reported in previous studies, DM and the contrast agents used in CA are two well-known risk factors for the development of AKI.[15-20] Although CIN is seen in up to 10% of patients with normal kidney function, this rate increases up to 25% in those with underlying renal dysfunction.[21]

The mechanism of CIN involves the direct toxic effect of contrast agents as well as contrast-induced vasospasm leading to decreased renal medullary blood flow, resulting in medullary ischemia, enhanced reactive oxygen substrates formation, and oxidative stress.[4,5] Patient-related risk factors for contrast-induced AKI include pre-existing chronic kidney disease, DM and diabetic nephropathy, advanced age, concomitant use of nephrotoxic drugs, multiple myeloma, and reduced kidney perfusion (i.e., dehydration, congestive heart failure, and hemodynamic instability). Contrast agentrelated risk factors for CIN include a high volume of contrast agents, the use of hyperosmolar contrast agents, repeated exposure to contrast agents within a short period, and intra-arterial administration of contrast agents.[20] The presence of DM also doubles the risk of developing CIN, and multivariate analysis of a database previously defined diabetes as an independent risk factor with an OR of 1.9.[6,7]

Furthermore, the contrast agents used in CA and the stress of CABG (double-hit) may cause postoperative renal failure in these patients. Diabetes mellitus is a common risk factor for CAD and is also a risk factor for both CIN and AKI.[1-3,5-7] Therefore, it has been suggested that it may be necessary to optimize the time interval between CA and CABG to reduce the additive effect of contrast agents and surgery in patients with DM. However, there are no data in the literature regarding the optimal time interval for isolated CABG in these patients. We, therefore, believe that this study would contribute to the body of knowledge in the literature by providing more data on the optimum time interval required for these patients.

In our study, we stratified the patients with AKI into three subgroups according to time interval to evaluate the effect of contrast agents used for CA on AKI development. Contrast-induced nephropathy usually occurs within 48 h; however, this time may take as long as seven days. Therefore, we specified the time intervals as 0-3 days, 4-7 days, and >7 days. The rate of CIN was 7.2% in our study and there was no statistically significant difference in the logistic regression analysis among the three subgroups.

Studies by Del Duca et al.[22] and Medalion et al.[23] showed that surgery within the first five days after CA increased the risk of AKI development. Of note, the latter study included only patients with isolated CABG, while the Del Duca"s study included those who underwent different types of surgeries, such as isolated heart valve surgery, CABG + heart valve surgery, other complex surgeries, and emergency surgeries. In another study, Ranucci et al.[24] reported that surgery on the first day after CA increased the risk by threefold in patients who underwent mixed type surgeries. Similarly, Hennessy et al.[25] found an increased risk of valve surgery on the first day after CA.[25] By contrast, Brown et al.[26] concluded that it was safe to perform valve surgery on the same day as CA in selected patients. However, Mariscalco[12] reported t hat CABG with valve surgery within the first five days increased the risk of AKI, although this increase was not observed in patients who underwent isolated CABG.

Altogether, we can conclude that there are conflicting results in the literature on the optimal time interval between CA and CABG. This may be due to the fact that the types of surgeries included in the studies are different (i.e., isolated CABG, CABG + valve surgery, and other complex surgeries) and, also, some of the studies were unable to differentiate between urgent and emergency surgeries. In the present study, we included a group of patients with normal baseline renal function, more limited and less frequent variables with DM, and elective isolated CABG. Based on our results, the time interval between CA and CABG did not show a correlation with the risk of AKI in these patients. Another important result of our study is that the increase in serum creatinine levels on the first postoperative day was found to be associated with the risk of AKI. Based on previous studies and literature data, the increase in creatinine levels within first five to seven days after surgery is accepted in diagnosing postoperative AKI. However, in our study, serum creatinine levels above 1.5 mg/dL on the first postoperative day could be used with 40% sensitivity and 90% specificity for the risk assessment for AKI. This result suggests that we should consider early postoperative increases in creatinine levels and take necessary precautions, accordingly.

Limitations of this study include the single-center, retrospective design with potential selection biases. In order to detected the effect of time interval to postoperative AKI incidence prospective randomized studies must be done. Our study population was small.

In conclusion, our study results show no correlation between time delay for coronary artery bypass grafting after coronary angiography and reduced risk of acute kidney injury development in patients with diabetes mellitus who have normal baseline renal functions. Therefore, coronary artery bypass grafting should be performed, when it is appropriate for the surgeon and the patient. In addition, it is of utmost importance to follow the creatinine level of patients on the first postoperative day, particularly in patients having previous myocardial infarction.

Declaration of conflicting interests
The authors declared no conflicts of interest with respect to the authorship and/or publication of this article.

Funding
The authors received no financial support for the research and/or authorship of this article.

References

1) Olsson D, Sartipy U, Braunschweig F, Holzmann MJ. Acute kidney injury following coronary artery bypass surgery and long-term risk of heart failure. Circ Heart Fail 2013;6:83-90.

2) Garg AX, Devereaux PJ, Yusuf S, Cuerden MS, Parikh CR, Coca SG, et al. Kidney function after off-pump or on-pump coronary artery bypass graft surgery: a randomized clinical trial. JAMA 2014;311:2191-8.

3) Tolpin DA, Collard CD, Lee VV, Virani SS, Allison PM, Elayda MA, et al. Subclinical changes in serum creatinine and mortality after coronary artery bypass grafting. J Thorac Cardiovasc Surg 2012;143:682-8.

4) Mehran R, Nikolsky E. Contrast-induced nephropathy: definition, epidemiology, and patients at risk. Kidney Int Suppl 2006;100:S11-5.

5) Ozkok S, Ozkok A. Contrast-induced acute kidney injury: A review of practical points. World J Nephrol 2017;6:86-99.

6) Ribichini F, Graziani M, Gambaro G, Pasoli P, Pighi M, Pesarini G, et al. Early creatinine shifts predict contrastinduced nephropathy and persistent renal damage after angiography. Am J Med 2010;123:755-63.

7) Nemoto N, Iwasaki M, Nakanishi M, Araki T, Utsunomiya M, Hori M, et al. Impact of continuous deterioration of kidney function 6 to 8 months after percutaneous coronary intervention for acute coronary syndrome. Am J Cardiol 2014;113:1647-51.

8) Machado MN, Miranda RC, Takakura IT, Palmegiani E, Santos CA, Oliveira MA, et al. Acute kidney injury after on-pump coronary artery bypass graft surgery. Arq Bras Cardiol 2009;93:247-52.

9) Kim MY, Jang HR, Huh W, Kim YG, Kim DJ, Lee YT, et al. Incidence, risk factors, and prediction of acute kidney injury after off-pump coronary artery bypass grafting. Ren Fail 2011;33:316-22.

10) Yousefshahi F, Bashirzadeh M, Abdollahi M, Mojtahedzadeh M, Salehiomran A, Jalali A, et al. Effect of Hypertonic Saline Infusion versus Normal Saline on Serum NGAL and Cystatin C Levels in Patients Undergoing Coronary Artery Bypass Graft. J Tehran Heart Cent 2013;8:21-7.

11) Loef BG, Epema AH, Smilde TD, Henning RH, Ebels T, Navis G, et al. Immediate postoperative renal function deterioration in cardiac surgical patients predicts in-hospital mortality and long-term survival. J Am Soc Nephrol 2005;16:195-200.

12) Mariscalco G, Cottini M, Dominici C, Banach M, Piffaretti G, Borsani P, et al. The effect of timing of cardiac catheterization on acute kidney injury after cardiac surgery is influenced by the type of operation. Int J Cardiol 2014;173:46-54.

13) Mehta RH, Honeycutt E, Patel UD, Lopes RD, Williams JB, Shaw LK, et al. Relationship of the time interval between cardiac catheterization and elective coronary artery bypass surgery with postprocedural acute kidney injury. Circulation 2011;124:149-55.

14) Bellomo R1, Ronco C, Kellum JA, Mehta RL, Palevsky P; Acute Dialysis Quality Initiative workgroup. Acute renal failure - definition, outcome measures, animal models, fluid therapy and information technology needs: the Second International Consensus Conference of the Acute Dialysis Quality Initiative (ADQI) Group. Crit Care 2004;8:R204-12.

15) Li XH, Xiao F, Li Y, Wang J, Song B, Yang Y, et al.Investigations of influential factors of acute renal injury after coronary artery bypass grafting. Beijing Da Xue Xue Bao Yi Xue Ban 2009;41:554-7. [Abstract]

16) Karkouti K, Wijeysundera DN, Yau TM, Callum JL, Cheng DC, Crowther M, et al. Acute kidney injury after cardiac surgery: focus on modifiable risk factors. Circulation 2009;119:495-502.

17) Perez-Valdivieso JR, Monedero P, Vives M, Garcia- Fernandez N, Bes-Rastrollo M. Cardiac-surgery associated acute kidney injury requiring renal replacement therapy. A Spanish retrospective case-cohort study. BMC Nephrol 2009;10:27.

18) Thakar CV, Arrigain S, Worley S, Yared JP, Paganini EP. A clinical score to predict acute renal failure after cardiac surgery. J Am Soc Nephrol 2005;16:162-8.

19) Ling LG, Zeng N, Liu J, Peng Y, Duan S, Xia Y, et al. Risk factors for acute kidney injury following 5100 cardiac surgeries with extracorporeal circulation. Zhong Nan Da Xue Xue Bao Yi Xue Ban 2009;34:861-6. [Abstract]

20) Pakfetrat M, Nikoo MH, Malekmakan L, Tabande M, Roozbeh J, Reisjalali G, et al. Risk Factors for contrast-related acute kidney injury according to risk, injury, failure, loss, and end-stage criteria in patients with coronary interventions. Iran J Kidney Dis 2010;4:116-22.

21) Kelly AM, Dwamena B, Cronin P, Bernstein SJ, Carlos RC. Meta-analysis: effectiveness of drugs for preventing contrast-induced nephropathy. Ann Intern Med 2008;148:284-94.

22) Del Duca D, Iqbal S, Rahme E, Goldberg P, de Varennes B. Renal failure after cardiac surgery: timing of cardiac catheterization and other perioperative risk factors. Ann Thorac Surg 2007;84:1264-71.

23) Medalion B, Cohen H, Assali A, Vaknin Assa H, Farkash A, Snir E, et al. The effect of cardiac angiography timing, contrast media dose, and preoperative renal function on acute renal failure after coronary artery bypass grafting. J Thorac Cardiovasc Surg 2010;139:1539-44.

24) Ranucci M, Ballotta A, Agnelli B, Frigiola A, Menicanti L, Castelvecchio S. Acute kidney injury in patients undergoing cardiac surgery and coronary angiography on the same day. Ann Thorac Surg 2013;95:513-9.

25) Hennessy SA, LaPar DJ, Stukenborg GJ, Stone ML, Mlynarek RA, Kern JA, et al. Cardiac catheterization within 24 hours of valve surgery is significantly associated with acute renal failure. J Thorac Cardiovasc Surg 2010;140:1011-7.

26) Brown ML, Holmes DR, Tajik AJ, Sarano ME, Schaff HV. Safety of same-day coronary angiography in patients undergoing elective valvular heart surgery. Mayo Clin Proc 2007;82:572-4.

Keywords : Acute kidney injury; coronary angiography; coronary artery bypass grafting; diabetes mellitus
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