Tight glycaemic control in acute exacerbations of COPD

Short abstract

A new standard of care?

It is now clear that hyperglycaemia of even short duration can be associated with adverse outcome in the acutely ill. Thus, the hyperglycaemic state has been associated with increased mortality in patients undergoing cardiothoracic surgery or suffering acute myocardial infarction, in victims of major trauma and those sustaining brain injury, and in association with community acquired pneumonia.¹,²,³,⁴,⁵ In this issue of Thorax Baker and colleagues extend this list, having performed a retrospective analysis of outcome in patients admitted to hospital with an acute exacerbation of chronic obstructive pulmonary disease (COPD).⁶ Multivariate analysis revealed that hyperglycaemia held more adverse prognostic significance even than spirometry. Not surprisingly, the authors propound the hypothesis that rigorous glycaemic control should improve mortality and/or reduce the length of hospital stay in this patient population which is so commonly encountered during the acute general medical take. To this end, they propose that a randomised trial of insulin therapy should be undertaken.

How robust are the data presented in this potentially important study? Although the authors are commendably open about the limitations of their study, these may be significant. Firstly, their (retrospective) identification of patients relied entirely on clinical coding, audits of which have suggested levels of accuracy as low as 60%.⁷ It is therefore unlikely that the study population was both complete and homogeneous. Indeed, the microbiological data presented suggest that a degree of overlap with patients suffering from community acquired pneumonia is possible, in whom hyperglycaemia is known to be associated with a poor outcome.⁵ Secondly, some measurements of blood glucose levels were made after hospital admission, during which the potentially significant confounding effects of therapeutic corticosteroids on glycaemic control were not quantified. Thirdly, single measurements of maximal blood glucose values were used in the analysis, which do not reflect the dynamic nature of levels encountered in acutely ill patients. Finney et al⁸ have shown that patients who spent the least time within the highest of several glycaemic bands (>8.0 mmol/l) were less likely to die than those who spent most time there. Detailed analysis of this kind is needed to facilitate precise quantification of dysfunctional glycaemic control. Finally, no data were presented that permit the assessment of severity of illness in this patient population, such as arterial pH. Not only does this remove the potential benefit of making comparisons with previously published work in patients with COPD,⁹ but it also renders impossible any attempt to establish whether hyperglycaemia was simply a reflection of illness severity and not therefore specific to this patient population.

Are the results obtained by Baker and colleagues rational and explicable in scientific terms? While a rigorous approach to glycaemic control has been shown to confer benefit following cardiothoracic surgery⁴ and in patients suffering acute myocardial infarction,¹⁰ it is possible that these results are due to the administration of exogenous insulin. Insulin is known to have both anti‐inflammatory¹¹ and anabolic properties,¹² and also promotes the utilisation of glucose as a metabolic fuel which generates more molecules of ATP per molecule of oxygen than free fatty acids with obvious potential benefits for ischaemic tissue. However, following cardiothoracic surgery the dose of insulin administered appears to be less significant in determining outcome than the quality of blood glucose (or surrogate variable) control.⁸,¹³ Moreover, glucose toxicity is suggested by post‐mortem studies of surgical patients in whom mitochondrial damage was limited to tissues characterised by the expression of glucose transporter (GLUT)‐1 and GLUT‐3, but not GLUT‐4.¹⁴ GLUT‐1 and GLUT‐3 are cell membrane transport proteins that allow equilibration of intracellular and extracellular glucose independently of insulin. Furthermore, hyperglycaemia causes many potentially damaging events such as the production of reactive oxygen species,¹⁵ glycosylation of proteins, impairment of leucocyte function, and activation of pro‐inflammatory genes through the transcription factors NF‐κB and AP‐1.¹¹ Alternatively, high plasma glucose levels may be a surrogate marker for deranged lipid metabolism. Insulin therapy appears to normalise lipid profiles with potentially beneficial consequences for membrane function and endotoxin scavenging.¹⁴ Finally, hyperglycaemia is associated with raised glucose levels both in tissues and bronchial aspirates, thereby potentially increasing the proliferation of pathogenic organisms,¹⁶ a positive finding of the present study. Since many of these theories are predicated upon the hypothesis that hyperglycaemia perpetuates inflammation either directly or through poor bacterial clearance/bacterial proliferation, quantification of the inflammatory response might provide a mechanistic insight in any subsequent study.

Should the results of this study change our clinical practice? The authors rightly emphasise that their investigation does not prove that administration of insulin is clinically beneficial. Furthermore, we could identify only one published interventional study that includes patients with respiratory failure. This historical, cohort based investigation found a reduction in mortality when insulin was administered to a mixed population of critically ill patients,¹⁷ only 12% of whom had a primary respiratory diagnosis. Many were mechanically ventilated. The insulin regimen applied was aimed at achieving blood glucose levels of <7.8 mmol/l, less rigorous than the targets of interventional studies performed in other populations.

Nevertheless, while there are limited data justifying tight glycaemic control in acutely ill medical patients, there are clearly no data or any scientific or clinical rationale to justify the maintenance of high blood glucose levels. On balance, it would appear that—based on only moderate evidence¹⁷—aiming for a blood glucose level of <8 mmol/l is reasonable in the acutely ill, even in those who are not known diabetics. Such uncertainty highlights the need for a trial of insulin therapy in patients with acute exacerbations of COPD, as Baker et al acknowledge. The logistic demands of tight glucose control should not, however, be underestimated. In a major randomised study of insulin therapy performed in the intensive care setting where staffing tends to be generous and monitoring apparatus readily available, blood sampling was recommended every 1–2 hours initially.⁴ Ward based patients may have even more variable glucose levels due to the intermittent nature of their caloric intake, in contrast to the continuous feeding that occurs commonly in critical care. The compounding effects of glucocorticoid treatment, frequently used in patients with COPD, have already been highlighted. Insulin infusions carry a risk of inadvertent hypoglycaemia which increases as blood glucose targets become more stringent. Indeed, in a major study of insulin therapy which aimed for blood glucose levels between 4.4 and 6.0 mmol/l, a 4.2% increase in the incidence of blood glucose levels of <2.2 mmol/l was identified, although these episodes apparently had no adverse sequelae.⁴ Finally, the implications for nursing workload are considerable; the development of computerised infusion control systems may help.

If the benefits of tight glycaemic control on mortality in patients with acute exacerbations of COPD are proved, the potential impact on the health care of patients with such a common disease is enormous. It will be revealing if the outcome is significantly influenced by what many would consider to be routine medical care that should be undertaken in all patients.