Connect
MJA
MJA

Cost-effectiveness of lowering blood pressure with a fixed combination of perindopril and indapamide in type 2 diabetes mellitus: an ADVANCE trial-based analysis

Paul P Glasziou, Philip M Clarke, Jan Alexander, Mohana Rajmokan, Elaine Beller, Mark Woodward, John Chalmers, Neil Poulter and Anushka A Patel
Med J Aust 2010; 193 (6): 320-324. || doi: 10.5694/j.1326-5377.2010.tb03941.x
Published online: 20 September 2010

Abstract

Objective: To determine the cost-effectiveness of routine administration, irrespective of blood pressure (BP), of a fixed-dose combination of perindopril and indapamide to patients with type 2 diabetes mellitus.

Design, setting and participants: Prospective cost-effectiveness analysis within the Action in Diabetes and Vascular Disease: Preterax and Diamicron-MR Controlled Evaluation (ADVANCE) trial, an international, multicentre, randomised controlled trial of 11 140 participants with type 2 diabetes randomly allocated to receive perindopril plus indapamide (4 mg–1.25 mg/day) or placebo.

Main outcome measures: Health-related quality-of-life measured by the EuroQol-5D, resource utilisation, and cost-effectiveness (cost per death averted at 4.3 years’ average follow-up, and estimated cost per life-year gained, by extrapolation).

Results: The mean health-related quality-of-life score of survivors was 0.80 (on a 0–1 scale [death to full health]), with no difference between treatment groups. Active treatment reduced hospital admissions for coronary heart disease and coronary revascularisation by 5%. For the Australian participants, perindopril–indapamide cost A$1368 per patient during the trial period, but reduced total hospitalisation costs by A$410 and other medication costs (mainly other BP-lowering drugs) by A$332. The absolute reduction in all-cause mortality for the active treatment group was 1.1%, giving a cost per life saved of A$49 200. Lifetime extrapolation gave an estimated cost per life-year saved of A$10 040 (discounted at 5% per year).

Conclusion: The combination of perindopril and indapamide in patients with type 2 diabetes appears to be cost-effective.

Trial registration: United States National Library of Medicine NCT00145925.

Reducing the vascular complications of type 2 diabetes mellitus is a global health priority; worldwide the number of people with diabetes is projected to rise from 171 million in 2000 to 366 million in 2030.1 Most people with diabetes will die from or be disabled by macrovascular and microvascular complications that can be reduced by blood pressure (BP)-lowering therapy.2 Traditional strategies have set BP thresholds and targets for treatment. While effective, these strategies are resource intensive, requiring multiple patient visits, careful monitoring of BP and side effects, and the management of complex drug regimens. Hence, few patients ever achieve recommended BP goals.3-5 This strategy also neglects patients with diabetes whose BP is not high enough for the arbitrary label of “hypertension”6 but is still a major determinant of their risk of vascular disease.7

A simpler approach in patients with diabetes may be routine BP-lowering therapy, additional to any current treatment and irrespective of initial BP. This is more inclusive and less resource intensive than the target-setting strategy. In testing this alternative strategy, the Action in Diabetes and Vascular Disease: Preterax and Diamicron-MR Controlled Evaluation (ADVANCE) trial recently demonstrated the benefits of a fixed-dose combination of an angiotensin-converting enzyme inhibitor, perindopril, and a diuretic, indapamide, versus placebo in preventing macrovascular and microvascular events in participants with type 2 diabetes, irrespective of their BP at inclusion.8 This approach was found to reduce cardiovascular mortality (relative risk reduction, 18%; P < 0.03) and all-cause mortality (relative risk reduction, 14%; P < 0.03).8 However, concerns have been raised about the expense if it is widely implemented.

We undertook a prospective cost-effectiveness analysis within the ADVANCE trial8-10 and report here on the health-related quality of life, resource utilisation, and cost-effectiveness of treatment with perindopril–indapamide compared with placebo.

Methods
Study design and population description

The ADVANCE trial was a 20-country, randomised controlled, 2 × 2 factorial trial involving 11 140 participants with type 2 diabetes. One arm of the study compared routine BP lowering based on a fixed-dose (4 mg–1.25 mg per day) perindopril–indapamide combination or matching placebo on top of whatever other hypertensive treatment was being used, if any.10 The study began in June 2001 and patient recruitment ended in March 2003; the BP-lowering treatment arm closed in June 2007. Data on mortality, morbidity, quality of life, and hospitalisation came from the main ADVANCE study. We also performed a substudy of the 978 Australian participants, which provided additional information on outpatient resource usage, including outpatient diagnostic investigations and procedures.

People with type 2 diabetes were eligible for the ADVANCE trial if they had been diagnosed at the age of 30 years or older, were aged 55 years or older on entry to the study, and had established vascular disease or at least one other major risk factor for cardiovascular diseases.8 There were no BP criteria for inclusion.

Outcomes and survival

All-cause mortality and cardiovascular mortality from the clinical trial have previously been reported.8 We calculated the survival time within the study for each treatment group from survival curves. Life expectancy of survivors beyond the close of the study was based on multistate life tables under the assumption of no continuing benefits from the within-trial treatment. These life tables were constructed from parametric survival models, and estimates were based on information about all ADVANCE participants who were alive 2 years after randomisation, including age, sex, smoking status, duration of diabetes and history of major cardiovascular disease.

Quality of life

To measure health-related quality of life, we administered the EuroQol-5D (EQ-5D) instrument11 to all participants from the 20 participating countries. For comparison, version 2 of the 36-item short-form health questionnaire (SF-36v2)12 was also used with the Australian subgroup of participants. Both questionnaires were administered at baseline, and at 2 years and 4 years after randomisation. A comparison of the baseline data13 found that the EQ-5D appeared to be as reliable and valid for measuring utility as the SF-36v2, hence the final analysis used the EQ-5D alone.

Resource usage

Hospitalisation data for participants from all 20 countries were included in an assessment of resource usage, and costs were based on diagnosis-related-group (DRG) categories using core grouping computer software (casemix expert release 2.3.1 AR [Australian revision]-DRG 5.1; 3M Australia, Sydney, NSW), together with information extracted from the National Hospital Cost Data Collection (NHCDC) in Australia.14

Of the 978 Australian participants, 948 (97%) consented to retrieval of Medicare claims data on medical services they received outside of hospital. Data on long-term (out-of-hospital) medications were collected as part of the main study, but information about dispensed medications and dosage were only collected for the Australian subgroup.

Unit costs

Unit costs of resources were allocated as suggested by the Australian Pharmaceutical Benefits Scheme manual of costs. The principal sources for establishing the unit costs of resources were:

  • for hospitalisations — DRG costs;14

  • for outpatient visits and outpatient diagnostic testing — the Australian Medicare Benefits Schedule; and

  • for the costs of medications — the Pharmaceutical Benefits Schedule.

All costs are reported in Australian dollars at 2007 values (Box 1).

Results

At baseline, characteristics of the 11 140 participants allocated to the two treatment groups were similar.8 About a third had a prior history of cardiovascular disease. Participants’ mean age was 66 years (SD, 6 years); mean number of years since diagnosis was 8 (SD, 6); 43% were women; 46% were from Europe, 37% from Asia, 9% from Australia, and 4% each from Canada and New Zealand. At the first (registration) visit, their mean BP was 145/81 mmHg. Forty-one per cent had a systolic BP less than 140 mmHg and diastolic BP less than 90 mmHg, and 25% were using no antihypertensive medication.

Mean follow-up was 4.3 years, during which allocated treatment was continued for 20 001 patient-years (83% of the time) in the active treatment group and 20 849 patient-years (87%) in the placebo group.

During the study, 879 participants died: 408 (7.3%) in the active treatment group and 471 (8.5%) in the placebo group (relative risk reduction, 14% [95% CI, 2%–25%]; P = 0.025). This overall mortality difference was primarily due to the reduction in cardiovascular deaths (Box 2) with active treatment (relative risk reduction, 18% [95% CI, 2%–32%]; P = 0.027).

Quality of life

Based on the EQ-5D,15 the mean quality-of-life utility assessment (on a scale from 0 [dead] to 1 [full health]) in survivors was 0.80, with a slight decline over time (from 0.82 at baseline), but with no statistically significant difference between the active treatment and placebo groups. Therefore, we did not adjust the life-years for quality-of-life differences in the economic analysis.

Hospital costs

The total in-trial average hospital costs per patient, by treatment group and based on Australian DRGs, for both the Australian substudy and all countries, are presented in Box 3. The overall difference in hospital costs between placebo and active treatment groups (placebo minus active) in all countries combined was just over A$1 million (about 4% of total hospital costs), with most of this arising from reductions in hospitalisations for cardiovascular episodes. Active treatment reduced hospital admissions for coronary heart disease and coronary revascularisation by 5%. There was a statistically significant reduction in cardiovascular events for participants in the active treatment group, with an average cost reduction of A$222 per patient. However, there were wide variations in hospital resource use by ADVANCE study participants in different regions of the world.16 In the Australian subgroup, the costs of hospitalisation were about double the average (Box 3), and the cost difference between treatment groups larger, at A$410 per patient (Box 2). This was somewhat higher than costings based on hospitalisation across all countries, mainly due to higher rates of hospitalisation in Australia.

Medication costs

At the end of follow-up, treatment adherence was 73% and 74% in the active and placebo treatment groups, respectively. Participants assigned to perindopril–indapamide used it for an average of 43.1 months (of 52 months’ average follow-up), resulting in a cost of A$1368 per patient when three assumed additional general practitioner visits for prescribing were included (Box 2). Significantly more additional BP-lowering agents were used by the placebo group, and some other cardiovascular agents were also used more in the placebo group (Box 4). The net difference in cost for drugs other than perindopril–indapamide was A$332 per patient (Box 2), representing a further 24% medication cost offset gained by active treatment.

Cost-effectiveness

For Australian participants, the average cost of the study therapy at A$1368 per patient was partly offset by lower average costs for other types of health care use: hospital costs were on average A$410 lower; outpatient visit costs A$72 lower; and other drug therapies were $332 lower (Box 2). The combined difference was A$814, which represents 60% of the in-study cost of perindopril–indapamide. At the trial close, the absolute difference in all-cause mortality was 1.1%, and the cost difference per patient treated was A$555. Hence the cost per death prevented was around A$49 200.

Predicted survival times for both treatment groups were substantially shorter than those for the general population of the same age. Within the period of follow-up, participants allocated to the perindopril–indapamide intervention lived a mean of 4.17 years (95% CI, 4.15–4.18 years) compared with 4.14 years (95% CI, 4.12–4.16 years) for the placebo group — an incremental gain in life expectancy of 0.03 years (95% CI, 0.00–0.05 years) (Box 6). Based on the observed within-trial treatment effects of perindopril–indapamide, the modelled mean life expectancy from the date of randomisation was 15.0 years (95% CI, 13.8–16.4 years) in the intervention group and 14.9 years (95% CI, 13.7–16.4 years) in the placebo group, a difference of 0.09 years (95% CI, 0.06–0.12 years), or 0.05 years (95% CI, 0.03–0.06 years) when discounted at 5%.

With no discounting, this is about A$8470 per life-year saved, and at a 5% discount rate, the incremental average cost in the perindopril–indapamide group was A$502 more per patient and the discounted benefits gained were 0.05 life-years, giving a cost-effectiveness ratio of A$10 040 per discounted life-year gained. Analysis of uncertainties showed there is a 30% chance the treatment is cost-neutral or cost-reducing (cost per quality-adjusted life-year [QALY] less than 0), and a 95% chance the cost per QALY is less than A$40 000. Applying the average EQ-5D utility score of 0.80 would mean the cost per QALY is around $10 600.

Discussion

Our cost-effectiveness analysis of data from the ADVANCE trial found that the cost offset attributable to the intervention was roughly two-thirds of the total costs of perindopril–indapamide dispensed during the trial. The resultant cost-effectiveness of A$49 200 per premature death prevented is within a range generally considered acceptable and is comparable to that of many other interventions. There was no difference in quality of life between groups, but applying the average quality-of-life score results in a cost per QALY of around $10 600.

These findings are comparable to previous studies of BP reduction in patients with diabetes and patients at high risk of cardiovascular events. For example, in the UK Prospective Diabetes Study, the estimated cost per QALY was £1049 (in 1998 pounds).17 For participants with stable coronary disease in the EUROPA trial, the estimated cost per QALY of perindopril alone was £9700.18 Similar relative risk reductions were found across different age, sex, and lipid profile groupings.17,18 Absolute risk, and hence cost-effectiveness, is therefore largely dependent on individual predicted risk.

Although we could make some approximation of cost-effectiveness in the UK and US from the ADVANCE trial data, differences in health care systems would require additional analyses to extend this analysis to other countries in more detail. The absolute benefit is unlikely to be substantially influenced by country-specific factors and, given a similar price for perindopril–indapamide in other countries, the cost offsets are unlikely to repay the medication costs. However, such country-specific variations are still likely to leave perindopril–indapamide in the cost-effective range.

If the monthly costs of medication were reduced to around $12, then this intervention would reduce net costs as well as being clinically important. However, as it is, from the Australian payer’s perspective, perindopril–indapamide is clearly cost-effective for patients with type 2 diabetes mellitus, independent of their BP level.

Received 26 January 2010, accepted 6 June 2010

  • Paul P Glasziou1
  • Philip M Clarke2
  • Jan Alexander3
  • Mohana Rajmokan4
  • Elaine Beller3
  • Mark Woodward2,5
  • John Chalmers2,5
  • Neil Poulter6
  • Anushka A Patel5

  • 1 Clinical Epidemiology and Biostatistics, Bond University, Gold Coast, QLD.
  • 2 University of Sydney, Sydney, NSW.
  • 3 Queensland Clinical Trials Centre, University of Queensland, Brisbane, QLD.
  • 4 Centre for Healthcare Related Infection Surveillance and Prevention, Queensland Health, Brisbane, QLD.
  • 5 The George Institute for International Health, Sydney, NSW.
  • 6 Imperial College London, London, UK.


Correspondence: pglaszio@bond.edu.au

Acknowledgements: 

We thank Peter Walker and 3M Australia for granting us use of their software for our analyses, the ADVANCE centres, and the ADVANCE trial patients. The ADVANCE trial is funded by grants from the National Health and Medical Research Council of Australia and Institut de Recherches Internationales Servier. Members of the ADVANCE Collaborative Group are fully listed in The Lancet.9 Neil Poulter received funding from the UK National Institute for Health Research Biomedical Research Centre funding scheme. The George Institute provided institutional grants for work on the substudy by Paul Glasziou, Philip Clarke, Janet Alexander, Mohana Rajmokan, and Elaine Beller. John Chalmers and Philip Clarke received institutional research grants from Servier.

Competing interests:

Paul Glasziou was reimbursed by the George Institute for travel to management committee meetings. John Chalmers is paid as a Board Member of the Servier International Diabetes Advisory Board. John Chalmers, Anushka Patel, Neil Poulter and Mark Woodward have received honoraria from Servier for speaking at scientific meetings. Mark Woodward has been paid by Roche as a member of the dal-PLAQUE steering committee and as a consultant by Servier, AstraZeneca and GlaxoSmithKline.

  • 1. Wild S, Roglic G, Green A, et al. Global prevalence of diabetes: estimates for the year 2000 and projections for 2030. Diabetes Care 2004; 27: 1047-1053.
  • 2. Turnbull F, Neal B, Pfeffer M, et al. Blood pressure-dependent and independent effects of agents that inhibit the renin-angiotensin system. J Hypertens 2007; 25: 951-958.
  • 3. Gu D, Reynolds K, Wu X, et al; InterASIA Collaborative Group. Prevalence, awareness, treatment, and control of hypertension in China. Hypertension 2002; 40: 920-927.
  • 4. Ong KL, Cheung BM, Man YB, et al. Prevalence, awareness, treatment, and control of hypertension among United States adults 1999-2004. Hypertension 2007; 49: 69-75.
  • 5. Patel R, Lawlor DA, Whincup P, et al. The detection, treatment and control of high blood pressure in older British adults: cross-sectional findings from the British Women’s Heart and Health Study and the British Regional Heart Study. J Hum Hypertens 2006; 20: 733-741.
  • 6. Baker S, Priest P, Jackson R. Using thresholds based on risk of cardiovascular disease to target treatment for hypertension: modelling events averted and number treated. BMJ 2000; 320: 680-685.
  • 7. Asia Pacific Cohort Studies Collaboration, Kengne AP, Patel A, Barzi F, et al. Systolic blood pressure, diabetes and the risk of cardiovascular diseases in the Asia-Pacific region. J Hypertens 2007; 25: 1205-1213.
  • 8. Patel A, MacMahon S, Chalmers J, et al: ADVANCE Collaborative Group. Effects of a fixed combination of perindopril and indapamide on macrovascular and microvascular outcomes in patients with type 2 diabetes mellitus (the ADVANCE trial): a randomised controlled trial. Lancet 2007; 370: 829-840.
  • 9. Rationale and design of the ADVANCE study: a randomised trial of blood pressure lowering and intensive glucose control in high-risk individuals with type 2 diabetes mellitus. Action in diabetes and vascular disease: preterax and diamicron modified-release controlled evaluation. J Hypertens Suppl 2001; 19: S21-28.
  • 10. Study rationale and design of ADVANCE: action in diabetes and vascular disease — preterax and diamicron MR controlled evaluation. Diabetologia 2001; 44: 1118-1120.
  • 11. Gudex C, Kind P. The QALY toolkit. (Discussion paper 38.) York: University of York, Centre for Health Economics, 1988.
  • 12. Ware JE, Kosinski M, Dewey J. How to score version two of the SF-36 health survey. Lincoln, RI: QualityMetric Incorporated, 2000.
  • 13. Glasziou P, Alexander J, Beller E, Clarke P. Which health-related quality of life score? A comparison of alternative utility measures in patients with type 2 diabetes in the ADVANCE trial. Health Qual Life Outcomes 2007; 5: 21.
  • 14. Department of Health and Ageing. National Hospital Cost Data Collection (NHCDC) reports. 2007. Round 11 cost weights, peer group report and hospital reference manual for 2006-07. Canberra: DoHA, 2008. http://www.health.gov.au/internet/main/publishing.nsf/Content/health-casemix-data-collections-NHCDCReports (accessed Dec 2007).
  • 15. Dolan P, Roberts J. Modelling valuations for Eq-5d health states: an alternative model using differences in valuations. Med Care 2002; 40: 442-446.
  • 16. Clarke PM, Glasziou P, Patel A, et al. Event rates, hospital utilization and costs associated with major complications of diabetes: multi-country comparative analysis. PLoS Med 2010; 7: e1000236. doi: 10.1371/journal.pmed.100 0236.
  • 17. Raikou M, Gray A, Briggs A, et al; UK Prospective Diabetes Study Group. Cost effectiveness analysis of improved blood pressure control in hypertensive patients with type 2 diabetes: UKPDS 40. BMJ 1998; 317: 720-726.
  • 18. Briggs A, Mihaylova B, Sculpher M, et al; EUROPA Trial investigators. Cost effectiveness of perindopril in reducing cardiovascular events in patients with stable coronary artery disease using data from the EUROPA study. Heart 2007; 93: 1081-1086.

Author

remove_circle_outline Delete Author
add_circle_outline Add Author

Comment
Do you have any competing interests to declare? *

I/we agree to assign copyright to the Medical Journal of Australia and agree to the Conditions of publication *
I/we agree to the Terms of use of the Medical Journal of Australia *
Email me when people comment on this article

Online responses are no longer available. Please refer to our instructions for authors page for more information.