Chronic obstructive pulmonary disease

Home high-flow therapy during recovery from severe chronic obstructive pulmonary disease (COPD) exacerbation: a mixed-methods feasibility randomised control trial

Abstract

Introduction Patients recovering from severe acute exacerbations of chronic obstructive pulmonary disease (AECOPD) have a 30-day readmission rate of 20%. This study evaluated the feasibility of conducting a randomised controlled trial to evaluate clinical, patient-reported and physiological effects of home high-flow therapy (HFT) in addition to usual medical therapy, in eucapnic patients recovering from AECOPD to support the design of a phase 3 trial.

Methods A mixed-methods feasibility randomised controlled trial (quantitative primacy, concurrently embedded qualitative evaluation) (ISRCTN15949009) recruiting consecutive non-obese patients hospitalised with AECOPD not requiring acute non-invasive ventilation. Participants were randomised to receive usual care or usual care and home HFT (37°C, 30 L/min) with weekly home-based follow-up for 4 weeks to collect data on: device usage, breathlessness (modified Borg scale, visual analogue scale, Multidimensional Dyspnoea Profile), health-related quality of life (COPD Assessment Test (CAT), Clinical COPD Questionnaire), pulse oximetry, spirometry and inspiratory capacity, parasternal electromyography and actigraphy. Semistructured interviews were conducted in week 4. Trial progression criteria were: ≥40% of eligible patients randomised, ≤20% attrition, ≥70% complete data, and no device-related serious adverse events (SAE).

Results 18 of 45 eligible patients were randomised (age 69±5 years, 44% female, body mass index 23±5 kg/m2, forced expiratory volume in 1 second 32±12%). One withdrew following non-respiratory hospitalisation. Complete outcome measures were collected in >90% of home assessments. There were no device-related SAE. Daily HFT usage was 2.7±2.2 hours in week 1, falling to 2.3±1.4 hours by week 4. Temperature and flow settings were modified for comfort in 6 cases. Higher HFT usage was associated with lower symptom burden (CAT p=0.01). Interviews highlighted ease of device use, reduced salbutamol usage, and improved sputum production and clearance.

Conclusions The data from this feasibility study support the progression to a phase 3 randomised clinical trial investigating the effect of home (HFT) on admission-free survival in COPD patients recovering from a severe exacerbation.

Trial registration number The study received ethical approval (REC19/LO/0194) and was prospectively registered (ISRCTN15949009).

What is already known on this topic

  • High-flow therapy (HFT) delivers heated humidified gas (air with or without oxygen enrichment) to the airways. Preliminary data in clinically stable patients with COPD and chronic respiratory failure indicates possible clinical benefits including reduced exacerbation rates and breathlessness and improved gas exchange and exercise capacity. Patients hospitalised with severe COPD exacerbation even without comorbid respiratory failure are at high-risk of re-exacerbation and readmission despite pharmacological optimisation and pulmonary rehabilitation.

What this study adds

  • Home HFT is safe and acceptable to patients to patients recovering from severe COPD exacerbation, and it is feasible to conduct a phase 3 randomised clinical trial evaluating the effect of home HFT on admission-free survival.

How this study might affect research, practice or policy

  • This study informs the design of a UK phase 3 clinical trial to investigate whether home HFT is an effective adjunct to reduce readmission and mortality in patients recovering from severe COPD exacerbation.

Introduction

Acute exacerbations of chronic obstructive pulmonary disease (COPD) are a common cause of admission to hospital in the UK and worldwide. Up to 24% of patients recovering from severe COPD exacerbation are readmitted to hospital within thirty days of discharge.1 This proportion has remained static despite implementation of readmission prevention strategies, including changes in process of care as well as optimisation of medical management.2

In patients who are hospitalised with COPD exacerbation, without evidence of persistent hypercapnia during recovery, interventions to reduce risk of re-exacerbation and readmission are limited. Although inhaled bronchodilation and mucolytics have been shown to reduce exacerbation risk3 4 and emerging data indicate that type 2 inflammation inhibition can reduce moderate and severe exacerbation rates,5 these studies have targeted stable COPD patients. In hospitalised eucapnic COPD patients, evidence supports non-pharmacological interventions, such as pulmonary rehabilitation, to reduce 12-month readmission and mortality risk.6 However, shortfalls in access, uptake and programme completion have failed to change clinical outcomes.7 Other interventions, such as home non-invasive ventilation (NIV) with oxygen therapy in post-acute COPD patients with persistent hypercapnia and long-term oxygen therapy (LTOT) in stable hypoxaemic COPD patients, have been shown to increase admission-free survival8–11 and are part of clinical guidelines.12

Home high-flow therapy (HFT) delivers heated, humidified air or air-oxygen blend, and there is growing evidence of clinical and physiological effects in COPD patients following acute treatment with mechanical ventilation13–15 and stable patients with hypoxaemia and hypercapnia.16–18 Short-term physiological studies in COPD patients demonstrate that HFT reduces respiratory rate, respiratory drive and inspiratory effort, by changing breathing pattern and increasing expiratory time, and reduces breathlessness.19 20 These observations of the effect of HFT during acute exacerbation recovery, combined with a physiological home monitoring study which demonstrated early post-discharge improvements in airflow obstruction, neural respiratory drive and breathlessness,21 provide the rationale to use HFT in eucapnic COPD patients in the recovery phase at home. Additionally, despite clinical trials demonstrating reduced exacerbation frequency and symptom burden with home HFT and LTOT, there has been no demonstrable impact on hospital admissions and readmissions, providing further support for the rationale to target eucapnic normoxaemic post-acute COPD patients.

The aim of this study was to determine the feasibility of conducting a randomised clinical trial to evaluate clinical, patient-reported and physiological effects of home HFT, in addition to usual medical therapy, in eucapnic patients recovering from severe COPD exacerbation following hospitalisation.

Methods

This was a single-centre open label feasibility mixed-methods study comprising a parallel group randomised controlled trial (RCT) with embedded concurrent qualitative process evaluation reported using the feasibility trials Consolidated Standards of Reporting Trials statement and Consolidated criteria for Reporting Qualitative research checklist.22 23 The study received ethical approval (REC19/LO/0194) and was prospectively registered (ISRCTN15949009).

Consecutive patients presenting to the Accident and Emergency Department at a large urban university hospital in the UK who were hospitalised with physician-diagnosed COPD exacerbation were screened for eligibility. Inclusion criteria were: admission to hospital with an acute exacerbation of COPD, age 40–80 years, ≥10 pack year smoking history, body mass index ≤35 kg/m2, cognitively able to provide informed consent and adhere to the study protocol, and recruitment within 24-hours of admission. Patients with comorbidities likely to influence readmission risk (including severe heart failure, end stage renal failure, active malignancy), or those who were hypercapnic (arterial partial pressure of carbon dioxide (PaCO2) >7.0 kPa) during the index hospitalisation, required acute NIV or were established on domiciliary NIV, or continuous positive airway pressures were excluded.

Prior to discharge, patients were randomised 1:1 to receive usual medical care24 or usual medical care with home HFT (myAIRVO2, Fisher & Paykel Healthcare, NZ) with established readmission predictors as stratification factors: annual exacerbation frequency (≥2 or <2) and admission-to-discharge change in parasternal electromyography (EMGpara) (>3.1% or ≤3.1%).25 26 Randomisation with a concealed allocation sequence was implemented (Online Randomisation Service v1.5.2, King’s Clinical Trials Unit). Strata were generated for each combination of covariates with subjects assigned to the appropriate stratum and then block randomisation to assign patients to a treatment group. Intervention arm participants underwent a period of inpatient HFT acclimatisation and training prior to hospital discharge, with settings titrated to comfort, aiming for temperature of 37°C and flow of 30 L/min. Participants were informed that benefits have been observed with home HFT usage of 6 hours per 24-hour period.16 A defined device prescription was not provided in this feasibility trial as one aim was to explore usage patterns.

Quantitative data collection

Demographics, anthropometrics and clinical data (medical history, admission venous and arterial blood tests, chest radiograph findings, vital observations) were recorded at baseline inpatient assessments. The study team performed weekly home-based assessments for 4 weeks post-discharge to measure patient-reported and physiological outcomes and device usage. Health-related quality of life (HRQoL) and symptom burden were assessed using the COPD Assessment Test (CAT), Clinical COPD Questionnaire (CCQ) and Multidimensional Dyspnoea Profile.27–29 Physiological measures included vital observations, spirometry and inspiratory capacity (EasyOne Diagnostic Spirometer, ndd Medical Technologies, Switzerland), which were performed in accordance with international guidelines and reported methods.21 30 Neural respiratory drive was quantified using EMGpara, using previously reported methods to derive values for mean EMGpara, EMG normalised to maximal inspiratory manoeuvre (EMGpara%max) and EMG as product of respiratory rate (neural respiratory drive index, NRDI).21 Patients recorded breathlessness daily (modified Borg scale (mBorg); visual analogue scale (VAS)) on a paper symptom diary. Physical activity and sleep quality were measured with a triaxial accelerometer (Actiwatch Spectrum, Philips, USA), worn continuously on the non-dominant wrist for the study duration. HFT usage was obtained directly from devices.

Qualitative data collection

Embedded qualitative research, underpinned by the Theoretical Framework of Acceptability (TFA), was used to explore patients’ experiences of home HFT during COPD exacerbation recovery, including its acceptability and barriers and facilitators to its use.31 Purposive sampling of intervention arm participants to include patients with a range of characteristics (gender, ethnicity, living alone, smoking status) was conducted. One face-to-face semistructured interview was undertaken with an investigator trained in qualitative methodology (RFD). The topic guide was developed using data and expertise in experiences of NIV in COPD and was reviewed for face validity by another team member with expertise in qualitative research (LR).32 33 Interviews were conducted in patients’ homes to enable direct visualisation of the environment in which the device was used, thereby providing additional cues to factors influencing acceptability and to reduce interviewer-subject power imbalance.

To determine trial feasibility, a priori progression criteria were defined as: ≥40% of eligible patients consenting to randomisation and ≤20% attrition (based on our previous trial data comparing usual care with or without home non-invasive respiratory support in COPD patients recovering from severe exacerbation),8 ≥70% data collected for outcome measures to enable sample size calculation for the full-scale clinical trial, and no device-related SAE as a safety outcome for this novel application of a medical device.

Statistical analysis

A sample size of 80 patients was planned to estimate feasibility (recruitment of 40% eligible subjects, 70% completion of outcome measures) and clinical (anticipated 20% 30-day readmission) outcomes with a 95% CI of ±10%.34 Quantitative data are reported descriptively (mean±SD, median (IQR), number (%)), using an intention-to-treat principle. Correlation analyses were performed using Pearson or Spearman Rank correlation (SPSS, v28, IBM Corp, USA). Qualitative data were analysed using framework analysis, involving familiarisation of transcripts, coding using TFA constructs and matrix formation (NVivo, v12, QSR International, Australia).31 35 Quantitative and qualitative integration was used to provide illustration of the data in a real-world context, with convergent validation (assumption of improved validity if the quantitative and qualitative findings agree) and analytic density (a wider and deeper picture of the research from multiple perspectives).36 37 Integration was achieved using adapted triangulation and convergence coding, whereby the findings of each study were sorted into meta-themes based on the outcome measures. Meta-themes were mapped into a matrix containing convergence coding for agreement, partial agreement, dissonance or silence. A convergence assessment was used to quantify the level of agreement, and a completeness comparison defined differences in the contributions of the datasets to the overall evaluation.38

Patient and public involvement (PPI)

Patient members of the Lane Fox Clinical Respiratory Physiology Research PPI Group supported the design and conduct of this study. The patient information leaflet, trial protocol, study intervention, outcome measures and data collection techniques were approved by the group, who advocated the need for research into re-exacerbation and readmission prevention strategies in COPD.

Results

Recruitment was undertaken between June 2019 and March 2020 and terminated prematurely due to COVID-19 (figure 1). 263 patients were screened for trial participation with 34 patients (13%) fully meeting eligibility criteria. After consenting to participate and prior to randomisation, one patient was withdrawn due to the development of significant hypercapnia, and one patient withdrew following hospital self-discharge. Of 34 eligible patients, 18 were randomised. Participant characteristics are reported in table 1. All feasibility progression criteria were met: 18/34 (53%) were recruited and randomised, one (6%) withdrew after sustaining a pelvic fracture, ≥70% data were collected for each outcome measure (table 2) and there were no device-related SAEs.

Figure 1
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Participant flow diagram. BMI, body mass index; CPAP, continuous positive airways pressure; NIV, non-invasive ventilation; PaCO2, arterial partial pressure of carbon dioxide.

Table 1
Participant characteristics at baseline assessment
Table 2
Completion of home-based outcome measures

Regarding HFT settings on discharge following acclimatisation, all patients tolerated a temperature of 37°C, and 6/9 (67%) tolerated 30 L/min flow rate, with 3/9 (33%) accepting 25 L/min as the highest acceptable flow rate. Following hospital discharge, temperature was modified for two patients and flow titrated for four patients for comfort (figure 2). Home HFT usage per 24-hour period was 2.4±1.7 hours. Use was highest in week 1 post-discharge (2.7±2.2 hours), falling to 2.4±1.8 hours, 2.4±1.5 hours and 2.3±1.4 hours in weeks 2, 3 and 4, respectively (figure 3). No patients randomised to receive HFT required home oxygen and therefore oxygen entrainment for hypoxaemic respiratory failure.

Figure 2
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Home high-flow therapy settings during recovery from severe chronic obstructive pulmonary disease (COPD) exacerbation. (A, B) Temperature and flow settings, respectively, at setup and during follow-up.

Figure 3
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Home high-flow therapy usage in the 4 week postdischarge period following hospitalisation with severe COPD exacerbation. (A) A box plot depicting hours of device usage per 24-hour period for all subjects. (B) Individual usage per 24-hour period.

There were six episodes of re-exacerbation in the study period, occurring in five patients, of which five were community-treated (four control, one intervention) and one required hospital readmission (control group). There were two readmissions for non-COPD-related reasons (pelvic fracture and left heart failure). 90-day mortality was 17% (one intervention, two control). Patient-reported and physiological outcomes are reported in table 3. The data show trends towards reduced symptom burden and improved physiological parameters (spirometric, neural drive, respiratory rate) over the study period. A weak dose-response relationship was observed for duration of daily home HFT use and total symptom scores (CAT r2 0.20, p=0.01; CCQ r2 0.24, p=0.01), cough (CAT r2 0.26, p=0.002; CCQ r2 0.18, p=0.03) and breathlessness (mBorg r2 0.13, p=0.04). Actigraphy indices highlighted a trend to reduced immobile time in both arms during exacerbation recovery, with shorter sleep time and reduced sleep efficiency observed in participants using HFT.

Table 3
Patient reported and physiological outcomes during recovery from severe COPD exacerbation

Qualitative data are presented below under Theoretical Framework of Acceptability (TFA) constructs

Affective attitude

Consistent with their willingness to participate in the trial, all patients expressed enthusiasm to try the novel intervention. Several described overall satisfaction: ‘I’m very pleased with it’ (P1) and ‘I think it’s a really great invention’ (P9). The interface was reportedly comfortable: ‘The nose part fits comfortable’ (P17) and ‘It’s relaxing, when you’re just lying there and it’s tickling your nose’ (P8). The sensation of heat was variably described as a facilitator ‘It just warms you up, it just makes you feel nice and warm’ (P10) and barrier (‘I found it too much when the heat was high’ (P13), which resolved with settings modification. HFT was perceived as promoting confidence in undertaking physical activities: ‘It’s given me more confidence in doing more about the house’ (P3) and a safety net (‘I think it would be very helpful on bad days, especially in winter’ (P10) and ‘Something to fall back on’ (P9)) in the event of clinical deterioration. One participant was worried by the potential for technical difficulties (‘It worried me…Here by myself, I felt that if something happen, then I be alone’ (P7)). Limescale build-up was noted in the humidification chamber, rectified after remembering to adhere to recommendations of using cooled boiled water.

Burden

HFT imposed no cognitive burdens and was reported as ‘easy’ (P3, P7 P10, P13, P18) and ‘straightforward (P13, P17) to setup, use and maintain. No technical problems were encountered. Participants considered that the duration HFT could be worn may be limited by employment or adherence to additional medications and hospital appointments (‘On your working days you can’t and if you’re doing night work you can’t. I think it’s the amount of time you’ve got to spend on it every day which makes it a little bit awkward’ (P18), ‘I do like to do as many hours as I can, but you know there are other things you have to do, and plus all my pills I have to take and hospital appointments’ (P3)). The time taken for the device to heat to be ready to use was observed (‘It takes quite a while to heat up’ (P13)) but not described as a barrier: ‘It’s not as though I’m running a race, is it?…I don’t sit there and wait for it now. I just put it on, do a few other little things and then I think okay it’s ready now and then, you know, go’ (P3), ‘I switch my computer on and I let the dog out, I switch that on, I go and make my coffee, by the time I come back it’s ready to put on, so I’ve never timed it but it’s pretty quick’ (P17)).

Ethicality

The non-pharmacological nature of home HFT appealed: ‘I think why I used it so much and liked using it is because there’s no chemicals in it… I think that’s the main thing is that it hasn’t got any medication in it’ (P17) and ‘I think good idea because obviously it’s not chemical so the obvious thing which I mean it’s better for your lungs’ (P18). It also reminded one participant of steam inhalation home remedies: ‘My brother, he always says to me, stick your head over a bowl’ (P3).

Intervention coherence

The purpose of the device was clear to all participants: ‘I think it’s a good idea that machine to be quite honest…It makes a massive difference’ (P13), ‘The thing is, I think it’s doing me some good. I think it’s a really great invention’ (P9) and ‘It’s worth using as it feels good and makes you feel better’ (P10). Training was well received (‘The training I felt was spot on, it was very good…I didn’t have any problem using it after that’ (P3)). Having written information was felt to be beneficial (‘It’s difficult to remember everything, so it’s good have the leaflets so then you can always go back and look it up’ (P13). The warm-up time impeded the application of home HFT as an acute breathlessness relief tool, and it was thus viewed better suited as a maintenance therapy: ‘What I do is I use the shaker first and I put on the machine’ (P13).

Opportunity costs

Home HFT was uniformly incorporated into daytime routines, most commonly while watching television, sleeping, reading or working on the computer (‘I’ll sit there for a couple of hours when I’m watching my programmes on television because it doesn’t interfere with me at all’ (P3)). HFT was reportedly used at consistent times every day, with several patients specifying which hours they selected. Adherence to consistent times appeared to encourage regular use, meant that device usage did not impede on other day-to-day activities, and allowed patients to use it when they felt they would benefit most, for instance, following physical exertion: ‘So I go to the gym, do my exercises and whatever, and I’ll come back, then I’ll have a shower for myself. So, I’ll relax for half an hour, and I’ll use the machine’ (P13).

Perceived effectiveness

Home HFT was perceived as having demonstrable efficacy in improving symptoms, most notably sputum volume and clearance and also breathlessness. Patients noticed that after introduction of the device, their sputum was looser and easier to clear, lighter in colour and had reduced in volume: ‘I find now that I don’t get a quarter as much as I used to and I find it really has helped me in that respect, because it used to get stuck in my throat and it always made me feel sick. But since I’ve been using the device, it’s been a lot, lot better’ (P3), ‘I think it loosens it up and helps me bring it up quite easy’ (P9) and ‘Since I started using it, I wasn’t coughing up as much phlegm as I had been’ (P10). The impact of loosened secretions on cough was variable. Some patients observed that it increased cough, while others felt it was no different than following nebuliser use: ‘It obviously has that side effect of making you have to cough it all up afterwards…It loosens it off although you’ve got to keep blowing your nose at times’ (P17) and ‘I didn’t cough any more than I would cough using the nebuliser to be honest’ (P18). Home HFT influenced breathlessness in several patients, although feedback was less emphatic than for sputum production and clearance: ‘With the breathlessness, I’m not too sure. I think it did help’ (P10), ‘Well, it’s helped with my breathing I think, I think it’s helped with my breathing. I think that’s what it is’ (P9) and ‘Normally when I’m walking about for a little while, I’m trying to fight for my breath but although I do still, not half as much as I did so no, it’s been very beneficial’ (P3). Patients reported a reduction in use of as-required inhaled bronchodilation: ‘To be honest I haven’t been using (salbutamol) much at all…sometimes I’d use it maybe three or four times a day. But thinking about it now, that’s the first time I’ve used the blue inhaler since I saw you last week’ (P17) and ‘Obviously you don’t use your puffer so much’ (P18). Few patients observed a change in functional ability following introduction of home HFT: ‘I’d say that I can walk a bit further than I used to let’s put it that way, yeah’ (P6) and ‘I didn’t think (climbing stairs) was any different using that’ (P2).

Self-efficacy

Patients were confident and empowered to setup and use home HFT immediately following hospital discharge. One patient remarked that he found it difficult to decide whether to use his nebuliser or HFT. Another patient who lived alone, despite early enthusiasm, technical capability and high usage, described progressively deteriorating confidence in home HFT use. He ascribed this to the inability to rapidly access support in the event of clinical or technical difficulties, unlike in the hospital setting. Conversely, an older male who had close support from his daughter developed improved confidence and autonomy following hospital discharge: ‘I told myself well my daughter’s not going to be here all the time, so I’ve got to do things for myself and that’s what I did. Yeah, and then I wasn’t too sure, but I’ve fathomed it out. I’ve worked it out and it was easy, really’ (P9).

Quantitative and qualitative integration within a convergence coding matrix is presented in table 4.

Table 4
Convergence coding matrix integrating quantitative and qualitative datasets to determine the feasibility and acceptability of home high-flow therapy during severe COPD exacerbation recovery

Discussion

This is the first study to evaluate the feasibility of randomising eucapnic patients recovering from severe COPD exacerbation to home high-flow therapy prior to hospital discharge. All progression criteria were met, demonstrating that this trial design is feasible with acceptable recruitment proportions, satisfactory outcome data capture and no concerning device-related adverse effects. Furthermore, the quantitative and qualitative data support home HFT use during severe COPD exacerbation recovery as an acceptable intervention to patients.

Feasibility

The primary outcome of this study was protocol feasibility. Recruitment and randomisation was consistent with comparable RCTs of respiratory support devices in COPD.8 16 Attrition was low and related to non-respiratory acute events. Completion of outcome measures was high, with an expected lower ability to perform technically acceptable spirometry during a severe COPD exacerbation. Patient-reported benefits, notably sputum clearance and breathlessness, were identified using quantitative questionnaire and qualitative interviews. No device-related adverse events were reported, consistent with the reported safety profile of home HFT.16 17

High-flow therapy (HFT) setup and adherence

Device-related discomfort was reported by four patients at follow-up, with prompt resolution (within seconds to minutes) of actively titrating temperature or flow to comfort. This is consistent with the findings of Roca et al, who observed immediate resolution of discomfort following flow reduction in patients with acute respiratory failure.39 HFT usage per 24-hour period in this study was higher than patients with stable COPD or bronchiectasis evaluated by Rea et al (mean 1.6 hours/24-hour period) and comparable to bronchiectasis patients studied by Hasani et al (3 hours/day), in whom heated humidification conferred mucociliary clearance, time to first exacerbation and HRQoL benefits.40 41 Adherence was lower than in stable COPD patients with hypoxaemic respiratory failure studied by Storgaard et al (mean 6 hours/24-hour period) and stable COPD patients with or without hypoxaemia recruited within 3 months of hospitalisation with exacerbation evaluated by Criner et al (mean 6.8 hours/24-hour period).16 42 It is conceivable that the presented cohort, who were naïve to respiratory support therapies (including LTOT or NIV), were unaccustomed to sustained use of a novel medical device. This highlights the need for greater education and support to be provided as part of a phase 3 trial. Home HFT adherence reduced during COPD exacerbation recovery, indicating that patients perceived less benefits from using home HFT with symptom resolution. Consideration of flow and pressure titration to comfort should be given in a future trial.

Patient-reported outcomes

Sputum production and clearance were emphatically reported by patients at interview as the most important effect of home HFT use. Heated humidification to 37°C 100% relative humidity has been established in animal models to optimise respiratory epithelial function, including ciliary beat frequency and mucus transport velocity.43 This was applied in a clinical trial undertaken by Hasani et al who demonstrated enhanced clearance of respiratory secretions by patients with bronchiectasis following consistent daily HFT use.41 The qualitative findings of the current study are consistent with previous reports, in which stable hypoxaemic patients describe reduced sputum volume and tenacity with regular home HFT use.44 Sputum clearance should be evaluated in a future clinical trial; however, this study highlights important limitations of existing quantitative questionnaires used to do so. Alternative approaches could include a visual analogue scale or numerical rating scale for sputum clearance.45

While this study was not powered to detect clinical change, the impact of home HFT on respiratory symptoms and HRQoL in this dataset is similar to published reports from stable and acutely hypoxaemic COPD patients.16 46 Reduced short-acting beta-agonist usage was qualitatively reported and should be quantified in a future trial.

Chronic obstructive pulmonary disease (COPD) re-exacerbation and readmission

COPD re-exacerbation and hospital readmission rates in this study are consistent with national and international data.2 47 RCT data in patients with stable COPD and respiratory failure have demonstrated that application of home HFT is associated with reduced risk of exacerbation over 12 months. However, none of these studies have demonstrated an effect on hospital admission rate.16 17 Temporal clustering of COPD exacerbations has been described, with a high-risk period for recurrent exacerbations reported in the 2 months following the index exacerbation,48 with 15% of eucapnic patients readmitted within 14 days and up to 24% within 30 days1 26. Therefore, if an intervention can be demonstrated to interrupt this cycle, exacerbation frequency may improve, and long-term data are warranted.

Study limitations

This trial was truncated due to the onset of the COVID-19 pandemic which rendered recruitment unfeasible due study team redeployment and reduced AECOPD admissions.49 However, participant numbers were considered sufficient to determine the primary outcome of protocol feasibility, based on methodological guidance on sample sizes for feasibility trials.50 A strength of this study was application of mixed methodology. This facilitated identification of the most tangible benefit of home HFT for patients, which was sputum production and clearance. This observation was not captured in the quantitative questionnaires implemented. Furthermore, conducting home-based rather than hospital/laboratory based assessments, which carry significant patient burden,51 facilitated adequate recruitment, retention and data collection.

Conclusion

This mixed methods feasibility randomised controlled trial determined that it is feasible to conduct a Phase 3 clinical trial to investigate the effects of home high-flow therapy in eucapnic COPD patients recovering from a severe exacerbation, as evidenced by the recruitment and retention, data collection, device safety and acceptability. Home high-flow therapy applied in this context is safe and acceptable to patients and may confer symptomatic and physiological benefits. Quantifying sputum clearance and short-acting beta-agonist usage were identified as valuable outcome measures to be included in the phase three clinical trial. With feasibility demonstrated, an RCT to investigate whether home HFT, in addition to standard care, increases 12-month admission-free survival following severe COPD exacerbation is currently recruiting (ISRCTN89405844).

Take home message

It is feasible to conduct a clinical trial to evaluate whether home high-flow therapy (HFT) can reduce re-exacerbations and readmissions during severe COPD exacerbation recovery. Home HFT is safe and may improve sputum clearance and reduce salbutamol use.

  • X: @rebdcruz

  • Contributors: RFD contributed to study design, undertook data acquisition and analyses, and led report writing. AR contributed to data collection and supported report writing. GK and ESS supported with report writing. AD provided statistical guidance, LR, PBM and NH contributed to study design and report writing. NH is the guarantor.

  • Funding: National Institute for Health Research Doctoral Research Fellowship, awarded to Dr Rebecca D’Cruz, reference DRF-2018-11-ST2-037.

  • Competing interests: None declared.

  • Patient and public involvement: Patients and/or the public were involved in the design, conduct, reporting or dissemination plans of this research. Refer to the Methods section for further details.

  • Provenance and peer review: Not commissioned; externally peer reviewed.

Data availability statement

All data relevant to the study are included in the article.

Ethics statements

Patient consent for publication:
Ethics approval:

This study involves human participants and was approved by London-Harrow Research Ethics Committee, reference REC19/LO/0194 Participants gave informed consent to participate in the study before taking part.

Acknowledgements

The authors wish to thank the patients for participating in this research.

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  • Received: 7 July 2024
  • Accepted: 5 December 2024
  • First Published: 6 January 2025

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