594528 research-article2015
TAK0010.1177/1753944715594528Therapeutic Advances in Cardiovascular Disease F Angeli, G Reboldi
Therapeutic Advances in Cardiovascular Disease
Hyperglycemia in acute coronary syndromes: from mechanisms to prognostic implications
Review
Ther Adv Cardiovasc Dis 2015, Vol. 9(6) 412–424 DOI: 10.1177/ 1753944715594528 © The Author(s), 2015. Reprints and permissions: http://www.sagepub.co.uk/ journalsPermissions.nav
Fabio Angeli, Gianpaolo Reboldi, Cristina Poltronieri, Ludovico Lazzari, Martina Sordi, Marta Garofoli, Claudia Bartolini and Paolo Verdecchia
Abstract: Hyperglycemia is a frequent condition in patients with acute coronary syndromes (ACS). Hyperglycemia during ACS is caused by an inflammatory and adrenergic response to ischemic stress, when catecholamines are released and glycogenolysis induced. Although the involved pathophysiological mechanisms have not yet been fully elucidated, it is believed that hyperglycemia is associated with an increase in free fat acids (which induce cardiac arrhythmias), insulin resistance, chemical inactivation of nitric oxide and the production of oxygen reactive species (with consequent microvascular and endothelial dysfunction), a prothrombotic state, and vascular inflammation. It is also related to myocardial metabolic disorders, leading to thrombosis, extension of the damaged area, reduced collateral circulation, and ischemic preconditioning. In the last few years, several observational studies demonstrated that hyperglycemia in ACS is a powerful predictor of survival, increasing the risk of immediate and long-term complications in patients both with and without previously known diabetes mellitus. Glucose management strategies in ACS may improve outcomes in patients with hyperglycemia, perhaps by reducing inflammatory and clotting mediators, by improving endothelial function and fibrinolysis and by reducing infarct size. Recent clinical trials of insulin in ACS have resulted in varying levels of benefit, but the clinical benefit of an aggressive treatment with insulin is yet unproved.
Keywords: acute coronary syndrome, glycemic control, hyperglycemia, myocardial infarction, prognosis
Introduction Numerous studies have shown that hyperglycemia is a commonly encountered issue in critically ill patients in the intensive care setting, even in patients without diabetes mellitus [Umpierrez et al. 2002; Finney et al. 2003; Bartnik et al. 2004; Jacobi et al. 2012; Viana et al. 2014]. A recent analysis of medical records showed that hyperglycemia was present in 38% of adult patients admitted to hospital, of whom 26% had a known history of diabetes, and 12% had no history of diabetes before the admission [Umpierrez et al. 2002]. In addition, patients with hyperglycemia had a longer length of hospital stay, a higher admission
rate to an intensive care unit, and were less likely to be discharged home, frequently requiring transfer to a transitional care unit or nursing home facility [Umpierrez et al. 2002]. Similarly, the Euro Heart Survey on diabetes and the heart analyzed the prevalence of abnormal glucose regulation in adult patients with coronary artery disease (CAD) [Bartnik et al. 2004]. The survey engaged 110 centers in 25 countries recruiting 4196 patients referred to a cardiologist due to CAD, of which 2107 were admitted on an acute basis and 2854 had an elective consultation [Bartnik et al. 2004]. In patients with acute CAD, 58% had impaired glucose regulation. In the stable group this proportion was 51% [Bartnik et al. 2004].
Correspondence to: Fabio Angeli, MD Division of Cardiology and Cardiovascular Pathophysiology, Hospital S.M. della Misericordia, Perugia, Italy
[email protected] Gianpaolo Reboldi, MD, PhD, MSc Department of Internal Medicine, University of Perugia, Perugia, Italy Cristina Poltronieri, MD Ludovico Lazzari, MD Martina Sordi, MD Department of Cardiology, University Hospital of Terni, Terni, Italy Marta Garofoli, MD Claudia Bartolini, MD Paolo Verdecchia, MD, FACC, FESH Department of Internal Medicine, Hospital of Assisi, Assisi, Italy
412 http://tac.sagepub.com
F Angeli, G Reboldi et al. The presence of hyperglycemia is also associated with increased morbidity and mortality, regardless of the reason for admission (e.g. acute myocardial infarction, surgery, stroke, sepsis) [Umpierrez et al. 2002; Finney et al. 2003; Bartnik et al. 2004; Jacobi et al. 2012; Viana et al. 2014]. In this context, the adverse prognostic impact of hyperglycemia at the time of acute coronary syndromes (ACS) has focused considerable attention from expert groups and professional societies [Capes et al. 2000; Deedwania et al. 2008; Inzucchi, 2008; Angeli et al. 2010]. It is now well established that glycometabolic status upon hospital admission is an important prognostic marker for all-cause death in patients with ACS, whether or not they had previously known diabetes mellitus [Deedwania et al. 2008; Angeli et al. 2010]. Although the association between hyperglycemia and increased mortality and in-hospital complications in patients with ACS has been confirmed in different studies [Capes et al. 2000; Angeli et al. 2010], the pathophysiology, the definition, and the treatment of hyperglycemia remain controversial [Deedwania et al. 2008; Inzucchi, 2008]. Epidemiology A certain amount of controversy still surrounds the cutoff value that should be used as a diagnostic marker of hyperglycemia in ACS. Further, it is not clear whether the glucose index value should be that taken on admission, after overnight fasting, or during an oral glucose tolerance test [Deedwania et al. 2008; Inzucchi, 2008]. Nevertheless, current classification of hyperglycemia in hospital includes diabetes diagnosed and treated before admission (known history of diabetes); existing, but unrecognized, diabetes (fasting glucose more than 6.9 mmol/liter or random glucose higher than 11.1 mmol/liter during hospital stay and confirmed after discharge; new-onset stress hyperglycemia or hospital-related hyperglycemia (fasting glucose more than 6.9 mmol/liter or random glucose higher than 11.1 mmol/liter during hospital stay that reverts to normal range after discharge) [Deedwania et al. 2008; Inzucchi, 2008]. Regardless of its classification, prevalence of hyperglycemia in different epidemiological studies (Table 1) ranges from 3% to 71% of patients admitted with ACS [Angeli et al. 2010, 2013].
As depicted in Figure 1, a number of contemporary investigators have shown a significant inverse relationship [r = –0.75; 95% confidence interval (CI) –0.88 to –0.49, p < 0.0001] between the threshold of blood glucose for defining hyperglycemia and its prevalence in patients with ACS [Angeli et al. 2010, 2013]. As expected, the lowest prevalence is observed with serum glucose levels of 9.4–17 mmol/liter (169–306 mg/dl) [Angeli et al. 2010], while lower thresholds for diagnosing hyperglycemia (6.1 mmol/liter; 108 mg/dl) are associated with the highest prevalence [Angeli et al. 2010, 2013]. Mechanisms Stress hyperglycemia is the result of sympathetic nervous system activation and the hypothalamic– pituitary axis with consequent raised production of catecholamines and cortisol that stimulate processes of glyconeogenesis, glycogenolysis, and lipolysis [McCowen et al. 2001; Huberlant and Preiser, 2010] (Figure 2). Although the mechanisms underlying the association between new hyperglycemia and mortality in patients with ACS are not fully understood, evidence that use of insulin to lower glucose concentrations at the time of ACS decreases mortality suggests that hyperglycemia is not simply an epiphenomenon of the stress response mediated by cortisol and noradrenaline [Huberlant and Presier, 2010; Senthinathan et al. 2011]. In particular, the higher risk of poor outcome in patients with hyperglycemia during ACS may reflect several potential underlying mechanisms (Figure 2). Acute or stress hyperglycemia has a facilitating role in the development of ACS and accentuates the consequences of cellular damage caused by acute myocardial ischemia [Ceriello, 2005]. It has been shown that hyperglycemia increases the release of inflammatory and vasoconstrictive factors which impair coronary endothelial function, contributes to the production of reactive oxygen species with consequent oxidative stress, and increases platelet aggregation [Ray et al. 2007; Worthley et al. 2007]. In addition, acute hyperglycemia produces a significant lengthening of the QT interval, reduces ischemic preconditioning and increases no-reflow and insulin resistance (impaired glucose utilization
http://tac.sagepub.com 413
Therapeutic Advances in Cardiovascular Disease 9(6) Table 1. Main clinical studies evaluating the prognostic significance of hyperglycemia in patients with acute coronary syndromes. Study
Setting
Threshold (mmol/liter)
Timing
Prevalence (%)
Ainla Ausburg Registry Bellodi CCP Gasior GRACE ICONS Ishihara JACCS Lewandowicz Nordin O’Sullivan Oswald Peturson Ravid Scott Sewdarsen Shen Soler Stranders Suleiman
ACS ACS ACS ACS in elderly ACS treated PCI ACS ACS ACS treated with PCI ACS treated with PCI ACS ACS treated with PCI ACS ACS ACS ACS ACS ACS ACS treated with PCI ACS ACS AMI
⩾11.1 >7.2 ⩾6.7 ⩾7.8 ⩾7.8 ⩾7.8 ⩾11.1 ⩾11.1 ⩾11.1 ⩾6.7 >7 ⩾8 ⩾8 >9.4 ⩾6.7 ⩾11.1 ⩾8 ⩾7.8 ⩾6.1 ⩾7.8 ⩾6.1
16.39 48.89 36.39 45.25 39.5 28.05 11.13 19.66 14.72 42.50 65.57 3.22 47.46 13.36 47.34 11.33 42.60 49.35 70.97 57.39 44.35
VALIANT Worcester HAS Zwolle
ACS (HR/LVSD) ACS ACS treated with PCI
>17 ⩾10
adm adm adm adm adm fasting > 12 h adm adm adm 24h adm after 8 h overnight adm (mean 9 h) adm within 72 h adm adm adm 24 h adm ⩾ 8 h fasting sample within 24 h adm/Rand (4, 9 days) adm adm
⩾11.1
5.13 17.7 11.80
ACS, acute coronary syndrome; adm, admission; CCP, Cooperative Cardiovascular Project; GRACE, Global Registry of Acute Coronary Events; HAS, Heart Attack Study; HR, high risk; ICONS, Improving Cardiovascular Outcomes in Nova Scotia; JACCS, Japanese Acute Coronary Syndrome Study; LVSD, left ventricular systolic dysfunction; PCI, percutaneous coronary intervention; Rand, randomization; VALIANT, VALsartan In Acute myocardial iNfarcTion. Data from the following references [Ravid et al. 1975; Lewandowicz et al. 1979; Soler and Frank, 1981; Oswald et al. 1986; Bellodi et al. 1989; Sewdarsen et al. 1989; O’Sullivan et al. 1991; Wahab et al. 2002; Aguilar et al. 2004; Stranders et al. 2004; Timmer et al. 2004; Ainla et al. 2005; Kosiborod et al. 2005; Kosuge et al. 2005; Nordin et al. 2005; Suleiman et al. 2005; Meisinger et al. 2006; Schiele et al. 2006; Shen et al. 2006; Goldberg et al. 2007; Ishihara et al. 2007; Petursson et al. 2007; Scott et al. 2007; Gasior et al. 2008].
which can potentially worsen ischemia through elevated oxygen consumption) [Oliver and Opie, 1994; Zarich, 2006; Bauters et al. 2007] (Figure 3). Moreover, the abnormal metabolic state that accompanies hyperglycemia alters the functional properties of multiple cell types, including platelets [Ferroni et al. 2004]. An altered platelet metabolism and changes in intraplatelet signaling pathways may contribute to the development of atherothrombotic complications. Hyperglycemia represents a causal factor for in vivo platelet activation, and is responsible for nonenzymatic glycation of platelet glycoproteins, causing changes in their structure and
conformation, as well as alterations of membrane lipid dynamics [Ferroni et al. 2004] (Figure 4). Furthermore, hyperglycemia-induced oxidative stress is responsible for enhanced peroxidation of arachidonic acid to form biologically active isoprostanes, which represents an important biochemical link between impaired glycemic control and persistent platelet activation [Ferroni et al. 2004]. Finally, increased oxidative stress is responsible for activation of transcription factors and expression of redox-sensitive genes leading to a phenotypic switch of endothelium toward an adhesive, prothrombotic condition, initial platelet activation, adhesion, and subsequent platelet aggregate formation [Ferroni et al. 2004].
414 http://tac.sagepub.com
F Angeli, G Reboldi et al.
Figure 1. Relationship with 95% confidence ellipse between threshold of blood glucose for defining hyperglycemia and its prevalence in contemporary studies recruiting patients with myocardial infarction. CCP, Cooperative Cardiovascular Project; GRACE, Global Registry of Acute Coronary Events; HAS, Heart Attack Study; ICONS, Improving Cardiovascular Outcomes in Nova Scotia; JACCS, Japanese Acute Coronary Syndrome Study; VALIANT, VALsartan In Acute myocardial iNfarcTion. See Table 1 for other details. Data from ref. [Ravid et al. 1975, Lewandowicz et al. 1979, Soler et al. 1981, Oswald et al. 1986, Bellodi et al. 1989, Sewdarsen et al. 1989, O’sullivan et al. 1991, Wahab et al. 2002, Aguilar et al. 2004, Stranders et al. 2004, Timmer et al. 2004, Ainla et al. 2005, Kosiborod et al. 2005, Kosuge et al. 2005, Nordin et al. 2005, Suleiman et al. 2005, Meisinger et al. 2006, Schiele et al. 2006, Shen et al. 2006, Goldberg et al. 2007, Ishihara et al. 2007, Petursson et al. 2007, Scott et al. 2007, Gasior et al. 2008].
Prognosis In recent years many studies have focused on the prognostic value of hyperglycemia in ACS, independent of whether the patients are known to have diabetes [Capes et al. 2000; Foo et al. 2003; Goyal et al. 2006]. In particular, hyperglycemia predicts mortality in patients with ACS, including ST-segment elevation myocardial infarction (STEMI), thrombolysis, and percutaneous coronary revascularization [Capes et al. 2000; Zeller et al. 2005; Pandey et al. 2009; Timmer et al. 2011; Eitel et al. 2012; Planer et al. 2013; Chen et al. 2014; Ekmekci et al. 2014; Lazzeri et al. 2014]. A recent analysis of the Cooperative Cardiovascular Project which included a large cohort of patients (n = 141,680) with ACS showed that depending on different levels of glucose on admission (⩽110, 110–140, 140–170, 170–240, and ⩾240 mg/dl), new hyperglycemia was associated with a significant 13–77% relative increase in short-term mortality and a 7–46% relative increase in 1-year
mortality [Kosiborod et al. 2005]. Notably, after multivariable adjustment for confounders (including age, sex, prior vascular events, hypertension, smoking status, Killip class, and atrial fibrillation) [Angeli et al. 2012a], patients with higher glucose levels at admission remained at increased risk of both 30-day and 1-year mortality compared with patients whose admission glucose was up to 110 mg/dl [Kosiborod et al. 2005]. In a study involving 2127 patients with ACS, Foo and coworkers stratified admission plasma glucose concentrations above 5.8 mmol/liter into quartiles, and reported a relationship between increasing glycemia and ventricular dysfunction, and in-hospital death [Foo et al. 2003]. The prognostic value of this variable was not affected by the known presence of diabetes at admission, and was similar in patients with ACS with and without ST segment elevation. Furthermore, Goyal and colleagues demonstrated that admission glucose and changes in glucose
http://tac.sagepub.com 415
Therapeutic Advances in Cardiovascular Disease 9(6)
Figure 2. Cardiovascular effects of hyperglycemia during the acute phase of myocardial infarction.
Hyperglycemia is associated with some circulatory and tissue effects, including oxidative stress and increased inflammation, hypercoagulability, reduced endothelial function, volume depletion, acid base disturbances, and altered immunity. FFA, free fatty acid.
Figure 3. Cardiac effects of hyperglycemia during the acute phase of myocardial infarction.
Multiple adverse effects are associated with acute hyperglycemia contributing to poor outcomes in acute coronary syndromes (ACS): promotion of inflammatory processes (including endothelial dysfunction, thrombosis, and platelet reactivity), metabolic derangements, increasing generation of free fatty acids and susceptibility to myocardial ischemia, and lower myocardial performance. Hyperglycemia is also a major predictor of left ventricular remodeling after ACS. FFA, free fatty acid; LV, left ventricular. 416 http://tac.sagepub.com
F Angeli, G Reboldi et al.
Figure 4. Impact of hyperglycemia on platelet function.
Hyperglycemia promotes changes in the structure and conformation of platelets, as well as alterations of membrane lipid dynamics. Increased oxidative stress associated with hyperglycemia is responsible for activation of transcription factors and expression of redox-sensitive genes leading to a phenotypic switch of endothelium toward an adhesive, prothrombotic condition, initial platelet activation, adhesion, and subsequent platelet aggregate formation. There is also evidence that the prothrombotic state generate by hyperglycemia originates from reduced plasma fibrinolytic activity and action of tissue plasminogen activator. GlyLD, glycated low-density lipoproteins; GP, glycoprotein; NO, nitric oxide; PKC, protein kinase C; ROS, reactive oxygen species.
level within the first 24 h predict the risk of mortality at 30 days in patients with ACS without a history of diabetes and that the risk of 30-day mortality decreased by 9% per 11 mg/dl reduction in glucose within the first 24 h after ACS [Goyal et al. 2006]. In the specific setting of patients with STEMI, elevated plasma glucose levels on admission confirmed to be independent prognosticators of both in-hospital and long-term outcome regardless of diabetic status [Malmberg et al. 1999; Chen et al. 2014]. For every 18 mg/dl increase in glucose level, there is a 4% increase in mortality in subjects without diabetes, and when admission glucose level exceeds 200 mg/dl, the risk of all-cause mortality is similar in patients with and without a history of diabetes [Stranders et al. 2004]. Nevertheless, in some reports fasting glucose the day after admission appeared to be a better predictor of early mortality than glucose level on
admission in patients with STEMI [Suleiman et al. 2005]. Patients with both an elevated admission glucose and an elevated fasting glucose the next day have a threefold increased risk of mortality. Similarly, failure of an elevated glucose level to fall within 24 h of admission is associated with excess mortality in patients with STEMI without diabetes mellitus [Goyal et al. 2006]. To further elucidate the significance of new hyperglycemia in ACS, we recently reviewed the literature on this topic and we performed a metaanalysis of observational studies [Angeli et al. 2010]. Overall, 24 clinical studies were included in the analysis (Figure 5). Patients with new hyperglycemia showed a 3.6-fold [odds ratio (OR) 3.62, 95% CI 3.09–4.24; p < 0.0001] increased risk of death during hospitalization compared with those who were normoglycemic [Angeli et al. 2010]. Similarly, new-onset hyperglycemia was associated with an increased risk of occurrence of death during a follow up of 30 days (OR 4.81, 95% CI 2.18–10.61; p < 0.0001) [Angeli et al. 2010]. Addressing long-term
http://tac.sagepub.com 417
Therapeutic Advances in Cardiovascular Disease 9(6)
Figure 5. Prognostic impact of new hyperglycemia on in-hospital (upper panel), 30-day (middle panel) and long-term mortality (lower panel) in patients with acute coronary syndromes. Odds ratios for individual studies are reported. Bars and diamonds denote the 95% confidence intervals (CI) for individual studies and pooled estimates, respectively. See Table 1 for other details. CCP, Cooperative Cardiovascular Project; GRACE, Global Registry of Acute Coronary Events; HAS, Heart Attack Study; ICONS, Improving Cardiovascular Outcomes in Nova Scotia; JACCS, Japanese Acute Coronary Syndrome Study; VALIANT, VALsartan In Acute myocardial iNfarcTion. Data from ref. [Angeli et al., 2010].
prognosis, new hyperglycemia was also associated with an excess risk of mortality (OR 2.02, 95% CI: 1.62 – 2.51, p < 0.0001) [Angeli et al. 2010]. Of note, trial level covariates (including timing of blood glucose determination, threshold glucose concentration used to define hyperglycemia, starting year of enrolment, and publication year) did not exert a statistically significant influence on estimates (all p > 0.05) of
in-hospital, 30-day and long-term mortality [Angeli et al. 2010]. In addition, admission hyperglycemia seems to predict mortality in patients with ACS, offering an incremental predictive value when added to risk prediction scores (including the Thrombolysis in Myocardial Infarction and the Global Registry of Acute Coronary Events (GRACE) scores) [Greig et al. 2010; Timoteo et al. 2014].
418 http://tac.sagepub.com
F Angeli, G Reboldi et al. In this context, a recent analysis of a single center registry of ACS (2099 patients, 69% men), evaluated the ability of two models (GRACE risk score alone and in combination with blood glucose) to predict death. The inclusion of admission blood glucose in the model with GRACE score increased the area under the receiver operating characteristic curve (p = 0.018) and was associated with an increase in both net reclassification improvement (37%) and integrated discrimination improvement (0.021) [Timoteo et al. 2014]. Therapeutic implications The substantial harm associated with hyperglycemia in patients with ACS suggests that glucose management strategies might improve outcome in patients with hyperglycemia [Angeli et al. 2010, 2013; Senthinathan et al. 2011].
the immediate 3-day post-ACS period. This initial increase in poor outcomes was likely mediated by the fact that GIK infusion frequently induced hyperglycemia and volume overload, which may have mitigated the beneficial effects of insulin in the regimen [Mehta et al. 2005]. Diabetes Mellitus Insulin-Glucose Infusion in Acute Myocardial Infarction (DIGAMI) [Malmberg, 1997, Malmberg et al. 1999] and DIGAMI-2 [Malmberg et al. 2005] examined the effect of glycemic control in patients with ACS with either a history of diabetes or admission glucose levels greater than 11 mmol/liter (198 mg/dl).
Clinical trials In the last few years, controlling hyperglycemia during ACS has been the target of a great deal of clinical research, with results primarily trending toward a benefit [Angeli et al. 2010, 2013].
The DIGAMI trial [Malmberg, 1997; Malmberg et al. 1999] evaluated the effect of intensive insulin treatment on mortality and morbidity in patients with diabetes and ACS. Insulin infusion was initiated as soon as possible after the onset of symptoms and continued for at least 24 h [Malmberg, 1997; Malmberg et al. 1999]. Patients were randomized to an intensive insulin treatment (insulin-glucose infusion followed by multidose subcutaneous insulin for ⩾3 months) or to a control group receiving conventional treatment at the discretion of the physician in charge [Malmberg, 1997; Malmberg et al. 1999]. Subjects assigned to more aggressive insulin therapy showed a significant reduction in mortality compared with the control group (estimate relative mortality reduction of 28%) [Malmberg, 1997; Malmberg et al. 1999].
In the Clinical Trial of Reviparin and Metabolic Modulation in Acute Myocardial Infarction Treatment Evaluation-Estudios Clinicos Latino America (CREATE-ECLA) study, which enrolled 20,000 patients, a glucose-insulin-potassium (GIK) regimen did not demonstrate improved outcomes in ACS [Mehta et al. 2005]. In this trial, high-dose GIK infusion was initiated immediately following randomization and continued for 24 h, and 40% of the total subjects became hyperglycemic (>144 mg/dl) in the postrandomization period; of these, the majority (62%) were in the GIK group [Mehta et al. 2005]. Subjects with a postrandomization glucose of more than 144 mg/dl had a 2.5-fold higher risk of mortality compared with subjects with a glucose level less than 126 mg/dl [Mehta et al. 2005]. While GIK was associated with a significant reduction in mortality and heart failure at 30 days after ACS, the overall effect was neutralized by an increase in mortality and heart failure with this regimen in
On the contrary, in the DIGAMI-2 trial [Malmberg et al. 2005] there were no differences in mortality rates at 2 years between patients who received insulin and those who received routine care. Specifically, this trial compared three different management strategies in patients with type 2 diabetes and acute myocardial infarction: a 24 h insulin–glucose infusion followed by a subcutaneous insulin-based long-term glucose control (group 1); a 24 h insulin–glucose infusion followed by standard glucose control (group 2); and routine metabolic management according to local practice (group 3) [Malmberg et al. 2005]. Overall, mortality was not significantly different among the three groups: the estimated mortality was 23.4% in group 1 and 21.2% in group 2 [hazard ratio (HR) 1.03; 95% CI 0.79–1.34; p = 0.832). In group 3, the observed mortality (17.9%) was lower compared with group 1 but this difference did not achieved significance (HR 1.26; 95% CI 0.92–1.72; p = 0.157). Comparing
Experimental studies suggested that treatment with insulin reduces inflammatory and clotting mediators in the plasma, improves endothelial function and fibrinolysis, and reduces infarct size in patients with ACS [Chaudhuri et al. 2004; Senthinathan et al. 2011; Wong et al. 2011].
http://tac.sagepub.com 419
Therapeutic Advances in Cardiovascular Disease 9(6) groups 2 and 3, the HR was 1.23 (95% CI 0.89– 1.69; p = 0.203) [Malmberg et al. 2005]. More recently, in the Hyperglycemia Intensive Insulin Infusion in Infarction Study (HI-5) [Cheung et al. 2006], 240 subjects with ACS and either known diabetes or without diabetes but blood glucose level at least 7.8 mmol/liter were randomized to receive insulin/dextrose infusion therapy for at least 24 h to maintain a glucose level less than 10 mmol/liter or conventional therapy. Insulin/dextrose infusion did not reduce mortality at the inpatient stage (4.8 versus 3.5%, p = 0.75), 3 months (7.1 versus 4.4%, p = 0.42), or 6 months (7.9 versus 6.1%, p = 0.62) [Cheung et al. 2006]. Although the varying glucose target levels in these trials make it difficult to compare their results and infer a conclusion, it is worth mentioning that in the DIGAMI-2 [Malmberg et al. 2005] and HI-5 trials [Cheung et al. 2006] blood glucose levels were not adequately lowered (the aggressive treatment groups achieved similar reductions in blood glucose compared with the control treatment groups). In addition, these trials were underpowered to show an effect on mortality and the infusions of insulin were started some hours after symptom onset, when it may have been too late to salvage the myocardium. In-hospital therapy Although recent large prospective studies of insulin in ACS have resulted in varying levels of benefit, the only acceptable treatment modality of hyperglycemia in the ACS setting is continuous intravenous regular insulin infusion, which should be initiated when blood glucose levels are greater than 10/11 mmol/liter (180/200 mg/dl) [Wilson et al. 2007; Houlden et al. 2013; Cheng et al. 2014]. Subcutaneous regimens with insulin and oral antihyperglycemic agents are not recommended because of the increased risk of hypoglycemia. While evidence favors a tighter control in the range of 6.1–7.8 mmol/liter (110–140 mg/dl) in surgical patients, a less aggressive target may suit patients with ACS (7.8–10.0 mmol/liter; 140–180 mg/dl) [Wilson et al. 2007; Houlden et al. 2013; Cheng et al. 2014]. There are many insulin infusion protocols available, but those protocols which contain orders that take into account both current blood glucose
values and rate of change of blood glucose are preferred [Goyal et al. 2008; Lipton et al. 2011]. Initial monitoring of blood glucose should be done on an hourly basis (interval of testing can be increased when two to three consecutive readings are consistently around the target) and insulin dose should be titrated according to blood glucose levels [Wilson et al. 2007; Houlden et al. 2013; Cheng et al. 2014]. Conclusion Hyperglycemia during ACS is a common finding and also an adverse prognostic marker that increases the risk of immediate and long-term complications in patients both with and without diabetes mellitus [Capes et al. 2000; Deedwania et al. 2008; Angeli et al. 2010, 2013]. In particular, new hyperglycemia during ACS portends an excess risk of mortality not only in the hospital setting, but also in the short term (30 days) and long term (up to 108 months) [Angeli et al. 2010]. Despite hyperglycemia as a factor of worse outcome is documented in several prospective studies, many gaps in knowledge currently exist in our understanding of the association between elevated glucose levels and adverse outcomes in patients with ACS [Deedwania et al. 2008; Jacobi et al. 2012; Angeli et al. 2013; Viana et al. 2014]. First, there is currently no consensus about the precise glucose value that should be considered abnormal (i.e. no minimum blood glucose concentration that could carry an increased risk of worse outcome has been clearly established) [Finney et al. 2003; Bartnik et al. 2004; Worthley et al. 2007; Jacobi et al. 2012]. Of note, the meta-analysis by Capes and coworkers has reported that patients without diabetes with ACS are at risk for in-hospital complications for blood glucose levels over 110 mg/dl, while patients with diabetes and ACS are at risk for inhospital complications for admission blood glucose concentrations equal to or over 180 mg/dl [Capes et al. 2000]. Second, there is no consensus about the most suitable method to initially measure and subsequently monitor blood glucose levels in the acute setting of ACS. Third, the benefits of treating hyperglycemia have not been established definitively, and the target
420 http://tac.sagepub.com
F Angeli, G Reboldi et al. value of blood glucose to be achieved with treatment remains undefined. The clinical benefits of an aggressive treatment with insulin are yet unproven [Senthinathan et al. 2011] and the potential role of concomitant drug therapies, including renin–angiotensin system blockers [Verdecchia and Angeli, 2003; Reboldi et al. 2009] and statins [Angeli et al. 2012b, 2012c], to ameliorate the detrimental effect of hyperglycemia need to be further evaluated.
statin therapy and mortality in patients with acute coronary syndrome. Acute Card Care 14: 34–39.
Thus, intervention trials are needed to optimize the definition of new hyperglycemia and to establish appropriate modalities and goals of glucoselowering treatment.
Angeli, F., Verdecchia, P., Karthikeyan, G., Mazzotta, G., Del Pinto, M., Repaci, S. et al. (2010) Newonset hyperglycemia and acute coronary syndrome: a systematic overview and meta-analysis. Curr Diabetes Rev 6: 102–110.
Acknowledgements The authors meet the criteria for authorship as recommended by the International Committee of Medical Journal Editors and were fully responsible for all content and editorial decisions, and were involved in all stages of manuscript development. The authors received no compensation related to the development of the manuscript.
Bartnik, M., Ryden, L., Ferrari, R., Malmberg, K., Pyorala, K., Simoons, M. et al. (2004) The prevalence of abnormal glucose regulation in patients with coronary artery disease across Europe. The Euro Heart Survey on Diabetes and the Heart. Eur Heart J 25: 1880–1890.
Conflict of interest statement The authors declare that there is no conflict of interest. Funding This research received no specific grant from any funding agency in the public, commercial, or notfor-profit sectors.
References Aguilar, D., Solomon, S., Kober, L., Rouleau, J., Skali, H., McMurray, J. et al. (2004) Newly diagnosed and previously known diabetes mellitus and 1-year outcomes of acute myocardial infarction: the Valsartan in Acute Myocardial Infarction (Valiant) trial. Circulation 110: 1572–1578. Ainla, T., Baburin, A., Teesalu, R. and Rahu, M. (2005) The association between hyperglycaemia on admission and 180-day mortality in acute myocardial infarction patients with and without diabetes. Diabet Med 22: 1321–1325. Angeli, F., Reboldi, G., Garofoli, M., Ramundo, E., Poltronieri, C., Mazzotta, G. et al. (2012a) Atrial fibrillation and mortality in patients with acute myocardial infarction: a systematic overview and meta-analysis. Curr Cardiol Rep 14: 601–610. Angeli, F., Reboldi, G., Garofoli, M., Ramundo, E. and Verdecchia, P. (2012b) Very early initiation of
Angeli, F., Reboldi, G., Mazzotta, G., Garofoli, M., Cerasa, M. and Verdecchia, P. (2012c) Statins in acute coronary syndrome: very early initiation and benefits. Ther Adv Cardiovasc Dis 6: 163–174. Angeli, F., Reboldi, G., Poltronieri, C. and Verdecchia, P. (2013) Hyperglycemia during acute coronary syndrome: prognostic implications. J Diabetes Metab 4: e111.
Bauters, C., Ennezat, P., Tricot, O., Lauwerier, B., Lallemant, R., Saadouni, H. et al. (2007) Stress hyperglycaemia is an independent predictor of left ventricular remodelling after first anterior myocardial infarction in non-diabetic patients. Eur Heart J 28: 546–552. Bellodi, G., Manicardi, V., Malavasi, V., Veneri, L., Bernini, G., Bossini, P. et al. (1989) Hyperglycemia and prognosis of acute myocardial infarction in patients without diabetes mellitus. Am J Cardiol 64: 885–888. Capes, S., Hunt, D., Malmberg, K. and Gerstein, H. (2000) Stress hyperglycaemia and increased risk of death after myocardial infarction in patients with and without diabetes: a systematic overview. Lancet 355: 773–778. Ceriello, A. (2005) Acute hyperglycaemia: a ‘new’ risk factor during myocardial infarction. Eur Heart J 26: 328–331. Chaudhuri, A., Janicke, D., Wilson, M., Tripathy, D., Garg, R., Bandyopadhyay, A. et al. (2004) Antiinflammatory and profibrinolytic effect of insulin in acute ST-segment-elevation myocardial infarction. Circulation 109: 849–854. Chen, P., Chua, S., Hung, H., Huang, C., Lin, C., Lai, S. et al. (2014) Admission hyperglycemia predicts poorer short- and long-term outcomes after primary percutaneous coronary intervention for ST-elevation myocardial infarction. J Diabetes Investig 5: 80–86. Cheng, A., Houlden, R. and Meltzer, S. (2014) In-hospital diabetes management. Can J Diabetes 38: 71–72.
http://tac.sagepub.com 421
Therapeutic Advances in Cardiovascular Disease 9(6) Cheung, N., Wong, V. and Mclean, M. (2006) The hyperglycemia: intensive insulin infusion in infarction (hi-5) study: a randomized controlled trial of insulin infusion therapy for myocardial infarction. Diabetes Care 29: 765–770. Deedwania, P., Kosiborod, M., Barrett, E., Ceriello, A., Isley, W., Mazzone, T. et al. (2008) Hyperglycemia and acute coronary syndrome: a scientific statement from the American Heart Association Diabetes Committee of the Council on Nutrition, Physical Activity, and Metabolism. Circulation 117: 1610–1619. Eitel, I., Hintze, S., De Waha, S., Fuernau, G., Lurz, P., Desch, S. et al. (2012) Prognostic impact of hyperglycemia in nondiabetic and diabetic patients with ST-elevation myocardial infarction: insights from contrast-enhanced magnetic resonance imaging. Circ Cardiovasc Imaging 5: 708–718. Ekmekci, A., Cicek, G., Uluganyan, M., Gungor, B., Osman, F., Ozcan, K. et al. (2014) Admission hyperglycemia predicts inhospital mortality and major adverse cardiac events after primary percutaneous coronary intervention in patients without diabetes mellitus. Angiology 65: 154–159. Ferroni, P., Basili, S., Falco, A. and Davi, G. (2004) Platelet activation in type 2 diabetes mellitus. J Thromb Haemost 2: 1282–1291. Finney, S., Zekveld, C., Elia, A. and Evans, T. (2003) Glucose control and mortality in critically ill patients. JAMA 290: 2041–2047. Foo, K., Cooper, J., Deaner, A., Knight, C., Suliman, A., Ranjadayalan, K. et al. (2003) A single serum glucose measurement predicts adverse outcomes across the whole range of acute coronary syndromes. Heart 89: 512–516. Gasior, M., Pres, D., Stasik-Pres, G., Lech, P., Gierlotka, M., Hawranek, M. et al. (2008) Effect of blood glucose levels on prognosis in acute myocardial infarction in patients with and without diabetes, undergoing percutaneous coronary intervention. Cardiol J 15: 422–430. Goldberg, R., Kramer, D., Lessard, D., Yarzebski, J. and Gore, J. (2007) Serum glucose levels and hospital outcomes in patients with acute myocardial infarction without prior diabetes: a community-wide perspective. Coron Artery Dis 18: 125–131. Goyal, A., Mahaffey, K., Garg, J., Nicolau, J., Hochman, J., Weaver, W. et al. (2006) Prognostic significance of the change in glucose level in the first 24 h after acute myocardial infarction: results from the CARDINAL study. Eur Heart J 27: 1289–1297. Goyal, A., Nerenberg, K., Gerstein, H., Umpierrez, G. and Wilson, P. (2008) Insulin therapy in acute coronary syndromes: an appraisal of completed and
ongoing randomised trials with important clinical end points. Diab Vasc Dis Res 5: 276–284. Greig, D., Corbalan, R., Castro, P., Campos, P., Lamich, R., Yovaniniz, P. et al. (2010) [Admission hyperglycemia and mortality of ST segment elevation myocardial infarction]. Rev Med Chil 138: 1109–1116. Houlden, R., Capes, S., Clement, M. and Miller, D. (2013) Canadian Diabetes Association Clinical Practice Guidelines Expert Committee. In-hospital management of diabetes. Can J Diabetes 37(Suppl. 1): S77–S81. Huberlant, V. and Preiser, J. (2010) Year in review 2009: critical care – metabolism. Crit Care 14: 238. Inzucchi, S. (2008) Hyperglycaemia and its therapy during acute coronary syndromes. Diab Vasc Dis Res 5: 259. Ishihara, M., Kagawa, E., Inoue, I., Kawagoe, T., Shimatani, Y., Kurisu, S. et al. (2007) Impact of admission hyperglycemia and diabetes mellitus on short- and long-term mortality after acute myocardial infarction in the coronary intervention era. Am J Cardiol 99: 1674–1679. Jacobi, J., Bircher, N., Krinsley, J., Agus, M., Braithwaite, S., Deutschman, C. et al. (2012) Guidelines for the use of an insulin infusion for the management of hyperglycemia in critically ill patients. Crit Care Med 40: 3251–3276. Kosiborod, M., Rathore, S., Inzucchi, S., Masoudi, F., Wang, Y., Havranek, E. et al. (2005) Admission glucose and mortality in elderly patients hospitalized with acute myocardial infarction: implications for patients with and without recognized diabetes. Circulation 111: 3078–3086. Kosuge, M., Kimura, K., Kojima, S., Sakamoto, T., Matsui, K., Ishihara, M. et al. (2005) Effects of glucose abnormalities on in-hospital outcome after coronary intervention for acute myocardial infarction. Circ J 69: 375–379. Lazzeri, C., Valente, S., Chiostri, M., Attana, P., Mattesini, A., Nesti, M. et al. (2014) Hyperglycemia, acute insulin resistance, and renal dysfunction in the early phase of ST-elevation myocardial infarction without previously known diabetes: impact on longterm prognosis. Heart Vessels 29: 769–775. Lewandowicz, J., Komorowski, J. and Gozlinski, H. (1979) Metabolic disorders in myocardial infarction. Changes in blood serum zinc, growth hormone, insulin and glucose concentration in patients with acute myocardial infarction. Cor Vasa 21: 305–316. Lipton, J., Can, A., Akoudad, S. and Simoons, M. (2011) The role of insulin therapy and glucose normalisation in patients with acute coronary syndrome. Neth Heart J 19: 79–84.
422 http://tac.sagepub.com
F Angeli, G Reboldi et al. Malmberg, K. (1997) Prospective randomised study of intensive insulin treatment on long term survival after acute myocardial infarction in patients with diabetes mellitus. DIGAMI (Diabetes Mellitus, Insulin Glucose Infusion in Acute Myocardial Infarction) Study Group. BMJ 314: 1512–1515. Malmberg, K., Norhammar, A., Wedel, H. and Ryden, L. (1999) Glycometabolic state at admission: important risk marker of mortality in conventionally treated patients with diabetes mellitus and acute myocardial infarction: long-term results from the Diabetes and Insulin-Glucose Infusion in Acute Myocardial Infarction (DIGAMI) study. Circulation 99: 2626–2632. Malmberg, K., Ryden, L., Wedel, H., Birkeland, K., Bootsma, A., Dickstein, K. et al. (2005) Intense metabolic control by means of insulin in patients with Diabetes Mellitus and Acute Myocardial Infarction (DIGAMI 2): effects on mortality and morbidity. Eur Heart J 26: 650–661. McCowen, K., Malhotra, A. and Bistrian, B. (2001) Stress-induced hyperglycemia. Crit Care Clin 17: 107–124. Mehta, S., Yusuf, S., Diaz, R., Zhu, J., Pais, P., Xavier, D. et al. (2005) Effect of glucose-insulinpotassium infusion on mortality in patients with acute ST-segment elevation myocardial infarction: the CREATE-ECLA randomized controlled trial. JAMA 293: 437–446. Meisinger, C., Hormann, A., Heier, M., Kuch, B. and Lowel, H. (2006) Admission blood glucose and adverse outcomes in non-diabetic patients with myocardial infarction in the reperfusion era. Int J Cardiol 113: 229–235. Nordin, C., Amiruddin, R., Rucker, L., Choi, J., Kohli, A. and Marantz, P. (2005) Diabetes and stress hyperglycemia associated with myocardial infarctions at an urban municipal hospital: prevalence and effect on mortality. Cardiol Rev 13: 223–230. Oliver, M. and Opie, L. (1994) Effects of glucose and fatty acids on myocardial ischaemia and arrhythmias. Lancet 343: 155–158. O’Sullivan, J., Conroy, R., Robinson, K., Hickey, N. and Mulcahy, R. (1991) In-hospital prognosis of patients with fasting hyperglycemia after first myocardial infarction. Diabetes Care 14: 758–760. Oswald, G., Smith, C., Betteridge, D. and Yudkin, J. (1986) Determinants and importance of stress hyperglycaemia in non-diabetic patients with myocardial infarction. Br Med J (Clin Res Ed) 293: 917–922. Pandey, S., Baral, N., Majhi, S., Acharya, P., Karki, P., Shrestha, S. et al. (2009) Prevalence of the metabolic syndrome in acute myocardial infarction
and its impact on hospital outcomes. Int J Diabetes Dev Ctries 29: 52–55. Petursson, P., Herlitz, J., Caidahl, K., Gudbjornsdottir, S., Karlsson, T., Perers, E. et al. (2007) Admission glycaemia and outcome after acute coronary syndrome. Int J Cardiol 116: 315–320. Planer, D., Witzenbichler, B., Guagliumi, G., Peruga, J., Brodie, B., Xu, K. et al. (2013) Impact of hyperglycemia in patients with ST-segment elevation myocardial infarction undergoing percutaneous coronary intervention: the HORIZONS-AMI trial. Int J Cardiol 167: 2572–2579. Ravid, M., Berkowicz, M. and Sohar, E. (1975) Hyperglycemia during acute myocardial infarction. A six-year follow-up study. JAMA 233: 807–809. Ray, K., Cannon, C., Morrow, D., Kirtane, A., Buros, J., Rifai, N. et al. (2007) Synergistic relationship between hyperglycaemia and inflammation with respect to clinical outcomes in non-ST-elevation acute coronary syndromes: analyses from OPUS-TIMI 16 and TACTICS-TIMI 18. Eur Heart J 28: 806–813. Reboldi, G., Gentile, G., Angeli, F. and Verdecchia, P. (2009) Choice of ACE inhibitor combinations in hypertensive patients with type 2 diabetes: update after recent clinical trials. Vasc Health Risk Manag 5: 411–427. Schiele, F., Descotes-Genon, V., Seronde, M., Blonde, M., Legalery, P., Meneveau, N. et al. (2006) Predictive value of admission hyperglycaemia on mortality in patients with acute myocardial infarction. Diabet Med 23: 1370–1376. Scott, A., Cheng, A., Greenacre, M. and Devlin, G. (2007) Implications of hyperglycaemia and ethnicity in patients with acute coronary syndromes in New Zealand. Diabetes Obes Metab 9: 121–126. Senthinathan, A., Kelly, V., Dzingina, M., Jones, D., Baker, M. and Longson, D. (2011) Hyperglycaemia in acute coronary syndromes: summary of NICE guidance. BMJ 343: d6646. Sewdarsen, M., Vythilingum, S., Jialal, I. and Becker, P. (1989) Prognostic importance of admission plasma glucose in diabetic and non-diabetic patients with acute myocardial infarction. Q J Med 71: 461–466. Shen, X., Jia, S. and Li, H. (2006) The influence of admission glucose on epicardial and microvascular flow after primary angioplasty. Chin Med J (Engl) 119: 95–102. Soler, N. and Frank, S. (1981) Value of glycosylated hemoglobin measurements after acute myocardial infarction. JAMA 246: 1690–1693. Stranders, I., Diamant, M., Van Gelder, R., Spruijt, H., Twisk, J., Heine, R. et al. (2004) Admission blood glucose level as risk indicator of death after myocardial
http://tac.sagepub.com 423
Therapeutic Advances in Cardiovascular Disease 9(6) infarction in patients with and without diabetes mellitus. Arch Intern Med 164: 982–988.
High Blood Pressure: the weapons are ready]. Rev Esp Cardiol 56: 843–847.
Suleiman, M., Hammerman, H., Boulos, M., Kapeliovich, M., Suleiman, A., Agmon, Y. et al. (2005) Fasting glucose is an important independent risk factor for 30-day mortality in patients with acute myocardial infarction: a prospective study. Circulation 111: 754–760.
Viana, M., Moraes, R., Fabbrin, A., Santos, M. and Gerchman, F. (2014) [Assessment and treatment of hyperglycemia in critically ill patients]. Rev Bras Ter Intensiva 26: 71–76.
Timmer, J., Hoekstra, M., Nijsten, M., Van Der Horst, I., Ottervanger, J., Slingerland, R. et al. (2011) Prognostic value of admission glycosylated hemoglobin and glucose in nondiabetic patients with ST-segment-elevation myocardial infarction treated with percutaneous coronary intervention. Circulation 124: 704–711. Timmer, J., Van Der Horst, I., Ottervanger, J., Henriques, J., Hoorntje, J., De Boer, M. et al. (2004) Prognostic value of admission glucose in non-diabetic patients with myocardial infarction. Am Heart J 148: 399–404. Timoteo, A., Papoila, A., Rio, P., Miranda, F., Ferreira, M. and Ferreira, R. (2014) Prognostic impact of admission blood glucose for all-cause mortality in patients with acute coronary syndromes: added value on top of GRACE risk score. Eur Heart J Acute Cardiovasc Care 3: 257–263. Umpierrez, G., Isaacs, S., Bazargan, N., You, X., Thaler, L. and Kitabchi, A. (2002) Hyperglycemia: an independent marker of in-hospital mortality in patients with undiagnosed diabetes. J Clin Endocrinol Metab 87: 978–982. Visit SAGE journals online http://tac.sagepub.com
SAGE journals
Verdecchia, P. and Angeli, F. (2003) [The Seventh Report of the Joint National Committee on the Prevention, Detection, Evaluation and Treatment of
Wahab, N., Cowden, E., Pearce, N., Gardner, M., Merry, H., Cox, J. et al. (2002) Is blood glucose an independent predictor of mortality in acute myocardial infarction in the thrombolytic era? J Am Coll Cardiol 40: 1748–1754. Wilson, M., Weinreb, J. and Hoo, G. (2007) Intensive insulin therapy in critical care: a review of 12 protocols. Diabetes Care 30: 1005–1011. Wong, V., Mardini, M., Cheung, N. and Mihailidou, A. (2011) High-dose insulin in experimental myocardial infarction in rabbits: protection against effects of hyperglycaemia. J Diabetes Complications 25: 122–128. Worthley, M., Holmes, A., Willoughby, S., Kucia, A., Heresztyn, T., Stewart, S. et al. (2007) The deleterious effects of hyperglycemia on platelet function in diabetic patients with acute coronary syndromes mediation by superoxide production, resolution with intensive insulin administration. J Am Coll Cardiol 49: 304–310. Zarich, S. (2006) Mechanism by which hyperglycemia plays a role in the setting of acute cardiovascular illness. Rev Cardiovasc Med 7(Suppl. 2): S35–S43. Zeller, M., Steg, P., Ravisy, J., Laurent, Y., JaninManificat, L., L’Huillier, I. et al. (2005) Prevalence and impact of metabolic syndrome on hospital outcomes in acute myocardial infarction. Arch Intern Med 165: 1192–1198.
424 http://tac.sagepub.com
