Journal Information
Vol. 38. Issue 4.
Pages 269-277 (April 2019)
Share
Share
Download PDF
More article options
Visits
3333
Vol. 38. Issue 4.
Pages 269-277 (April 2019)
Original Article
Open Access
Assessment of the relationship between preprocedural C-reactive protein/albumin ratio and stent restenosis in patients with ST-segment elevation myocardial infarction
Visits
3333
Ibrahim Rencuzogullaria,
Corresponding author
rencuzog@gmail.com

Corresponding author.
, Yavuz Karabağa, Metin Çağdaşa, Süleyman Karakoyuna, Sabri Seyisb, Mustafa Ozan Gürsoyc, Mahmut Yesind, İnanç Artaça, Doğan İlişa, İbrahim Halil Tanboğae
a M.D. Kafkas University Medical Faculty, Department of Cardiology, Kars, Turkey
b M.D. Istinye University Education and Research Hospital, Department of Cardiology, Istanbul, Turkey
c M.D. Gaziemir State Hospital, Department of Cardiology, İzmir, Turkey
d M.D. Kars Harakani State Hospital, Department of Cardiology, Kars, Turkey
e M.D. Ataturk University Medical Faculty, Department of Cardiology, Erzurum, Turkey
This item has received

Under a Creative Commons license
Article information
Abstract
Full Text
Bibliography
Download PDF
Statistics
Figures (3)
Show moreShow less
Tables (3)
Table 1. Demographic, clinical and laboratory characteristics of the total study population and of patients with and without restenosis.
Table 2. Univariate and multivariate logistic regression analysis of demographic, clinical, laboratory and coronary angiographic characteristics for prediction of restenosis.
Table 3. Demographic, clinical, laboratory and coronary angiographic characteristics of the study population stratified according to C-reactive protein/albumin ratio.
Show moreShow less
Abstract
Introduction

Stent restenosis remains a clinical challenge for patients with ischemic heart disease, since it is associated with repeated coronary interventions as well as higher hospitalization rates and medical costs. Inflammation plays a significant role. Although an association between stent restenosis, increased C-reactive protein (CRP) and decreased albumin levels has been previously reported, no studies have investigated the ability of the CRP/albumin ratio to predict stent restenosis.

Methods

This retrospective study included 448 patients who had previously undergone primary percutaneous coronary intervention and who were referred for subsequent reintervention due to recurrence of anginal symptoms. The study population was divided into two groups based on whether the patient had developed stent restenosis. They were then stratified into three groups according to their CRP/albumin ratio.

Results

Out of 448 patients, stent restenosis was observed in 24.5% (n=110), as determined by coronary angiography. Patients with stent restenosis had a higher CRP/albumin ratio, greater platelet distribution width (PDW), higher CRP levels, and lower levels of both high-density lipoprotein (HDL) cholesterol and serum albumin. The CRP/albumin ratio (OR: 2.289, 95% CI: 1.056-4.959; p=0.036), stent diameter, PDW and HDL cholesterol levels were found to be independent predictors of stent restenosis. A ROC curve comparison demonstrated that the CRP/albumin ratio was a better predictor of restenosis than either albumin and CRP individually, but it was not better than PDW and HDL cholesterol.

Conclusion

As a novel inflammation-based risk score, the CRP/albumin ratio may be an easily accessible marker for assessment of stent restenosis risk.

Keywords:
Stent restenosis
C-reactive protein/albumin ratio
ST-segment elevation myocardial infarction
Inflammation
Resumo
Objetivo

A reestenose de stent permanece como um desafio clínico em doentes com cardiopatia isquémica. A reestenose de stent está associada a intervenções coronárias recorrentes bem como a aumento de internamentos e de custos médicos. A inflamação tem um papel significativo. Embora a associação entre reestenose de stent e o aumento dos níveis de proteína C-reativa (PCR) e a diminuição dos níveis de albumina tenham sido previamente registados, nenhum estudo pesquisou a possibilidade da PCR/albumina prever um diagnóstico de reestenose de stent.

Métodos

Este estudo retrospetivo incluiu 448 doentes que tinham sido previamente submetidos a intervenção coronária percutânea primária e que foram referidos para reintervenção posterior devido a ressurgimento dos sintomas de angina. A população do estudo foi dividida em dois grupos com base no facto do doente ter desenvolvido reestenose de stent. Posteriormente, foram estratificados em três grupos de acordo com as relações PCR/albumina.

Resultados

De um grupo de 448 doentes, a reestenose de stent foi observada em 24,5% (n = 110), conforme determinado por avaliação através de angiografia coronária. Os doentes com reestenose de stent apresentaram uma relação PCR/albumina mais elevada, variação maior do diâmetro das plaquetas (DP), níveis mais elevados de PCR e níveis mais baixos de colesterol de lipoproteínas de alta densidade (HDL) e de albumina sérica. Os níveis da relação PCR/albumina (OR: 2,289, IC 95%:1,056 – 4,959; p = 0,036), o diâmetro do stent, a variação maior do DP e o colesterol HDL foram considerados fatores preditores independentes da restenose de stent. A comparação das curvas ROC demonstrou que a relação PCR/albumina constituiu um fator preditor melhor do que a albumina e a PCR, isoladamente, não sendo, no entanto, melhor do que o DP e o colesterol HDL.

Conclusão

Como novo score de risco baseado em inflamação, a relação PCR/albumina pode ser um marcador facilmente acessível para a avaliação do risco de reestenose de stent.

Palavras chave:
Reestenose de stent
Proteína C reativa/albumina
Enfarte do miocárdio com elevação do segmento ST
Inflamação
Full Text
Introduction

Deaths from ischemic heart disease have decreased in recent years due to increased use of percutaneous coronary intervention (PCI). Primary PCI (pPCI) is generally the first line of treatment for patients with ST-segment elevation myocardial infarction (STEMI), and stenting is recommended over balloon angioplasty.1 However, restenosis, a gradual re-narrowing of the stented segment, continues to be a clinical challenge. Stent restenosis decreases the patient's quality of life and is associated with repeated coronary interventions as well as higher hospitalization rates and medical costs.2–4

Stent restenosis is a complex and multifactorial process that begins with stent deployment in the coronary artery.5 Inflammation plays a key role in arterial damage after stent placement, accelerating macrophage accumulation and neovascularization. The inflammation process also leads to neointimal tissue proliferation, thrombus formation at the stent struts and activation of neutrophils, fibrin and platelets, all of which result in stent restenosis.6,7 Studies on stent-induced inflammation have found a significant association between C-reactive protein (CRP) and stent restenosis.5,8,9 An acute phase protein that is released from the liver, CRP is a useful marker for objectively stratifying an active inflammation process. Similarly, serum albumin is a negative acute phase protein in acute inflammation and has been shown to have an inverse relationship with stent restenosis.10

The CRP/albumin ratio has been identified as an inflammation-based prognostic marker and is considered to reflect the relationship between CRP and albumin levels in determining the prognosis of critical diseases and malignancy.11,12 The fact that the CRP/albumin ratio is a good indicator of inflammatory status led us to investigate its relationship with stent restenosis. In this study, we aimed to assess whether the CRP/albumin ratio and levels of CRP and albumin at the time of initial pPCI are associated with subsequent stent restenosis in STEMI patients who were treated with bare-metal stents (BMS).

MethodsStudy population

Between January 2010 and June 2016, 1844 STEMI patients were referred for coronary angiography and pPCI, and these formed the basis of our study population. Of these, 191 were excluded from the study: those referred for emergency coronary artery bypass graft surgery, those treated noninvasively, those under hemodialysis, and those with malignancy, fever or an autoimmune disorder. Of the remaining 1653 patients, 448 were referred for redo coronary angiography due to recurrence of anginal symptoms and were therefore included in this retrospective study (Figure 1). The first STEMI was defined based on the following criteria: a typical increase or decrease in cardiac biomarkers; ongoing ischemic symptoms (within 12 hours of presentation); newly developed left bundle branch block pattern or new ST elevation in two or more contiguous leads, with readings of at least 0.2 mV in leads V1, V2 and V3 or at least 0.1 mV in the other leads; or imaging evidence of a new loss of viable myocardium or new regional wall motion abnormality.13 Stent restenosis was defined as the presence of clinical symptoms and/or signs of ischemia and at least 50% narrowing in lumen diameter at follow-up angiography.14

Figure 1.

Flowchart of enrollment and follow-up of study patients.

(0.4MB).

The study protocol was reviewed and approved by the local ethics committee of Kafkas University and was conducted in accordance with the Declaration of Helsinki.

Data collection

All patients who were referred for coronary reintervention due to recurrence of ischemic symptoms were hospitalized. To establish the effects of the first pPCI on subsequent stent restenosis, patients’ baseline clinical, demographic, biochemical and hematological characteristics at the time of the first pPCI were recorded. Complete blood count and blood biochemical parameters were assessed in all patients on admission and prior to pPCI. CRP and serum albumin levels were determined using an automatic biochemical analyzer (Cobas 8000 c502, Roche Diagnostics). The CRP/albumin ratio was calculated as the ratio of CRP to albumin multiplied by 10 for ease of interpretation. The neutrophil/lymphocyte ratio was calculated from the complete blood count obtained on admission. Blood samples were retested for creatine kinase-myocardial band (CK-MB) every six hours until peak levels were identified. The estimated glomerular filtration rate (eGFR) was determined using the Cockcroft-Gault formula from the blood samples obtained on admission. Left ventricular ejection fraction (LVEF) was defined as the postprocedural ejection fraction and was assessed using a modified version of Simpson's method.

Angiographic analysis

The standard Judkins percutaneous transfemoral technique was performed by experienced interventional cardiologists on all patients who underwent pPCI. Coronary angiograms and pPCIs were recorded using digital media (DICOM viewer, MedCom GmbH, Darmstadt, Germany). The digital angiography and PCI records of all patients who were admitted with STEMI and underwent BMS implantation (the records of the first angiography) were analyzed quantitatively in terms of lesion and intervention characteristics. Coronary blood flow patterns before and after pPCI were assessed using Thrombolysis in Myocardial Infarction (TIMI) flow grade as defined previously, and epicardial no-reflow was defined as TIMI flow grade <3 at the target vessel lesion in the absence of spasm, thrombus, dissection and/or significant residual stenosis.15 Similarly, thrombus burden was assessed according to the TIMI thrombus grading scale as defined by Gibson et al.15 The sizes of the stents used in the interventions were confirmed from hospital records. All patients had received 300 mg aspirin and a 600-mg loading dose of clopidogrel on a routine basis before the intervention and received unfractionated heparin during the intervention. The decision whether to use tirofiban was left to the operator's discretion.

Statistical analysis

The statistical analysis was performed using IBM SPSS version 22.0 (IBM SPSS Inc., Chicago, IL). The normality of the data was determined using the Kolmogorov-Smirnov test. With respect to data distribution and normality, continuous variables were expressed as mean ± standard deviation or median [interquartile range] (25th-75th percentiles), and the t test or Mann-Whitney U-test was conducted to compare variables between two groups. Continuous variables with and without normal distribution were compared between three groups using analysis of variance and the Kruskal-Wallis H-test, respectively. Categorical variables were presented as numbers (percentages) and compared using Fisher's exact test or the chi-square test. Multivariate logistic regression analysis was performed to identify independent predictors of stent restenosis using variables that showed a statistically significant association with stent restenosis in univariate analysis. Multicollinearity between the CRP/albumin ratio and CRP and albumin levels was assessed by eigenvalues and condition indices. Linearity was tested following the logarithmic transformation of each parameter. A receiver operating characteristic (ROC) curve was used to derive the best cut-off value of the CRP/albumin ratio for predicting stent restenosis using Youden's J statistic. A p-value <0.05 was taken to indicate statistical significance.

Results

The study population consisted of 448 patients who underwent repeat coronary intervention (mean age 56±11 years; 17.8% female). The mean interval between coronary reintervention and the first STEMI was 21.07±3.89 months. Stent restenosis was observed in 24.5% (n=110) of the study population who underwent a second coronary angiography. The baseline clinical and angiographic characteristics of the total population and of patients with and without stent restenosis are shown in Table 1. Patients with stent restenosis had a higher CRP/albumin ratio, more frequent involvement of the left anterior descending artery (LAD), greater platelet distribution width (PDW), higher CRP levels, and lower levels of both high-density lipoprotein (HDL) cholesterol and serum albumin, compared to those without stent restenosis. Furthermore, patients with stent restenosis had higher thrombus burden, greater stent length and smaller angiographic reference lumen diameter, and had more frequently received tirofiban infusion at the time of the first pPCI. There was no difference between the two groups in terms of preprocedural TIMI flow (Table 1).

Table 1.

Demographic, clinical and laboratory characteristics of the total study population and of patients with and without restenosis.

  Total population (n=448)  Patients without SR (n=338)  Patients with SR (n=110) 
Age, years  56±11  56±11  57±12  0.209 
Female, n (%)  81.0 (18.10)  60.0 (17.80)  21.0 (19.10)  0.751 
Diabetes, n (%)  102.0 (22.80)  73.0 (21.60)  29.0 (26.40)  0.301 
Hypertension, n (%)  180.0 (40.20)  132.0 (39.10)  48.0 (43.60)  0.395 
Hyperlipidemia, n (%)  184.0 (41.10)  132.0 (39.10)  52.0 (47.30)  0.128 
Smoking, n (%)  245.0 (54.70)  180.0 (53.30)  65.0 (59.10)  0.286 
LVEF, %  47.51±7.49  47.71±7.42  46.94±7.71  0.208 
Total ischemia time, min, median [IQR]  173.5 [117.0-256.5]  174.0 [118.0-245.0]  168.5 [110.0-262.0]  0.779 
IRA, n (%)
LAD  231.0 (51.60)  170.0 (50.30)  61.0 (55.50)  0.032 
RCA  165.0 (36.80)  133.0 (39.30)  32.0 (29.10)   
CX  52.0 (11.60)  35.0 (10.40)  17.0 (15.50)   
Proximal/ostial lesion as IRA, n (%)  255.0 (56.90)  192.0 (56.80)  63.0 (57.30)  0.931 
High-grade thrombus burden, n (%)  237.0 (52.90)  168.0 (49.70)  69.0 (62.70)  0.017 
Pre-dilatation, n (%)  358.0 (79.90)  267.0 (79.00)  91.0 (82.70)  0.397 
Tirofiban infusion n (%)  186.0 (41.50)  127.0 (37.60)  59.0 (53.60)  0.003 
Stent length, mm  22.24±9.65  21.97±9.80  23.06±9.16  0.029 
Stent diameter, mm  3.10±0.37  3.13±0.37  3.01±0.35  0.009 
Post-dilatation, n (%)  112.0 (25.00)  86.0 (25.40)  26.0 (23.60)  0.704 
No-reflow, n (%)  44.0 (9.80)  30.0 (8.90)  14.0 (12.70)  0.239 
Time from first STEMI to reintervention, months  21.07±3.89  22.31±2.62  17.25±4.60   
Hemoglobin, g/dl  13.8±1.7  13.7±1.8  13.8±1.4  0.533 
WBC count, /1000  12.032±3.552  12.151±3.650  11.665±3.221  0.322 
Platelet count, 10 000/ml  254±62  254±63  254±60  0.876 
Mean platelet volume, fl  9.3±1.3  9.3±1.2  9.2±1.4  0.337 
PDW, %  16.20±1.37  16.11±1.34  16.48±1.42  0.001 
Neutrophil count, /1000  9.168±3.313  9.252±3.403  8.912±3.017  0.483 
Lymphocyte count, /1000, median [IQR]  1.800 [1.30-2.50]  1.800 [1.30-2.50]  1.700 [1.30-2.50]  0.648 
Neutrophil-to-lymphocyte ratio, median [IQR]  4.80 [3.20-7.26]  4.85 [3.24-7.23]  4.69 [3.14-7.36]  0.984 
Total cholesterol, mg/dl  178.81±43.03  180.88±43.92  172.17±39.52  0.082 
LDL-C, mg/dl  111.55±35.82  112.31±36.12  109.13±34.90  0.336 
HDL-C, mg/dl  40.25±12.51  41.20±12.63  37.20±11.67  0.002 
Triglycerides, mg/dl, median [IQR]  121.00 [87.0-168.5]  123.00 [88.0-171.0]  115.00 [76.0-167.0]  0.172 
Glucose on admission, mg/dl, median [IQR]  126.00 [105.5-168.5]  125.00 [103.0-170.0]  133.50 [110.0-165.0]  0.110 
eGFR, ml/min/1.73 m2  91.62±24.31  92.25±24.83  89.67±22.65  0.179 
CRP, mg/dl, median [IQR]  9.26 [5.34-16.45]  8.86 [4.78-15.40]  11.00 [6.75-18.70]  0.009 
Serum albumin, g/dl  3.86±0.47  3.89±0.48  3.77±0.43  0.006 
Total protein, g/dl  6.67±0.62  6.69±0.63  6.62±0.61  0.546 
CRP/albumin ratio, median [IQR]  0.258 [0.139-0.421]  0.237 [0.117-0.39]  0.300 [0.182-0.51]  0.003 
Baseline uric acid, mg/dl  5.06±1.40  5.10±1.40  4.92±1.40  0.195 
Peak CK-MB, ng/ml, median [IQR]  167.00 [97.0-303.0]  170.50 [99.0-303.0]  149.00 [90.0-301.0]  0.774 

CK-MB: creatine kinase-myocardial band; CRP: C-reactive protein; CX: circumflex artery; eGFR: estimated glomerular filtration rate; HDL-C: high-density lipoprotein cholesterol; IQR: interquartile range (25th-75th percentiles); IRA: infarct-related artery; LAD: left anterior descending artery; LDL-C: low-density lipoprotein cholesterol; LVEF: left ventricular ejection fraction; PDW: platelet distribution width; RCA: right coronary artery; SR: stent restenosis; STEMI: ST-segment elevation myocardial infarction; WBC: white blood cell.

Multivariate regression analysis was used to determine the independent predictors of stent restenosis using the parameters that were associated with stent restenosis in univariate analysis. The CRP/albumin ratio (odds ratio [OR]: 2.289, 95% confidence interval [CI]: 1.056-4.959; p=0.036), stent diameter (per 1 mm, OR: 0.370, 95% CI: 0.180-0.760; p=0.007), PDW (per 1 percent, OR: 1.247, 95% CI: 1.023-1.522; p=0.029), and HDL cholesterol (OR: 0.973, 95% CI: 0.952-0.994; p=0.014) were found to be independent predictors of stent restenosis (Table 2).

Table 2.

Univariate and multivariate logistic regression analysis of demographic, clinical, laboratory and coronary angiographic characteristics for prediction of restenosis.

  Univariate analysisMultivariate analysis
  OR  95% CI  OR  95% CI 
Stent diameter (per 1 mm)  0.401  0.210-0.764  0.005  0.370  0.180-0.760  0.007 
PDW (per 1 percent)  1.252  1.041-1.506  0.017  1.247  1.023-1.522  0.029 
HDL-C (mg/dl)  1.252  1.041-1.506  0.017  0.973  0.952-0.994  0.014 
CRP/albumin ratio  2.539  1.285-5.016  0.007  2.289  1.056-4.959  0.036 

CI: confidence interval; CRP: C-reactive protein; HDL-C: high-density lipoprotein cholesterol; OR: odds ratio; PDW: platelet distribution width.

The variables included in the multivariate analysis were infarct-related artery, high-grade thrombus burden, stent length, stent diameter, PDW, HDL cholesterol and CRP/albumin ratio.

Because no specific cut-off was identified for the CRP/albumin ratio, subjects who underwent repeat coronary angiography were stratified into three groups according to CRP/albumin ratio by equalizing the number of patients: tertile 1 (<0.170, n=149), tertile 2 (0.170-0.363, n=150) and tertile 3 (>0.363, n=149). There were significant differences between these tertiles. Mean CRP level, age, frequency of hypertension, total ischemia time, peak CK-MB, incidence of proximal coronary lesion involvement, LAD involvement as the infarct-related artery, and presence of no-reflow increased progressively from tertile 1 to tertile 3, while LVEF and albumin levels decreased progressively (Table 3). It was also observed that stent restenosis increased progressively with the tertiles’ increasing CRP/albumin ratio (Table 3).

Table 3.

Demographic, clinical, laboratory and coronary angiographic characteristics of the study population stratified according to C-reactive protein/albumin ratio.

  CRP/albumin ratio
  <0.170 (n=149)  0.170-0.363 (n=150)  >0.363 (n=149) 
Age  54±11  56±11  59±12  0.002 
Female, n (%)  24.0 (16.10)  23.0 (15.30)  34.0 (22.80)  0.182 
Diabetes, n (%)  34.0 (22.80)  33.0 (22.00)  35.0 (23.50)  0.954 
Hypertension, n (%)  48.0 (32.20)  58.0 (38.70)  74.0 (49.70)  0.008 
Hyperlipidemia, n (%)  59.0 (39.60)  68.0 (45.30)  57.0 (38.30)  0.418 
Smoking, n (%)  77.0 (51.70)  88.0 (58.70)  80.0 (53.70)  0.459 
LVEF, %  49.85±6.45  48.21±6.65  44.43±8.25  <0.001 
Total ischemia time, min, median [IQR]  145.0 [112.0-223.0]  168.5 [105.0-235.0]  190.0 [137.0-308.0]  <0.001 
IRA, n (%)
LAD  65.0 (43.60)  78.0 (52.00)  88.0 (59.10)  0.044 
RCA  66.0 (44.30)  57.0 (38.00)  42.0 (28.20)   
CX  18.0 (12.10)  15.0 (10.00)  19.0 (12.80)   
Proximal/ostial lesion for IRA, n (%)  73.0 (49.00)  85.0 (56.70)  97.0 (65.10)  0.020 
High-grade thrombus burden, n (%)  90.0 (60.40)  97.0 (64.70)  100.0 (67.10)  0.475 
Pre-dilatation, n (%)  116.0 (77.90)  117.0 (78.00)  125.0 (83.90)  0.333 
Tirofiban infusion, n (%)  61.0 (40.90)  64.0 (42.70)  61.0 (40.90)  0.941 
Stent length, mm  22.50±11.22  22.16±8.76  22.06±8.83  0.999 
Stent diameter, mm  3.13±0.35  3.09±0.40  3.08±0.36  0.216 
Post-dilatation, n (%)  31.0 (20.80)  44.0 (29.30)  37.0 (24.80)  0.235 
No-reflow, n (%)  6.0 (4.00)  14.0 (9.30)  24.0 (16.10)  0.002 
Time from first STEMI to reintervention (months)  21.38±2.98  21.00±3.97  20.82±4.55   
Hemoglobin, g/dl  13.6±1.8  13.8±1.6  13.8±1.7  0.867 
WBC count, /1000  11.737±3.373  12.046±3.339  12.312±3.917  0.428 
Platelet count, 10 000/ml  255±61  250±61  257±65  0.599 
Mean platelet volume, fl  9.1±1.2  9.3±1.3  9.3±1.4  0.458 
PDW, %  16.22±1.22  16.34±1.39  16.05±1.47  0.747 
Neutrophil count, /1000  8.914±3.041  9.223±3.078  9.368±3.774  0.579 
Lymphocyte count, /1000, median [IQR]  1.700 [1.20-2.50]  1.800 [1.30-2.40]  1.800 [1.40-2.60]  0.358 
Neutrophil-to-lymphocyte ratio, median [IQR]  5.00 [3.16-7.82]  4.76 [3.59-7.21]  4.65 [2.99-7.06]  0.730 
Total cholesterol, mg/dl  177.04±41.82  182.73±43.21  176.61±44.08  0.313 
LDL-C, mg/dl  109.01±34.43  117.01±35.81  108.56±36.81  0.107 
HDL-C, mg/dl  41.24±13.46  39.42±11.74  40.08±12.30  0.756 
Triglycerides, mg/dl, median [IQR]  120.00 [85.0-183.5]  124.00 [86.0-159.0]  119.0 [88.0-158.0]  0.939 
Glucose on admission, mg/dl, median [IQR]  126.00 [103.0-167.0]  124.00 [103.0-168.0]  133.00 [109.0-169.0]  0.323 
eGFR, ml/min/1.73 m2  95.96±26.34  90.93±23.18  87.97±22.74  0.029 
CRP, mg/dl, median [IQR]  4.070 [2.88-5.33]  9.265 [7.70-12.10]  20.50 [16.40-24.50]  <0.001 
Serum albumin, g/dl  3.95±0.52  3.83±0.42  3.80±0.47  0.013 
Total protein, g/dl  6.70±0.61  6.66±0.61  6.65±0.66  0.799 
CRP/albumin ratio, median [IQR]  0.106 [0.073-0.14]  0.258 [0.204-0.31]  0.518 [0.422-0.69]  <0.001 
Baseline uric acid, mg/dl  4.87±1.32  5.12±1.36  5.17±1.50  0.202 
Peak CK-MB, ng/ml, median [IQR]  122.00 [82.0-218.0]  160.5 [102.0-289.0]  234.0 [120.0-373.0]  <0.001 
Stent restenosis, n (%)  24.0 (16.10)  41.0 (27.3)  45.0 (30.2)  0.010 

CK-MB: creatine kinase-myocardial band; CRP: C-reactive protein; CX: circumflex artery; eGFR: estimated glomerular filtration rate; HDL-C: high-density lipoprotein cholesterol; IQR: interquartile range (25th-75th percentiles); IRA: infarct-related artery; LAD: left anterior descending artery; LDL-C: low-density lipoprotein cholesterol; LVEF: left ventricular ejection fraction; PDW: platelet distribution width; RCA: right coronary artery; STEMI: ST-segment elevation myocardial infarction; WBC: white blood cell.

In ROC curve analysis, the area under the curve (AUC) of the CRP/albumin ratio was 0.601 (95% CI: 0.540-0.661; p<0.001). The cut-off value for the CRP/albumin ratio that indicated stent restenosis was 0.167 (with 80.9% sensitivity and 36.1% specificity). ROC curve comparisons were used to determine which variables best predicted stent restenosis. The CRP/albumin ratio was a better predictor than both serum albumin (AUC: 0.577, 95% CI: 0.516-0.638) and CRP (AUC: 0.582, 95% CI: 0.524-0.641) (p=0.050 and p=0.008, respectively) (Figure 2), but there was no significant difference between CRP/albumin ratio and PDW (AUC: 0.604, 95% CI 0.541-0.667) and HDL cholesterol (AUC: 0.602, 95% CI: 0.538-0.665) (p=0.942 and p=0.961, respectively) (Figure 3).

Figure 2.

Receiver operating characteristic curves to detect the best variable for predicting stent restenosis. AUC: area under the curve; CRP: C-reactive protein.

(0.1MB).
Figure 3.

Receiver operating characteristic curves comparing independent predictors of laboratory parameters to detect the best predictor of stent restenosis. AUC: area under the curve; CRP: C-reactive protein; HDL-C: high-density lipoprotein cholesterol; PDW: platelet distribution width.

(0.1MB).
Discussion

Our study demonstrated that the CRP/albumin ratio was not only associated with, but was also an independent predictor of stent restenosis in STEMI patients undergoing pPCI. The CRP/albumin ratio was better than both CRP and serum albumin levels, individually, in predicting stent restenosis.

pPCI is the standard treatment for patients with STEMI. Compared with balloon angioplasty alone, stenting with a BMS is associated with a lower risk of reinfarction and target vessel revascularization.1 However, with a restenosis rate of 12.7% with drug-eluting stents (DES) and 20.1% with BMS, stent restenosis remains a major concern for the management of STEMI in patients treated with pPCI.16 In our study, stent restenosis was observed in 24.5% of patients who were referred for repeat coronary angiography.

The etiology of stent restenosis is complex and multifactorial. Several risk factors have been identified, including angiographic, clinical and technical factors. Consistent with the results of previous studies, patients with stent restenosis in our study had longer stents and smaller stent lumen diameter,17 higher CRP levels,5,8,9 and lower levels of HDL cholesterol18 and serum albumin.10 Additionally, the CRP/albumin ratio was significantly higher and PDW was greater in patients with restenosis than in those without.

Inflammation plays a central role in stent restenosis. It has been previously established in animal models that there is a significant correlation between the severity of arterial inflammation and neointimal hyperplasia following balloon angioplasty and stenting.19,20 The local inflammatory reaction induced by the trauma of stenting leads to the release of cytokines and growth factors from macrophages and smooth muscle cells, resulting in a proliferative response.21 More importantly, higher baseline levels of acute-phase proteins indicate the hyper-responsiveness of inflammatory cells to any inflammatory stimuli.22 Hence, higher systemic CRP levels or lower serum albumin levels identify patients with an enhanced inflammatory response in the vessel wall to the inflammatory stimulus of stenting. In our study, baseline CRP levels were higher and serum albumin levels were significantly lower in patients with stent restenosis. These findings strongly suggest that baseline inflammatory status is a determining factor in the development of stent restenosis, in addition to the classical etiological factors.

We found that the baseline inflammatory response was exacerbated in patients with restenosis. We also observed that patients’ baseline inflammatory status was related to factors associated with a larger infarct area, including LAD involvement as the culprit lesion, no-reflow, prolonged total ischemia time and elevated peak CK-MB levels. Acute myocardial infarction triggers an inflammatory response that lasts for weeks and months, and this mid-term inflammatory response seems to be more severe in patients with large infarcts and high baseline inflammation.23 However, an increased baseline inflammatory response in patients with restenosis cannot be explained by infarct size alone. Our patients with increased CRP/albumin ratios were older and more frequently had a history of hypertension in addition to reduced eGFR and LVEF. Chronic renal insufficiency has been associated with background inflammation,24 and there is a consistent correlation between heart failure (lower LVEF) and inflammation.25 In addition, aging is accompanied by two- to four-fold increases in the plasma/serum levels of inflammatory mediators such as cytokines and acute phase proteins.26 Hypertension is also clearly associated with chronic mild inflammation.27 Although not all these factors were found to be individually associated with stent restenosis in our study, their cumulative effect might have contributed to an association between the CRP/albumin ratio and restenosis.

The various acute phase reactants may not all respond to inflammatory events to the same degree. Merging albumin and CRP into a single index as an inflammation-based prognostic score provides stability between fluctuating CRP and albumin levels in diseases where inflammation plays an important role. The CRP/albumin ratio has been used as a parameter of inflammatory status in many studies.11,12,28,29 Consistent with previous findings, the present study showed that the CRP/albumin ratio was a better predictor of stent restenosis than either CRP or albumin, individually, in ROC curve analysis.

Interestingly, the present study found PDW to be an independent predictor of stent restenosis. PDW indicates variability in platelet size, which is directly related to platelet density and reactivity in circulating platelets. Changes in these variables play an important role in the development of acute coronary syndrome.30 Recently, it has been shown that PDW is associated with acute stent thrombosis31 and is an independent predictor of no-reflow and in-hospital major cardiac adverse events32 in STEMI patients. In this study, for the first time, we demonstrated that PDW is an independent predictor of stent restenosis.

In addition to inflammation-induced neointimal hyperplasia and vascular remodeling, oxidative stress and increased vascular levels of reactive oxygen species are also thought to be involved in the pathophysiology of stent restenosis.33,34 HDL cholesterol molecules reduce macrophage accumulation, promote removal of oxidized cholesterol from the arterial wall, and can inhibit monocyte activation, adhesiveness and inflammation.35–37 Previous studies have shown that lower HDL levels are an independent risk factor for stent restenosis in different patient groups.38–40 Our study also showed that HDL cholesterol is an independent predictor of stent restenosis. A comparison of the ROC curves showed that CRP/albumin ratio, PDW and HDL cholesterol levels were not inferior to each other in predicting stent restenosis.

Limitations

The present study has several limitations. First, although the data were acquired prospectively, the study had a retrospective design and was based on a registry analysis. Second, this study provided information about stent restenosis in STEMI patients treated with BMS; it did not include information on patients treated with DES, which currently are widely used. Third, high-sensitivity CRP, which has proven efficacy in demonstrating endovascular inflammation, could not be used in our study, due to the lack of this information in our subjects’ patient records. Finally, the prognostic value of the CRP/albumin ratio could not be assessed in the present study. Stent restenosis and patient prognosis may not necessarily correlate; therefore, the prognostic value of the CRP/albumin ratio in the development of stent restenosis should be verified by further research.

Conclusion

This study suggests that baseline inflammatory status appears to be a significant factor in subsequent stent restenosis in STEMI patients. Based on the evidence that the CRP/albumin ratio is a better predictor than CRP or albumin, individually, assessment of a patient's preprocedural CRP/albumin ratio could be beneficial. In STEMI patients, a high CRP/albumin ratio on admission may be an early, mid- and long-term marker of inflammation that could lead to stent restenosis. Although this study only analyzed restenosis with BMS, which does not correspond to the majority of stents currently used in developed countries, the mechanisms underlying stent restenosis may be common to other types of stents, and this research may be a bridge to DES studies. Additionally, for the first time, PDW has been found to be an independent predictor of stent restenosis. Therefore, PDW may be another easily accessible marker for the risk assessment of stent restenosis.

Funding

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

Conflicts of interest

The authors have no conflicts of interest to declare

Acknowledgments

The authors thank www.metastata.com for their contributions to the statistical analysis and trial design.

References
[1]
B. Ibanez, S. James, S. Agewall, et al.
2017 ESC Guidelines for the management of acute myocardial infarction in patients presenting with ST-segment elevation: The Task Force for the management of acute myocardial infarction in patients presenting with ST-segment elevation of the European Society of Cardiology (ESC).
[2]
M.S. Chen, J.M. John, D.P. Chew, et al.
Bare metal stent restenosis is not a benign clinical entity.
Am Heart J, 151 (2006), pp. 1260-1264
[3]
K.R. Bainey, C.M. Norris, M.M. Graham, et al.
APPROACH investigators. Clinical in-stent restenosis with bare metal stents: is it truly a benign phenomenon?.
Int J Cardiol, 128 (2008), pp. 378-382
[4]
E. Remak, S. Manson, J. Hutton, et al.
Cost-effectiveness of the Endeavor stent in de novo native coronary artery lesions updated with contemporary data.
EuroIntervention, 5 (2010), pp. 826-832
[5]
G. Ferrante, G. Niccoli, L.M. Biasucci, et al.
Association between C-reactive protein and angiographic restenosis after bare metal stents: an updated and comprehensive meta-analysis of 2747 patients.
Cardiovasc Revasc Med, 9 (2008), pp. 156-165
[6]
R. Komatsu, M. Ueda, T. Naruko, et al.
Neointimal tissue response at sites of coronary stenting in humans: macroscopic, histological, and immunohistochemical analyses.
Circulation, 98 (1998), pp. 224
[7]
A. Farb, G. Sangiorgi, A.J. Carter, et al.
Pathology of acute and chronic coronary stenting in humans.
Circulation, 99 (1999), pp. 44
[8]
D. Silva, A. Pais de Lacerda.
High-sensitivity C-reactive protein as a biomarker of risk in coronary artery disease.
Rev Port Cardiol, 31 (2012), pp. 733-745
[9]
J.J. Li, Y. Ren, K.J. Chen, et al.
Impact of C-reactive protein on in-stent restenosis: a meta-analysis.
Tex Heart Inst J, 37 (2010), pp. 49-57
[10]
I.E. Celik, M. Yarlioglues, A. Kurtul, et al.
Preprocedural albumin levels and risk of in-stent restenosis after coronary stenting with bare-metal stent.
Angiology, 67 (2016), pp. 478-483
[11]
A. Kinoshita, H. Onoda, N. Imai, et al.
The C-reactive protein/albumin ratio, a novel inflammation-based prognostic score, predicts outcomes in patients with hepatocellular carcinoma.
Ann Surg Oncol, 22 (2015), pp. 803-810
[12]
E. Fairclough, E. Cairns, J. Hamilton, et al.
Evaluation of a modified early warning system for acute medical admissions and comparison with C-reactive protein/albumin ratio as a predictor of patient outcome.
Clin Med, 9 (2009), pp. 30-33
[13]
P.G. Steg, S.K. James, D. Atar, et al.
ESC guidelines for the management of acute myocardial infarction in patients presenting with ST-segment elevation.
Eur Heart J, 33 (2012), pp. 2569-2619
[14]
G.D. Dangas, B.E. Claessen, A. Caixeta, et al.
In-stent restenosis in the drug-eluting stent era.
J Am Coll Cardiol, 56 (2010), pp. 1897-1907
[15]
C.M. Gibson, C.P. Cannon, W.L. Daley, et al.
TIMI frame count: a quantitative method of assessing coronary artery flow.
Circulation, 93 (1996), pp. 879-888
[16]
M.T. Dirksen.
Drug-eluting vs bare-metal stents in primary angioplasty.
Arch Intern Med, 172 (2012), pp. 611
[17]
P.J. de Feyter, P. Kay, C. Disco, et al.
Reference chart derived from post-stent-implantation intravascular ultrasound predictors of 6-month expected restenosis on quantitative coronary angiography.
Circulation, 100 (1999), pp. 1777-1783
[18]
X.D. Jing, X.M. Wei, S.B. Deng, et al.
The relationship between the high-density lipoprotein (HDL)-associated sphingosine-1-phosphate (S1P) and coronary in-stent restenosis.
Clin Chim Acta, 446 (2015), pp. 248-252
[19]
R.S. Schwartz, K.C. Huber, J.G. Murphy, et al.
Restenosis and the proportional neointimal response to coronary artery injury: results in a porcine model.
J Am Coll Cardiol, 19 (1992), pp. 267-274
[20]
S.P. Karas, M.B. Gravanis, E.C. Santoian, et al.
Coronary intimal proliferation after balloon injury and stenting in swine: an animal model of restenosis.
J Am Coll Cardiol, 20 (1992), pp. 467-474
[21]
P. Libby, D. Schwartz, E. Brogi, et al.
A cascade model for restenosis. A special case of atherosclerosis progression.
Circulation, 86 (1992), pp. III47-III52
[22]
G. Liuzzo, A. Buffon, L.M. Biasucci, et al.
Enhanced inflammatory response to coronary angioplasty in patients with severe unstable angina.
Circulation, 98 (1998), pp. 2370-2376
[23]
S.D. Prabhu, N.G. Frangogiannis.
The biological basis for cardiac repair after myocardial infarction: from inflammation to fibrosis.
Circ Res, 119 (2016), pp. 91-112
[24]
V. Cachofeiro, M. Goicochea, S.G. de Vinuesa, et al.
Oxidative stress and inflammation, a link between chronic kidney disease and cardiovascular disease.
Kidney Int Suppl, (2008), pp. S4-S9
[25]
L.F. Shirazi, J. Bissett, F. Romeo, et al.
Role of inflammation in heart failure.
Curr Atheroscler Rep, 19 (2017), pp. 27
[26]
K.S. Krabbe, M. Pedersen, H. Bruunsgaard.
Inflammatory mediators in the elderly.
Exp Gerontol, 39 (2004), pp. 687-699
[27]
L.E. Bautista, L.M. Vera, I.A. Arenas, et al.
Independent association between inflammatory markers (C-reactive protein, interleukin-6, and TNF-alpha) and essential hypertension.
J Hum Hypertens, 19 (2005), pp. 149-154
[28]
O.T. Ranzani, F.G. Zampieri, D.N. Forte, et al.
C-reactive protein/albumin ratio predicts 90-day mortality of septic patients.
[29]
M. Çağdaş, I. Rencüzoğullari, S. Karakoyun, et al.
Assessment of relationship between C-reactive protein to albumin ratio and coronary artery disease severity in patients with acute coronary syndrome.
[30]
J.F. Martin, J. Plumb, R.S. Kilbey, et al.
Changes in volume and density of platelets in myocardial infarction.
Br Med J (Clin Res Ed), 287 (1983), pp. 456-459
[31]
M. Balli, H. Taşolar, M. Çetin, et al.
Relationship of platelet indices with acute stent thrombosis in patients with acute coronary syndrome.
Postepy Kardiol Interwencyjnej, 11 (2015), pp. 224-229
[32]
T. Celik, M.G. Kaya, M. Akpek, et al.
Predictive value of admission platelet volume indices for in-hospital major adverse cardiovascular events in acute ST-segment elevation myocardial infarction.
Angiology, 66 (2015), pp. 155-162
[33]
M. Sundaresan, Z.X. Yu, V.J. Ferrans, et al.
Requirement for generation of H2O2 for platelet-derived growth factor signal transduction.
Science, 270 (1995), pp. 296-299
[34]
K.K. Griendling, G.A. FitzGerald.
Oxidative stress and cardiovascular injury: Part II: animal and human studies.
Circulation, 108 (2003), pp. 2034-2040
[35]
A.J. Murphy, J.P. Chin-Dusting, D. Sviridov, et al.
The anti-inflammatory effects of high density lipoproteins.
Curr Med Chem, 16 (2009), pp. 667-675
[36]
J.R. Hessler, A.L. Robertson Jr., G.M. Chisolm III.
LDL-induced cytotoxicity and its inhibition by HDL in human vascular smooth muscle and endothelial cells in culture.
Atherosclerosis, 32 (1979), pp. 213-229
[37]
X.P. Li, S.P. Zhao, X.Y. Zhang, et al.
Protective effect of high density lipoprotein on endothelium-dependent vasodilatation.
Int J Cardiol, 73 (2000), pp. 231-236
[38]
I. Matsumoto, Y. Miyake, M. Mizukawa, et al.
Impact of low-density lipoprotein cholesterol/high-density lipoprotein cholesterol ratio on long-term outcome in patients undergoing percutaneous coronary intervention.
Circ J, 75 (2011), pp. 905-910
[39]
R. Sukhija, W.S. Aronow, R. Sureddi, et al.
Predictors of in-stent restenosis and patient outcome after percutaneous coronary intervention in patients with diabetes mellitus.
Am J Cardiol, 100 (2007), pp. 777-780
[40]
O. Turak, U. Canpolat, F. Özcan, et al.
Usefulness of preprocedural serum uric acid level to predict restenosis of bare metal stents.
Am J Cardiol, 113 (2014), pp. 197-202
Copyright © 2019. Sociedade Portuguesa de Cardiologia
Download PDF
Idiomas
Revista Portuguesa de Cardiologia (English edition)
Article options
Tools
en pt

Are you a health professional able to prescribe or dispense drugs?

Você é um profissional de saúde habilitado a prescrever ou dispensar medicamentos

By checking that you are a health professional, you are stating that you are aware and accept that the Portuguese Journal of Cardiology (RPC) is the Data Controller that processes the personal information of users of its website, with its registered office at Campo Grande, n.º 28, 13.º, 1700-093 Lisbon, telephone 217 970 685 and 217 817 630, fax 217 931 095, and email revista@spc.pt. I declare for all purposes that the information provided herein is accurate and correct.