A clinical and economic evaluation of Control of Hyperglycaemia in Paediatric intensive care (CHiP): a randomised controlled trial
Health Technology Assessment, No. 18.26
Authors
Duncan Macrae,1,* Richard Grieve,2 Elizabeth Allen,3 Zia Sadique,2 Helen Betts,1 Kevin Morris,4 Vithayathil John Pappachan,5 Roger Parslow,6 Robert C Tasker,7 Paul Baines,8 Michael Broadhead,9 Mark L Duthie,10 Peter-Marc Fortune,11 David Inwald,12 Paddy McMaster,13 Mark J Peters,9 Margrid Schindler,14 Carla Guerriero,2 Deborah Piercy,3 Zdenek Slavik,1 Claire Snowdon,3 Laura Van Dyck,3 and Diana Elbourne3.Affiliations
Headline
This study found no differences in clinical effectiveness between tight glycaemic control and conventional management and no evidence to suggest that paediatric intensive care units should stop providing conventional management to children admitted following cardiac surgery. For those admitted for reasons other than cardiac surgery, tight glycaemic control reduced costs at 12 months and is likely to be cost-effective. Before tight glycaemic control can be recommended for this subgroup of patients, further research is required to determine how the risk of hypoglycaemia can be minimised and the long-term benefits of tight glycaemic control.
Abstract
Background:
Early research in adults admitted to intensive care suggested that tight control of blood glucose during acute illness can be associated with reductions in mortality, length of hospital stay and complications such as infection and renal failure. Prior to our study, it was unclear whether or not children could also benefit from tight control of blood glucose during critical illness.
Objectives:
This study aimed to determine if controlling blood glucose using insulin in paediatric intensive care units (PICUs) reduces mortality and morbidity and is cost-effective, whether or not admission follows cardiac surgery.
Design:
Randomised open two-arm parallel group superiority design with central randomisation with minimisation. Analysis was on an intention-to-treat basis. Following random allocation, care givers and outcome assessors were no longer blind to allocation.
Setting:
The setting was 13 English PICUs.
Participants:
Patients who met the following criteria were eligible for inclusion: ≥ 36 weeks corrected gestational age; ≤ 16 years; in the PICU following injury, following major surgery or with critical illness; anticipated treatment > 12 hours; arterial line; mechanical ventilation; and vasoactive drugs. Exclusion criteria were as follows: diabetes mellitus; inborn error of metabolism; treatment withdrawal considered; in the PICU > 5 consecutive days; and already in CHiP (Control of Hyperglycaemia in Paediatric intensive care).
Intervention:
The intervention was tight glycaemic control (TGC): insulin by intravenous infusion titrated to maintain blood glucose between 4.0 and 7.0 mmol/l.
Conventional management (CM):
This consisted of insulin by intravenous infusion only if blood glucose exceeded 12.0 mmol/l on two samples at least 30 minutes apart; insulin was stopped when blood glucose fell below 10.0 mmol/l.
Main outcome measures:
The primary outcome was the number of days alive and free from mechanical ventilation within 30 days of trial entry (VFD-30). The secondary outcomes comprised clinical and economic outcomes at 30 days and 12 months and lifetime cost-effectiveness, which included costs per quality-adjusted life-year.
Results:
CHiP recruited from May 2008 to September 2011. In total, 19,924 children were screened and 1369 eligible patients were randomised (TGC, 694; CM, 675), 60% of whom were in the cardiac surgery stratum. The randomised groups were comparable at trial entry. More children in the TGC than in the CM arm received insulin (66% vs. 16%). The mean VFD-30 was 23 [mean difference 0.36; 95% confidence interval (CI) –0.42 to 1.14]. The effect did not differ among prespecified subgroups. Hypoglycaemia occurred significantly more often in the TGC than in the CM arm (moderate, 12.5% vs. 3.1%; severe, 7.3% vs. 1.5%). Mean 30-day costs were similar between arms, but mean 12-month costs were lower in the TGC than in CM arm (incremental costs –£3620, 95% CI –£7743 to £502). For the non-cardiac surgery stratum, mean costs were lower in the TGC than in the CM arm (incremental cost –£9865, 95% CI –£18,558 to –£1172), but, in the cardiac surgery stratum, the costs were similar between the arms (incremental cost £133, 95% CI –£3568 to £3833). Lifetime incremental net benefits were positive overall (£3346, 95% CI –£11,203 to £17,894), but close to zero for the cardiac surgery stratum (–£919, 95% CI –£16,661 to £14,823). For the non-cardiac surgery stratum, the incremental net benefits were high (£11,322, 95% CI –£15,791 to £38,615). The probability that TGC is cost-effective is relatively high for the non-cardiac surgery stratum, but, for the cardiac surgery subgroup, the probability that TGC is cost-effective is around 0.5. Sensitivity analyses showed that the results were robust to a range of alternative assumptions.
Conclusions:
CHiP found no differences in the clinical or cost-effectiveness of TGC compared with CM overall, or for prespecified subgroups. A higher proportion of the TGC arm had hypoglycaemia. This study did not provide any evidence to suggest that PICUs should stop providing CM for children admitted to PICUs following cardiac surgery. For the subgroup not admitted for cardiac surgery, TGC reduced average costs at 12 months and is likely to be cost-effective. Further research is required to refine the TGC protocol to minimise the risk of hypoglycaemic episodes and assess the long-term health benefits of TGC.
Trial registration:
Current Controlled Trials ISRCTN61735247.
Funding:
This project was funded by the NIHR Health Technology Assessment programme and will be published in full in Health Technology Assessment; Vol. 18, No. 26. See the NIHR Journals Library website for further project information.
Article history
The research reported in this issue of the journal was funded by the HTA programme as project number 05/506/03. The contractual start date was in February 2007. The draft report began editorial review in May 2012 and was accepted for publication in April 2013. The authors have been wholly responsible for all data collection, analysis and interpretation, and for writing up their work. The HTA editors and publisher have tried to ensure the accuracy of the authors’ report and would like to thank the reviewers for their constructive comments on the draft document. However, they do not accept liability for damages or losses arising from material published in this report.
Declared competing interests of authors
All authors have completed the unified competing interest form at www.icmje.org/coi_disclosure.pdf (available on request from the corresponding author) and declare Medicines for Children Research Network funding (MD); involvement in the Health Technology Assessment programme SLEEPS (Safety profiLe Efficacy and Equivalence in Paediatric intensive care Sedation) trial and royalties for acting as an editor of handbook of PIC (KM); payment from Baxter for a single advisory meeting and from GlaxoSmithKline for pip contributions (MP); and a grant awarded from the neonatal and paediatric pharmacists group for an in vitro study of drug compatibility (JP).
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