Abstract
Asthma action plans (AAPs) reduce healthcare utilisation, improve quality of life and are recommended across guidelines. However, fewer than 25% of patients receive an AAP, partly due to prescribers' inability to complete “yellow zone” instructions (how to intensify therapy for acute loss of control). We sought to review best evidence to develop a practical, evidence-based tool to facilitate yellow zone guidance in adults.
We reviewed recent asthma guidelines and adult studies addressing acute loss of asthma control (January 2010 to March 2016). We developed evidence-based rules for yellow zone therapy and operational guidelines to maximise adherence and minimise errors.
We reviewed three guidelines and 11 manuscripts (2486 abstracts screened). Recommendations were comparable but some areas lacked guidance. For 15/43 asthma regimens, the commonly recommended four- to five-fold yellow zone inhaled corticosteroid dose increase was problematic due to regulatory dose limits. We identified evidence-based alternatives for 8/15 regimens. Operational guidance included increasing to a maximum of four inhalations while maintaining baseline inhaler frequency and device in the yellow zone.
We developed a practical implementation tool to facilitate AAP delivery at the point of care, addressing existing gaps and uncertainties. Our tool should be implemented as part of a multifaceted approach to augment AAP usage.
Abstract
New tool brings complex evidence to the point-of-care, guiding providers on how to create the best #asthmaactionplan http://ow.ly/rmFu30a9neW
Introduction
Asthma is one of the most common chronic diseases in Europe, is increasing in prevalence, and is projected to carry a healthcare expenditure of more than €19 billion [1]. Although effective therapies exist, up to 53% of patients remain poorly controlled [2, 3].
An asthma action plan (AAP) is an individualised written plan produced by a healthcare professional for a patient with asthma, providing education and guidelines for self-management of worsening symptoms in a “traffic light” configuration [4]. A “green zone” describes adequate control and corresponding baseline medications, a “yellow zone” describes loss of control and corresponding instructions for therapeutic intensification, and a “red zone” indicates severe symptoms that should prompt immediate medical assistance [5]. A Cochrane review of 36 randomised controlled trials (RCTs) demonstrated that use of a written AAP in conjunction with education and regular clinical review significantly reduces healthcare utilisation, absenteeism and asthma symptoms, and improves quality of life [4]. Furthermore, AAP use has been associated with a 70% reduction in mortality [6]. In accordance with this strong evidence, international asthma guidelines recommend that all patients receive a written AAP [7–9].
Despite these data, AAP provision and use remains poor. In a study examining patients in the European Community Respiratory Health Survey II, only 30% of asthmatic patients who had used inhaled corticosteroid in the past year received a personalised AAP [10]. The principal barriers to AAP uptake are at the level of the provider and include lack of time, experience and confidence in creating appropriate AAP recommendations [11–13]. In one study, 30% of motivated physicians attending an asthma skills workshop were unable to prepare an adequate AAP [13]. Although recent asthma guidelines attempt to address this knowledge gap by providing evidence-based recommendations for changes to therapy in the yellow zone of the AAP, practical implementation remains complex and no implementation tools are widely available [7–9, 14].
We sought to develop a practical, evidence-based point-of-care guide for populating AAP yellow zone instructions in adult patients (age ≥18 years) with persistent asthma on regular maintenance therapy, with a goal of facilitating AAP delivery.
Methods
Evidence review
We used recommendations in international guidelines complemented by a literature search as the basis for our algorithm.
Guideline review
We searched major international asthma guidelines published in the last 5 years (prior to December 2016) for recommendations regarding AAP yellow zone formulation. We included guidelines produced by the Global Initiative for Asthma (GINA) [7], the British Thoracic Society/Scottish Intercollegiate Guideline Network (BTS/SIGN) [8] and the Canadian Thoracic Society (CTS) [9].
Literature review
The literature search in the oldest included guideline (CTS) was performed in October 2010. Accordingly, we searched for English-language studies involving human adult subjects, using asthma search terms as MeSH and keywords in Ovid MEDLINE, EMBASE and the Cochrane Central Registry of Controlled Trials from January 2010 to March 2016 (a complete list of search terms can be found in appendix 3). We included all RCTs, reviews and systematic reviews that described strategies for adjusting controller therapy for acute loss of asthma control in adults with persistent asthma on regular maintenance therapy. A. Kouri and S. Gupta reviewed all abstracts and categorised them as definitely, possibly or definitely not meeting inclusion criteria, and then reviewed full manuscripts for all abstracts definitely or possibly meeting inclusion criteria to determine whether they should be included. Any differences were settled by discussion, leading to consensus.
We examined all citations of interest from reference lists of retrieved articles and used a reference harvesting approach on all included papers, using Web of Science and Google Scholar, to identify any additional relevant publications.
We searched all included publications for guidance in areas where guideline recommendations were lacking or divergent and for new evidence.
Algorithm development
Based on this review, we established evidence-based rules for therapeutic intensification in the yellow zone. In cases where guideline recommendations and/or literature search findings diverged, we reviewed original studies cited by guideline writers to determine which approach was best supported. Next, we attempted to apply these rules to a catalogue of common controller medication dose and frequency regimens (for each commercially available medication). We documented regulatory limits on total daily doses for each medication according to international drug licensing agencies (appendix 2, table S1). In cases where yellow zone doses exceeded recommended daily limits across agencies, we searched guideline references and our search results and developed evidence-based alternative approaches where possible. Given that more than one medication type, dose and/or frequency could be used to operationalise yellow zone instructions, we developed practical rules to simplify and standardise prescriptions while maximising patient adherence and minimising patient errors. These rules were based on best evidence where available and on expert opinion where no evidence was available. Relevant expertise included asthma guideline development (A. Kaplan, L-P. Boulet), primary care practice (A. Kaplan) and guideline implementation (L-P. Boulet, S. Gupta).
Results
Evidence review
Guideline review
Included guidelines provided mostly comparable recommendations for self-management of acute loss of asthma control using an AAP (table 1).
Literature review
We identified 2486 abstracts between January 2010 and March 2016. Of these, 51 (2%) possibly met and 2435 (98%) did not meet inclusion criteria. Upon full manuscript review, 11 (22%) of 51 citations “possibly meeting inclusion criteria” met inclusion criteria. We did not identify any additional citations of interest from the manual search or from reference harvesting. The 11 included reports consisted of 1 RCT, 1 practice guideline, 3 narrative reviews and 6 systematic reviews. Upon detailed analysis, the RCT was not applicable to an outpatient AAP, as it tested the effects of a nebulised inhaled corticosteroid against systemic corticosteroids [15]. The practice guideline and 8 of the 9 reviews had either been directly cited in one or more of the guidelines we reviewed, or all individual studies included in the publication had been cited in one or more guidelines. Accordingly, where relevant, data from these studies had already been accounted for in our algorithm. However, the remaining review cited a relevant trial that had not been referenced in the included guidelines, comparing high-dose ciclesonide to prednisone for acute loss of asthma control. Although the dose used exceeded regulatory limits for total daily dosing, the study demonstrated both equivalence and safety and its findings were therefore incorporated into our algorithm [16]. See appendix 2 table S2, for full discussion of reviewed studies.
Algorithm development
For inhaled corticosteroid (ICS) monotherapy, the CTS and BTS/SIGN guidelines were consistent, recommending increasing the ICS dose by a factor of four to five (with strong levels of evidence; table 1) [8, 9]. The BTS/SIGN guideline limited its recommendation to patients on a low baseline ICS dose (200 µg beclomethasone diproprionate (BDP) equivalent). However, referenced studies included patients on moderate and high baseline ICS doses, suggesting that this practice should apply to various dose levels. We do note that a single trial demonstrated that immediate doubling of ICS dose in response to a drop in peak expiratory flow (PEF) can reduce asthma exacerbations [17]. However, this finding has not been replicated and most patients do not routinely monitor PEF. Although more evidence is required in this area, the balance of existing evidence favours increasing the ICS dose by four- to five-fold.
For non-ICS/formoterol combination therapy, CTS guidelines recommended taking a similar approach to that in patients on ICS alone (quadrupling the ICS component), whereas GINA guidelines recommended increasing the ICS component without specific dose guidance (except a maximum ICS dose of 2000 µg BDP equivalent). Both groups acknowledged a dearth of evidence in this area and made these recommendations based on consensus [7, 9]. We adopted the CTS approach, which provides a pragmatic rule for yellow zone dose intensification. In one exceptional circumstance, we recommended simply quadrupling the dose of a fluticasone furoate/vilanterol combination inhaler, as vilanterol doses of up to 100 µg have been shown to be safe for short courses of therapy [18, 19].
For ICS/formoterol therapy using the adjustable maintenance dosing (AMD) approach, GINA guidelines recommended quadrupling the maintenance ICS/formoterol dose (to a maximum of 72 µg·day−1 formoterol), whereas CTS guidelines recommended increasing the number of puffs to a maximum of 4 puffs twice daily (48 µg·day−1 formoterol) [7, 9]. These slightly divergent recommendations were based on a nearly identical set of studies (GINA guidelines cited a 2006 review by Reddel et al. [20], which included six trials, whereas CTS guidelines cited a 2007 review by Edwards et al. [21] which included the same six trials and an additional five trials) and assigned similarly high levels of evidence (table 1). However, all cited studies compared yellow zone dose intensification in patients on budesonide/formoterol–AMD to a higher baseline fixed dose of budesonide/formoterol. Accordingly, they concluded that yellow zone dose intensification is preferred to a higher baseline dose (with no change in the yellow zone), but did not answer the question as to which approach would be preferred in the yellow zone. A lack of available data to answer this specific question was noted by CTS guideline writers [9]. Practically, for typically recommended starting dose levels (budesonide/formoterol 100/6 µg or 200/6 µg 1 puff twice daily), GINA and CTS recommendations amounted to the same yellow zone change. Their recommendations diverge in patients on unconventional dose regimens (e.g. 100/6 µg 3 puffs twice daily or 200/6 µg 2 puffs twice daily). In these cases, following the CTS recommendation to increase to 4 puffs twice daily would equate to doubling (or less) the total ICS dose, which guidelines universally discourage. We therefore adopted the GINA guideline recommendation to quadruple the maintenance ICS/formoterol dose (table 2).
For ICS/formoterol therapy using the MART (maintenance and reliever therapy) approach, GINA and CTS guidelines recommended continuing this approach in the yellow zone, with a consistently high level of evidence [7, 9].
Guidelines were consistent in their recommendation that a short course of oral corticosteroids (OCS) should be considered as second-line therapy in the yellow zone when initial increases in inhaled therapy are not effective and/or if a clinical deterioration occurs (table 1) [7, 8]. We adopted specific criteria provided by all guidelines for such use of OCS (table 2). GINA and CTS guidelines also recommended considering OCS as first-line therapy in patients with certain high-risk features (table 1). Accordingly, we added these caveats to our yellow zone recommendation table (table 2). It should be noted that an AAP that includes conditional recommendations for ICS dose increases followed by addition of an OCS can be confusing to some patients. To address this, OCS recommendations could be operationalised by providing criteria for patients to contact their provider for an OCS prescription, while reserving a standing prescription with a conditional self-management plan only for patients with excellent self-management skills (table 2, footnotes). Also, although we have included the option to add OCS after failed initial ICS intensification as part of the yellow zone, some AAPs have operationalised this through an extra “orange zone” and others by including OCS in the “red zone” [22, 23]. This recommendation should thus be operationalised in accordance with the particular AAP format that the clinician is using.
Finally, certain patients were on baseline ICS doses that did not permit a four- to five-fold dose increase without exceeding regulatory limits for the total daily dose. In such patients on fluticasone, budesonide or ciclesonide, we were able to make evidence-based dose increase recommendations guided by specific studies demonstrating the safety and efficacy of dose increases (see section “Additional rules”). However, for other medications where such data are lacking, we offered two options: either temporarily exceeding regulatory limits by increasing the ICS dose four-fold, or going straight to a short course of OCS. Although we concede that having two options adds complexity, there are important considerations that lend support to each approach, leading to a conclusion that the therapeutic decision in this situation requires individualisation. Considerations favouring exceeding regulatory dose limits with ICS include that 1) regulatory limits on total daily ICS doses are intended for chronic use and not short-term use as part of step-up therapy in an AAP; 2) short-term use of doses exceeding regulatory limits has been shown to be safe in other medication preparations (ciclesonide in particular) [16]; and 3) one of the main goals of AAPs is to avoid a requirement for systemic steroids, which have several documented risks and side-effects. Considerations favouring going straight to a short course of OCS include that 1) pharmacists and patients often object to dispensing and consuming medications at doses that exceed product monograph specifications; 2) safety data for short-term higher dose usage are not available for these medications; and 3) many primary-care clinicians may not feel comfortable writing prescriptions that exceed regulatory dose limits, thus limiting the practical usability of such a recommendation in real-world care.
Additional rules
In cases where above rules could not be implemented due to maximum daily ICS dose limits (appendix 2, table S1), we developed additional evidence-based rules where applicable (table 2).
High-dose fluticasone
For patients on a baseline daily fluticasone dose greater than 500 µg (ICS alone or in a combination inhaler), a four- or five-fold dose increase would exceed the regulatory limit of a total daily dose of 2000 µg. However, two studies suggest that a four- to five-fold intensification might not be required in these patients. Levy et al. [24] and Di Franco et al. [25] compared fluticasone 2000 µg·day−1 (with or without a long-acting beta-agonist (LABA)) to a course of OCS in patients presenting to the emergency department with asthma exacerbation severe enough to warrant systemic steroids. Given a mean baseline dose of approximately 800 µg BDP-equivalent (equivalent to 800 µg fluticasone [9]), this represented an approximately 2.5-fold increase. Both trials found high-dose inhaled fluticasone to be non-inferior to OCS [24, 25]. Baseline doses were highly variable and did not predict treatment failure [24]. These data suggest that increasing the total daily fluticasone dose to 2000 µg·day−1 has a similar efficacy to a course of OCS, regardless of baseline ICS dose (see appendix 4 for further trial details). Given that patients who are self-managing through the yellow zone of an AAP would be expected to have less severe symptoms than patients seen in the emergency room, an increase to 2000 µg·day−1 of fluticasone could be a reasonable alternative to OCS in patients whose baseline fluticasone dose is greater than 500 µg·day−1. GINA guidelines also indicated that high-dose ICS has an equivalent effect to a short course of OCS (table 1).
Moderate- and high-dose budesonide
For patients on a baseline daily budesonide dose greater than 600 µg (ICS alone or in a combination inhaler), a four- or five-fold dose increase would exceed the regulatory limit on total daily dose of 2400 µg. However, trials by FitzGerald et al. [26] and Nana et al. [27] demonstrated non-inferiority between high-dose budesonide and OCS in patients discharged from the emergency room after an asthma exacerbation (see appendix 4 for further trial details). As above, these data suggest that increasing the total daily budesonide dose to 2400 µg·day−1 may have a similar efficacy to a course of OCS and presents a reasonable yellow zone option in patients with a baseline budesonide dose exceeding 600 µg·day−1.
High-dose ciclesonide
For patients on a baseline daily ciclesonide dose of greater than 200 µg, a four- or five-fold increase would exceed the regulatory total daily dose limit of 800 µg. However, a trial by Van den Berge et al. [16] found that in 130 patients with worsening asthma, a 2 week course of ciclesonide 800 µg twice daily was similar in efficacy to prednisolone 40 mg daily for improvement in FEV1, morning PEF and symptoms. Importantly, no serious adverse events occurred with this high dose of ciclesonide and there were fewer overall adverse events than with prednisolone. These data suggest that ciclesonide can be safely and effectively increased past its regulatory total daily dose limit, allowing for quadrupling in patients on high baseline doses.
It should also be noted that exact symptom- and peak expiratory flow-based criteria, as well as the timing for initiating an increase in controller medications (“activating the yellow zone”) during acute loss of asthma control were not specifically detailed in each guideline (table 1) and have been shown to be somewhat variable across existing AAPs [23, 28]. However, based on RCTs demonstrating the efficacy of a four- to five-fold increase in ICS dose [29, 30], we recommend that patients initiate yellow-zone therapy within 24–48 h of loss of control.
Practical implementation
We established basic principles for formulating yellow zone prescriptions. These principles aim to establish a consistent approach while maximising patient adherence and minimising patient errors, applying best evidence where available and expert opinion where evidence is lacking (table 3).
Finally, we applied our algorithm and practical guidelines to a collection of common controller medication types and regimens, creating a yellow zone dose escalation chart that can be printed and posted in the clinical environment for practical use (printable charts, by region, in appendix 1).
Discussion
We have used best evidence from the latest international asthma guidelines and an updated literature review to create a practical algorithm for populating asthma action plans. Recommendations for intensifying controller therapy during acute loss of asthma control were broadly similar across major international guidelines, with more variance in areas lacking evidence. Of interest, our guideline review revealed that different international groups ascribed noticeably different levels of evidence to similar recommendations (table 1). For example, for ICS monotherapy, BTS/SIGN guidelines recommended a five-fold dose increase as a level 1+ recommendation (corresponding to well-conducted meta-analyses, systematic reviews or RCTs with a low risk of bias), whereas CTS guidelines recommended a four- to five-fold increase as a level 2C recommendation (a weak recommendation with low-quality evidence). Our literature review did not find any significant new contributory studies published between the dates of the CTS and BTS guideline literature searches (appendix 2, table S2). Accordingly, variation probably resulted from differences in methodology, including evidence selection, synthesis, appraisal and recommendation formulation [37].
In attempting to apply guideline recommendations to develop a practical algorithm for use in a real-world clinical environment, we found several areas where recommendations were lacking or offered guidance that was difficult to operationalise. For example, for baseline regimens where intensification approaches were not supported by strong evidence (e.g. non-ICS/formoterol ICS/LABA medications), BTS/SIGN guidelines did not offer guidance (table 1). Additionally, even unanimously agreed-upon recommendations, such as increasing ICS doses by four- to five-fold, could not be universally applied due to regulatory limits on total daily doses. It would be infeasible to apply this recommendation in 15 of the 43 common dose regimens included in our practical chart (Appendix 1, Europe; our literature search identified alternative approaches for eight of these 15 cases). These factors support the commonly reported primary care perception that expert guidelines are too ambiguous [38] and rigid for application in individual patients [39, 40]. This poor “usability” is a consistently identified barrier to recommendation implementation [41, 42] and may be a factor in the observed low AAP usage rates in primary care [43].
Another important practical consideration is that recommended yellow zone doses could be achieved in various ways, including changes in the number and/or frequency of inhalations and/or through addition of a new inhaler or temporary replacement with a new inhaler. Despite this, guidelines did not specify how dose intensifications should be operationalised. A lack of any clear published guidance in this area probably also explains the large variability in yellow zone instructions across existing AAPs [23]. Given that both knowledge of available medication doses and formulations and time are major barriers to AAP usage in busy primary care environments, this uncertainty may also contribute to poor uptake [12, 13]. We attempted to address this by developing a series of practical implementation guidelines based on evidence and expert opinion. Our approach sought to minimise patient confusion and dosing errors while maximising patient satisfaction and adherence – notoriously difficult factors to elicit and to prioritise in guideline production [44]. This approach seeks not only to improve adherence to AAPs among patients, but also to address clinicians' concerns that patients may not effectively follow their AAPs, which in itself is a barrier to AAP delivery [45].
Our work has several limitations. As noted, our principal recommendations were based on major international guidelines, but our exception rules were based on small numbers of individual studies. It should be noted, however, that the evidence for AAP yellow zone formulation remains limited, and most guideline recommendations were also based on a small number of studies or expert consensus. Some of our practical rules for dose intensification regimens also relied on expert opinion and common sense, when evidence was lacking. Although we believe that this was necessary in order to produce a usable implementation tool, we recognise that more research is required to support our approaches in some of these areas. Our rules also do not provide guidance in patients with mild asthma who are not on regular controller therapy. Unfortunately, a literature review has found insufficient evidence to provide a recommendation for such patients [9]. We also appreciate that ensuring adherence to ICS is often challenging due to ICS aversion among patients [46] and that recommendations to further increase doses by four- to five-fold as part of an AAP will require patient education at the time of AAP delivery. Finally, we did not directly involve patients in developing these rules, which could have provided an important perspective.
We provide easy-to-follow, printable, paper-based algorithms that can be posted in a clinical setting, to inform completion of the AAP yellow zone (one each for Europe, Canada and the USA, in appendix 1). However, given that time is another major barrier to AAP delivery [3, 12, 47], integration of this algorithm into an electronic clinical decision support system would enable automated AAP generation, addressing both knowledge and time barriers to AAP delivery at the point of care. Accordingly, our team developed the Electronic Asthma Management System (eAMS), which features a patient questionnaire completed through a smartphone, tablet or PC interface in advance of the clinical visit, followed by real-time EMR (electronic medical record)-integrated advice for clinicians regarding asthma control status and corresponding medication adjustments, along with a pre-populated, personalised AAP (all content and recommendations can be altered by clinicians if required). A clinical trial of this system is currently under way.
In summary, we have developed a practical implementation tool to facilitate AAP delivery at the point of care, addressing the gaps and uncertainties in existing international guidelines. This tool addresses physician-level knowledge barriers as well as patient-level barriers surrounding adherence. However, other important barriers, including physician time and access to AAPs and patient aversion to steroid medications remain important determinants of AAP adherence. Our tool could be used as a paper reference guide or integrated into an electronic medical record system at the point of care. A future study should measure its impact on the frequency of AAP delivery, the quality of AAPs, patient uptake and patient-level outcomes. Future interventions should use our tool as part of a multifaceted approach to address the multiple known barriers to AAP usage.
Supplementary material
Supplementary Material
Please note: supplementary material is not edited by the Editorial Office, and is uploaded as it has been supplied by the author.
Appendix 1 ERJ-02238-2016_Appendix_1
Appendices 2, 3 and 4 ERJ-02238-2016_Appendices_2-4
Acknowledgements
We thank Len Fromer (Dept of Family Medicine, University of California at Los Angeles) and Kevin Gruffydd-Jones (University of Aberdeen) for support in developing the region-specific practical implementation tables. We also thank Suzanne Levitz, Robert Hauptman, David Cheah and Renu Bala Gupta for help piloting our tables for primary care physicians.
Footnotes
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Conflict of interest: None declared.
- Received November 13, 2016.
- Accepted February 17, 2017.
- Copyright ©ERS 2017
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