4 Evidence and interpretation

The appraisal committee (appendix A) considered evidence from a number of sources (appendix B).

4.1 Clinical effectiveness

4.1.1

There is a large body of evidence for the use of ICSs in asthma, with studies of various methodologies reported in the literature as well as unpublished studies submitted by manufacturers. The study populations are often hospital based and the inclusion and exclusion criteria frequently make them unrepresentative of the general population of people with asthma. The participants have varying severities of asthma and degrees of symptom control. The drugs are used in different doses, delivered by various devices, and they are compared with other drugs, devices, doses or placebo. The trials are generally of a short duration (up to 1 year). A variety of outcomes are measured, including changes in lung function such as FEV and PEF, changes in asthma symptoms or the avoidance of exacerbations, and the use of short-acting bronchodilators or other medications. It is often unclear how these outcomes relate to quality of life.

4.1.2

The assessment group identified 5 questions relevant to this appraisal and conducted a systematic review in order to address them. The questions were as follows.

  • Which ICS is the most clinically effective at low doses, equivalent to beclometasone dipropionate at a dosage of 200 to 800 micrograms per day (step 2 of the BTS/SIGN guidelines)?

  • Which ICS is the most clinically effective at high doses, equivalent to beclometasone dipropionate at a dosage of 800 to 2,000 micrograms per day (step 4 of the BTS/SIGN guidelines)?

  • Which is the more clinically effective approach to introducing a LABA into a treatment regimen:

    • increasing the dose of the ICS alone or adding a LABA to ICS treatment, or

    • continuing with the ICS alone or adding a LABA to a similar dose of the ICS using a combination device (steps 2 to 3 of the BTS/SIGN guidelines)?

  • Which is the more clinically effective treatment:

    • fluticasone propionate/salmeterol in a combination device or the same drugs given in separate devices, or

    • budesonide/formoterol fumarate in a combination device or the same drugs given in separate devices?

  • Which is the more clinically effective treatment:

    • fluticasone propionate/salmeterol in a combination device, or

    • budesonide/formoterol fumarate in a combination device (step 3 of the BTS/SIGN guidelines)?

4.1.3

The systematic review included only randomised controlled trials (RCTs) that compared ICSs using the same inhaler device in each trial arm. A total of 22 RCTs compared ICSs at low doses. All ICSs were compared with fluticasone propionate and budesonide but there were no pairwise comparisons between beclometasone dipropionate, mometasone furoate and ciclesonide. There were fewer studies for mometasone furoate and ciclesonide (3 studies each) compared with the other drugs, which have been available for a longer period of time. The assessment group concluded that all the ICSs were associated with favourable changes from baseline to endpoint across efficacy outcomes. However, in pairwise comparisons, there were few statistically significant differences between the ICSs. The assessment group therefore concluded that it was reasonable to assume that there were no differences in clinical effectiveness between the different ICSs at low doses.

4.1.4

A total of 24 RCTs compared ICSs at high doses. Ciclesonide was compared only with fluticasone propionate; mometasone furoate was compared only with budesonide and fluticasone propionate. There were pairwise comparisons for all other drugs, with more evidence available for the older ICSs. For the comparison of 1 type of HFA-beclometasone dipropionate the equivalence ratio to HFA-fluticasone propionate was assumed to be 1:1 rather than 1:2. The assessment group concluded that all the ICSs were associated with favourable changes from baseline to endpoint across efficacy and safety outcomes. However, in pairwise comparisons, there were few statistically significant differences between the ICSs. The assessment group therefore concluded that it was also reasonable to assume that there were no differences in clinical effectiveness between the different ICSs at high doses.

4.1.5

Six RCTs compared combination devices containing a corticosteroid and a LABA with a device containing the same ICS alone at a higher dose. Four RCTs compared an ICS/LABA combination with a device containing a different ICS at a higher equivalent dose. Five studies compared the fluticasone propionate/salmeterol combination and 5 compared the budesonide/formoterol fumarate combination with a higher equivalent dose of ICS alone. There were no comparisons of the combination devices with beclometasone dipropionate, mometasone furoate or ciclesonide alone. Only trials in which the LABA and ICS were delivered in a single combination device were considered. The assessment group found that generally the addition of a LABA was statistically significantly superior to increasing the dose of ICS across a range of outcomes related to lung function, symptoms, rescue medication use and, to a lesser extent, asthma exacerbations.

4.1.6

Nine RCTs compared a combination device of an ICS and a LABA to the same dose of ICS alone. Six of these compared the fluticasone propionate/salmeterol combination with fluticasone propionate alone, and the remaining three were comparisons of the budesonide/formoterol fumarate combination with budesonide alone. The dose of ICS used in the studies varied. There were statistically significant improvements in lung function, asthma symptoms and rescue medication use favouring the combination treatment. The benefit in terms of frequency of exacerbation was not so marked, and there were no significant differences in adverse effects.

4.1.7

Six RCTs compared an ICS and LABA in a combination device with the 2 drugs delivered via separate devices. The 2 available combination devices (fluticasone propionate/salmeterol and budesonide/formoterol fumarate) were compared with their component drugs (3 and 2 studies, respectively). One study compared the fluticasone propionate/salmeterol combination device with budesonide and formoterol fumarate as individual components. No comparisons were made with any other ICS/LABA combination. Because many of these studies used a double-blind, double-dummy design (the patients taking a combination device also received a placebo dummy), they would not be expected to fully capture any benefits of improved treatment adherence with a combination device. There were very few statistically significant differences between the treatments across various efficacy outcomes, and for some outcomes (for example, lung function) non-inferiority was demonstrated. Meta-analysis revealed no statistically significant differences in adverse events.

4.1.8

Three RCTs compared the 2 available combination devices head to head in their dry powder form (DPIs) and all were in the low-to-medium range of the ICS dose. The outcomes in terms of lung function, asthma symptoms and exacerbations were mixed. Meta-analysis found no statistically significant differences in rates of adverse events.

4.1.9

Seven submissions were received from manufacturers. Four of these concentrated on the delivery device, which was either a DPI with improved characteristics or contained a non-CFC propellant with improved delivery properties. One submission concentrated on an ICS alone and 2 concentrated on the LABA/ICS combination in a single device. In general, the submissions focused on each manufacturer's products only and no systematic comparison of all available products was made.

4.1.10

In summary, the assessment group concluded that, when comparing the different ICSs, either at low or high doses, there was no difference between them in terms of effectiveness. It also concluded that adding a LABA is more effective than continuing on the same or an increased dose of ICS. When considering simultaneous treatment with a LABA and an ICS, the assessment group concluded that it was reasonable to assume that there was no significant difference in effectiveness when these were administered in a combination device as opposed to separate devices. The assessment group also concluded that comparisons of the 2 combination devices showed mixed results, with the fluticasone/salmeterol combination being statistically superior for some outcomes and the budesonide/formoterol combination being statistically superior for other outcomes.

4.2 Cost effectiveness

4.2.1

The assessment group conducted a systematic review of published economic evaluations of asthma and identified 15 studies. Four studies were analysed from the UK NHS perspective but only 1 calculated an incremental cost per quality-adjusted life year (QALY). This analysis produced incremental cost-effectiveness ratios (ICERs) of £4,800 to £18,300 per QALY gained for fluticasone propionate/salmeterol compared with fluticasone propionate alone at various dose levels. However, the analysis pooled effectiveness and resource-use data from patients in 44 countries and, for this reason, the assessment group concluded that the generalisability of these results to the UK setting may be limited.

4.2.2

Seven submissions were produced by 6 manufacturers (Altana, AstraZeneca, GlaxoSmithKline, IVAX, Meda and Trinity Cheisi). There was no submission from the manufacturer of mometasone furoate (Schering-Plough). All manufacturers produced a cost-minimisation analysis for the ICS products but none of the submissions compared all 5 available ICSs. Four submissions focused on either the device or the propellant associated with the ICS and 1 on the ICS itself. Two submissions produced a cost-effectiveness analysis for the combination devices from a product-specific perspective.

4.2.3

The assessment group addressed the economic evaluation of the five questions addressed in the effectiveness section (see section 4.1.2). Two of the questions relate to the comparison of ICSs as monotherapy at low and high doses, while 3 address the use of combination therapy (adding a LABA to ICS treatment compared with increasing the dose of ICS; treatment with separate devices compared with a combination device; and comparing the available combination devices). Where consistent evidence of differential clinical effectiveness was lacking, a cost-minimisation approach was used. If there was relatively consistent evidence showing differential effectiveness, a cost-consequence approach was adopted.

4.2.4

To generate a single cost figure for each ICS, a mean annual per-patient cost was calculated. This mean was presented as the average (unweighted) cost of a particular ICS, or the average cost weighted by usage based on the 2005 market share of different ICS preparations. As any particular target daily dosage can be achieved in a number of ways given the multiplicity of inhaler strengths available on the market, it was assumed that a dosage would be achieved in a fixed manner using higher strength inhalers to achieve higher total dosages. The BTS SIGN guideline assumptions on the equivalence of doses of different ICSs were applied (see section 3.2). In addition to the mean annual per-patient cost being calculated for all currently available products, it was also calculated with CFC-containing products excluded, because it is expected that these will soon be phased out. Because there are a limited number of combination device products, the mean cost was calculated for each product. In general, the DPIs are more expensive than other device types. The cheapest products are pMDIs that contain CFCs and, with their withdrawal, the overall cost of ICSs will increase. The average costs conceal a wide variation in the cost of individual preparations for each drug. While the most expensive devices for any ICS have similar costs there is a wide variation in cost among the cheapest available devices.

4.2.5

At the lower end of the low-dose range (400 micrograms beclometasone dipropionate equivalent per day), the cheapest ICS is beclometasone dipropionate with an average cost of £65 per year (mean cost including all available inhalers containing beclometasone dipropionate). When CFC‑containing products are excluded the cost increases, but beclometasone dipropionate remains the cheapest ICS on average (mean cost of £79 per year). Excluding CFC-containing products has no effect on the mean costs of fluticasone propionate, mometasone furoate or ciclesonide because these are available only as CFC-free products. At the upper end of the low-dose range (800 micrograms beclometasone dipropionate equivalent per day), beclometasone dipropionate is the cheapest product with a mean cost of £130 per year. When CFC-containing products are excluded, beclometasone dipropionate remains the cheapest drug according to the unweighted mean cost, but fluticasone propionate becomes the cheapest if a weighted mean is considered (that is an average calculated by weighting each product according to market share in terms of quantity of doses sold). The weighted and unweighted mean costs for each drug conceal variation in the costs of individual generic or branded inhalers and the cheapest product may not be a product containing the corticosteroid drug that was cheapest on average.

4.2.6

In the high-dose range (800 to 2,000 micrograms beclometasone dipropionate equivalent per day), only 4 ICSs were compared because ciclesonide is not licensed for use at an equivalent dose. The cheapest drug is beclometasone dipropionate with an average cost of £198 per year (unweighted mean of all available inhalers). When CFC-containing products are excluded, beclometasone dipropionate remains the cheapest drug according to the unweighted mean, but fluticasone propionate becomes the cheapest if a weighted mean is considered. The weighted and unweighted mean costs for each drug conceal variation in the costs of individual generic or branded inhalers and the cheapest product may not be a product containing the corticosteroid drug that was cheapest on average.

4.2.7

A cost-consequence analysis was conducted because the review of clinical effectiveness found that the ICS/LABA combination therapy was more effective than ICS monotherapy using an increased dose of ICS. The cost‑consequence comparison for the fluticasone propionate/salmeterol combination device was based solely on the device used in the relevant clinical trials (Accuhaler device) and not the least costly available device. At the low end of the dose range of ICS, the annual cost of the fluticasone propionate/salmeterol device is £92 more than fluticasone propionate alone at a higher dose. However, at the higher end of the dose range, the cost of the fluticasone propionate/salmeterol combination is £35 less than the ICS alone at a higher dose. When comparing the fluticasone propionate/salmeterol combination with budesonide alone at a higher dose, the combination treatment ranges from £94 cheaper to £109 more expensive depending on the budesonide preparation chosen. The budesonide/formoterol fumarate combination varies from being £163 cheaper to £66 more expensive than a higher dose of either fluticasone propionate or budesonide alone. No comparisons were made between the combination devices and other ICSs as monotherapy. The cost-consequence analysis above omits any potential cost savings that may result from avoidance of exacerbations as well as any potential quality of life gains associated with better asthma symptom control.

4.2.8

When the cost of taking a combination device is compared with taking the components separately, the combination product is almost always cheaper than taking the same drugs in separate devices. For the budesonide/formoterol fumarate combination, annual savings vary from £36 to £227 depending on the daily dose of ICS and the preparation of the LABA used. For the fluticasone propionate/salmeterol combination the annual savings vary from £39 to £185.

4.2.9

At the lower dose level (400 micrograms budesonide and 200 micrograms fluticasone propionate daily, given as regular twice-daily doses), the cheapest combination device is the fluticasone propionate/salmeterol aerosol pMDI, which costs £219 per year and is only £12 cheaper than the budesonide/formoterol fumarate DPI. The annual cost of low dose fluticasone propionate/salmeterol delivered by DPI (£379) is £148 more costly than budesonide/formoterol fumarate DPI (£231). At the higher dose level (800 micrograms budesonide and 500 micrograms fluticasone propionate), the fluticasone propionate/salmeterol DPI and pMDI are the cheapest at £446 per year, which is £16 cheaper than the budesonide/formoterol fumarate DPI.

4.3 Consideration of the evidence

4.3.1

The appraisal committee reviewed the data available on the clinical and cost effectiveness of ICSs, having considered evidence on the nature of the condition and the value placed on the benefits of ICSs by people with asthma, those who represent them, and clinical specialists. The committee also considered the NICE technology appraisal guidance on inhaler devices for routine treatment of chronic asthma in older children. The committee was also mindful of the BTS SIGN guidelines on the management of asthma, and of the need to take into account the effective use of NHS resources.

4.3.2

The committee considered the evidence on the clinical effectiveness of ICSs and their use within the context of the BTS/SIGN guidelines on the management of asthma. Clinical specialists were in agreement with the dose-equivalence estimates for the effectiveness of CFC preparations of ICS, as presented in the BTS/SIGN guidelines, but noted that the evidence base for determining the dose equivalence of mometasone furoate and ciclesonide relative to other ICSs was smaller. The specialists also stated that the Qvar brand of HFA-beclometasone dipropionate delivers smaller particles of ICS, which leads to improved lung deposition. Therefore, it may be given at lower doses than beclometasone dipropionate delivered using a CFC propellant to achieve an equivalent effect. The committee was also aware that CFC devices will be phased out in the near future in accordance with the Montreal Protocol.

4.3.3

The committee understood the importance of using an ICS in the context of a pathway of care that includes informing people about their condition, involving them in their asthma management using a personal action plan, training them in the effective use of the delivery device, and regular review of the effectiveness of their treatment.

4.3.4

The committee considered the different types of inhaler devices in children aged 5 to 15 years of age in line with NICE technology appraisal guidance on inhaler devices for routine treatment of chronic asthma in older children. The committee considered that this guidance remains appropriate, being based on an assessment of good-quality evidence regarding the effective deposition of ICSs in the lower respiratory tract. The specialists agreed that this guidance for young asthmatics also applies to the use of ICSs in adults and that, for ICSs, a pMDI and spacer device is usually considered in the first instance in routine clinical practice, especially when high doses of ICS are required and where patients have difficulty using a pMDI correctly. The committee heard from experts that spacers may not always be appropriate for adults, particularly when using low-dose pMDIs because local deposition and systemic absorption were likely to be good without a spacer. Patient experts also stated that some people do not use spacer devices because they consider them to be cumbersome. The committee accepted the approach recommended in NICE technology appraisal guidance 38 and concluded that although pMDI and a spacer where appropriate should be considered in the first instance, where there is evidence that a person is not able to use a pMDI and spacer effectively, or if this approach is not appropriate for the agent chosen, then alternative devices should be considered.

4.3.5

The committee first considered the RCT evidence on the clinical effectiveness of ICSs at doses equivalent to beclometasone dipropionate up to 800 micrograms per day. The committee heard from clinical specialists that the RCTs recruited a selected group of individuals with better compliance with treatment and inhaler technique than is generally seen in clinical practice. The committee heard from the specialists that, although there is little evidence of statistically significant differences in the clinical effectiveness of ICSs from the RCTs, in clinical practice some people respond to some agents/inhaler device systems better than others. They stated that at low doses of inhaled steroids (below the beclometasone dipropionate equivalent of 800 micrograms), few people experience local or systemic adverse effects. However, they added that in a small minority of people who experience local side effects (even at low doses) the use of pro-drugs, which are converted to an active form only once they reach the lungs (for example, ciclesonide), may be of use. The specialists agreed that, at low doses, there was a low risk of systemic adverse effects with ICSs. The committee concluded that there is little difference in the clinical effectiveness of different products when delivered appropriately at low doses.

4.3.6

The committee considered the RCT evidence on the clinical effectiveness of higher dose ICSs (doses equivalent to greater than 800 micrograms beclometasone dipropionate). Clinical specialists noted that higher doses of ICSs were associated with an increased risk of systemic adverse events, although the extent of this risk was poorly quantified and based on observational studies with conflicting results. The committee considered the possible effect of ICSs on growth in adolescents. The committee heard from clinical specialists that, in clinical practice, other factors such as choosing the most appropriate device were considered to be more important than the impact on growth, and therefore this was not seen to be an overriding factor in considering which product to use. The specialists agreed that people's treatment should be initiated and maintained on the lowest possible dose of ICS that controls their symptoms. They expressed concern that some people may be on inappropriately high doses of ICSs because treatment has been 'stepped up' during an exacerbation but not 'stepped down' when good control of asthma was achieved. The committee was aware that an individual's propensity for experiencing side effects at high doses of ICS was dependent on the pharmacokinetics of the ICS as well as the physical properties of the delivery system and other factors that determine lung deposition such as airway calibre. Based on the evidence from RCTs, the committee concluded that at equivalent doses there is little difference in the effectiveness or adverse-event profile of the different ICSs and also concluded that treatment with the lowest effective dose of ICS was most appropriate.

4.3.7

Two clinical specialists and 1 patient expert attended the appraisal committee meeting. They agreed with the conclusion of the assessment report that there are no consistent differences between the clinical effectiveness of the different ICSs or the different ICS/LABA combinations. They also emphasised the need for choice to individualise patients' treatment with a wide range of delivery devices. They provided insight into the importance of the type of device to adherence and overall clinical effectiveness of asthma treatment.

4.3.8

The committee considered evidence on the relative cost effectiveness of the different ICS products for the treatment of asthma. The committee was aware of the variation in the price of different manufacturer's products of the same ICS and the variation in price of the different types of inhaler devices. The committee concluded that, in light of the assumed equivalence of the clinical effectiveness of the different ICS products, the least costly product that can be used effectively by an individual should be chosen.

4.3.9

The committee considered the RCT evidence on the addition of a LABA to ICS treatment in people who are not adequately controlled on an ICS alone at step 3 of the BTS/SIGN guidelines. The committee noted from the evidence that the addition of a LABA to the current dose of ICS is more clinically effective than increasing the dose of ICS (in the absence of a LABA). The committee were in agreement with the BTS/SIGN guidelines on the introduction of LABA to people not adequately controlled on ICS alone (step 3) and therefore did not consider it necessary to make a separate recommendation concerning when a LABA should be added to ICS treatment. The committee was also aware that LABAs are licensed only for use in people with asthma who are already taking an ICS. It also noted that there were no consistent differences between the 2 combination devices currently available in terms of clinical effectiveness.

4.3.10

The committee considered that treatment with an ICS plus a LABA in a single combination device was at least as effective as using the same ingredients in separate devices. The committee heard from clinical specialists and patient experts that the use of a single combination device is associated with significantly improved adherence. The committee was aware that clinicians should take into consideration the individual's therapeutic need, including their ability to adjust the ICS dose in relation to the LABA, which is one of the benefits of using separate devices. However, the committee was also aware of the safety issues arising from prescribing 2 separate devices (for example, preferential use of the LABA and omission of ICSs) and that the budesonide/formoterol combination device could be used in flexible dosing regimens. In conclusion, the committee was persuaded that decisions should be made on an individual patient basis taking into account the therapeutic need, and that the use of a single combination device would normally be preferred to the use of 2 separate devices. However, the committee agreed that there might be circumstances when separate devices in fully compliant individuals could be equally clinically effective and equally or more cost effective.

4.3.11

The committee considered the evidence on the cost effectiveness of ICSs plus LABA treatment using a single combination device or separate devices. The committee noted that the use of a combination device (ICS plus LABA) can be cost saving compared with using separate devices. The committee also considered that, in people for whom ICS plus LABA treatment is appropriate, the least costly delivery method should be used, which is currently a combination device. The committee was aware that future changes in the availability and relative cost of generic ICSs, LABAs and combination products (ICS plus LABA in a single device) may alter the relative cost effectiveness of delivery using a combination device compared with separate devices so that, in the future, delivery via separate devices in fully compliant individuals may become the preferred option. However, based on the current availability and relative pricing of combination devices, the committee was persuaded that, at present, combination devices would be preferable. The committee also noted that using a single combination device decreased the prescription cost for the individual.