European Respiratory Society guidelines on long-term home non-invasive ventilation for management of COPD

Background

COPD can cause both hypoxaemic and hypercapnic CRF resulting in a high impact on mortality and economic burden of disease [19, 20]. So far, long-term oxygen therapy (LTOT), which has been shown to improve survival, is the standard of care in COPD patients with hypoxaemic CRF. COPD patients with chronic hypercapnia are more likely to be admitted to hospital, and once admitted experience a more rapid clinical deterioration [21, 22]. The presence of hypercapnia has been shown to be a determinant of mortality [23–25].

Correcting hypercapnia may be an important intervention aiming at improving the prognosis of these patients. NIV in this setting is increasingly being used [26, 27]. The favourable impact of the reduced lung hyperinflation on respiratory muscle workload and the increased ventilatory chemo-sensitivity to carbon dioxide have been demonstrated as the main mechanisms that may explain the effectiveness of NIV in stable hypercapnic COPD patients [28–30].

Many patients with advanced COPD have severe comorbidities (most importantly cardiovascular diseases), which independently impact their prognosis. Therefore, improving survival in hypercapnic COPD patients is challenging. The inconsistent results evident between early studies [26] are likely due to a number of factors, including heterogeneous patient populations (including different degrees of hypercapnia), different NIV ventilators, varied ventilator settings and interfaces, wide range of NIV application time and patient compliance.

In 2009, McEvoy et al. [31] randomised 144 severe hypercapnic COPD patients either to NIV+LTOT or LTOT alone and demonstrated a slight survival benefit with NIV (median 28 months versus 20.5 months), but decreased HRQL. The mean inspiratory positive airway pressure (IPAP) was 13 cmH₂O and the mean expiratory positive airway pressure (EPAP) was 5 cmH₂O, which corresponded to an inspiratory pressure support (difference between inspiratory and expiratory pressures) of 8 cmH₂O. There was no decrease in partial pressure of carbon dioxide in arterial blood (P_aCO2) level during follow-up. Subsequent clinical observation studies and randomised crossover clinical trials reported that targeting maximal reduction of carbon dioxide by high inspiratory pressures and high backup rates, or so called high-intensity NIV, improved gas exchange, lung function and respiratory muscle function [32–35]. A multicentre RCT included 195 patients with stable chronic hypercapnia (mean P_aCO2 59 mmHg in the NIV group and 58 mmHg in the control group) and randomised patients to either LTOT alone or LTH-NIV in addition to LTOT ventilation targeting carbon dioxide reduction (mean IPAP of 22 cmH₂O with a mean EPAP of 5 cmH₂O employed to decrease P_aCO2 by at least 20% from baseline or to achieve P_aCO2 <48 mmHg). Results showed a 1-year survival benefit in patients randomised to LTH-NIV with an increase in HRQL [36].

Long-term prognosis following hospitalisation in COPD is poor, with 5-year mortality rates of around 50% [37]. Therefore, one of the overall goals in the management of COPD is to minimise the number of disease-related hospitalisations, especially in those patients at high risk of developing acute hypercapnic respiratory failure (AHRF). LTH-NIV, initiated when the patient is in stable condition, may reduce the number of future hospitalisations in these patients. Clini et al. [38] reported that overall hospital admissions were lower in patients randomised to NIV and LTOT as compared with LTOT alone (−45% versus +27%). In the study by Köhnlein et al. [36], a decrease in emergency hospital admissions was observed in the NIV group when compared to the control group (2.2 and 3.1 exacerbations per patient per year, respectively).

Evidence summary

Overall 13 RCTs (comparators to NIV are shown in the appendix) evaluated the effect of LTH-NIV on survival in stable hypercapnic patients with COPD; pooled analysis showed that NIV may have little effect on mortality (relative risk (RR) 0.86, 95% CI 0.58–1.27; low certainty) [31, 36, 38–48] or hospitalisations (mean difference (MD) 1.26 fewer hospitalisations, 95% CI 0.08–2.59; low certainty) [36, 38, 49].

Although the presence of hypercapnia is one of the primary indicators to prescribe LTH-NIV in COPD, data suggest only a limited effect of NIV on this outcome. The pooled data over 12 RCTs showed that P_aCO2 decreased by 3.37 mmHg (95% CI 0.99 lower to 5.75 lower; moderate certainty) and partial pressure of oxygen in arterial blood (P_aO2) increased by 3.09 mmHg (95% CI 1.45 higher to 4.74 higher; moderate certainty) following NIV therapy [31, 36, 39, 41, 43–50]. This minimal effect may be due to the fact that ventilator settings were not titrated to target normal P_aCO2 levels. In a subgroup analysis of five RCTs in which NIV was used to target normal P_aCO2 levels, the P_aCO2 decrease was larger (4.92 mmHg reduction, 95% CI 2.90 lower to 6.94 lower) [36, 39, 46–48]. There was no effect of NIV upon lung function as assessed by forced expiratory volume in 1 s (FEV₁) (standardised mean difference (SMD) 0.07 higher, 95% CI 0.14 lower to 0.27 higher; low certainty) or forced vital capacity (SMD 0.10 higher, 95% CI 0.06 lower to 0.26 higher, low certainty) [31, 36, 38, 39, 41, 44, 46–48, 50].

Dyspnoea, exercise capacity, and HRQL are recognised as the most important patient-centred outcomes in the COPD population. Pooled analysis of five RCTs shows that NIV may decrease dyspnoea scores (SMD 0.51 lower, 95% CI 0.06 lower to 0.95 lower; moderate certainty) [39, 43, 46, 47, 50]. NIV may improve exercise capacity and outcomes of pulmonary rehabilitation by resting chronically fatigued respiratory muscles, ameliorating lung mechanics, and daytime gas exchange [39]. Pooled analysis demonstrated an improvement in 6-min walk distance (6MWD) (MD 32.03 m, 95% CI 10.79–53.26 m; moderate certainty), which was higher than minimal important difference (26 m) for severe COPD, in those using NIV [36, 38, 39, 41, 45–47, 49–52].

Seven RCTs evaluated HRQL with a follow-up period ranging between 3 and 12 months; the pooled analysis demonstrated that HRQL was higher with NIV (SMD 0.49 higher, 95% CI 0.01 lower to 0.98 higher; very low certainty) [31, 36, 39, 43, 46, 47, 50]. Included studies had to use one of the multiple validated scales/questionnaires in this population to assess HRQL. Whether NIV using high inspiratory pressure support values might be associated with higher HRQL remains unclear. In the multicentre study of Köhnlein et al. [36], Severe Respiratory Insufficiency (SRI) Questionnaire summary scale score, general health perception subscale of Short Form 36 (SF-36) and St George Respiratory Questionnaire (SGRQ) summary score improved more with NIV than with LTOT alone.

The effect of LTH-NIV on sleep quality has been studied to a lesser extent and only based on subjective assessments. Pooled analysis suggested sleep efficiency was slightly lower in those randomised to NIV (SMD 0.55 lower, 95% CI 1.13 lower to 0.03 higher; low certainty), but the clinical relevance of this is unclear due to heterogeneous measurements of sleep [38, 41, 46]. Minor adverse events such as discomfort, skin damage or rash were more common with NIV therapy (RR 10.35, 95% CI 2.45–43.71; low certainty) when compared to LTOT alone. However, most of these effects are interface-related and may be straightforward to manage [53, 54].

Justification

The guideline panel decided on a conditional recommendation for NIV in the setting of stable chronic hypercapnic COPD patient. This recommendation was based on the evidence suggesting improvements in HRQL, dyspnoea, and exercise tolerance. Even though the certainty in evidence for these outcomes was low to moderate, all were felt to be very important to patients. The evidence also suggested the possibility of small reductions in mortality and hospitalisations, with LTH-NIV, though there was significant imprecision in the pooled effects. Overall, the benefits were felt to outweigh the potential harms including minor adverse events.

In terms of costs, frequent exacerbations and hospital readmissions account for the greatest part of economic burden in COPD patients, and economic data from the included trials suggest that NIV is cost-effective, especially in patients with frequent exacerbations and hospital admissions. Historically, LTH-NIV has been shown to reduce disease-related cost by decreasing the rate of outpatient visits, the hospital admissions, and the length of stay in the hospital [55]. The overall cost-effectiveness of NIV therapy depends on further variables, such as strategy for initiating NIV and close monitoring and follow-up including home care. LTH-NIV has evolved over the past 20 years and today's technology gives us the opportunity to monitor, even remotely, many physiological parameters by built-in software systems of NIV devices [56]. While in higher developing countries there has been a widespread use of LTH-NIV, in the countries with lower income economies, financial constrains may be a major limiting factor for patients who may benefit of LTH-NIV, including those with stable COPD [57].

Background

Severe COPD patients with chronic hypercapnia are most likely to experience re-hospitalisation after a life-threatening episode of acute on chronic respiratory failure. These so-called “revolving doors” patients, are often discharged with a P_aCO2 above 55 mmHg after a decompensated or compensated episode of respiratory acidosis due to COPD exacerbation on the background of at least two hospital admission episodes in the previous year [55, 58].

Four RCTs have evaluated the use of LTH-NIV after AHRF [59–62]. The first clinical trial randomised 40 patients with severe stable COPD (P_aCO2 ≥55 mmHg) after hospital discharge from AHRF to NIV or standard treatment for 2 years. The use of NIV was not associated with a reduction in mortality but improved several physiological (e.g. P_aCO2 and P_aO2, 6MWD, mean pulmonary artery pressure), patient-centred (e.g. anxiety, depression, dyspnoea) and healthcare centred (e.g. hospitalisation rates) outcomes [59]. The second trial was a pilot RCT designed to compare continuation of NIV from hospital to home, with sham continuous positive airway pressure (CPAP) used as control, in severe COPD patients who had survived an acute episode treated with NIV and showed persistent hypercapnia at discharge (mean P_aCO2 ∼50 mmHg). A total of 47 patients were randomised and the proportion of patients developing an acute exacerbation during the time course of the study was statistically higher in the CPAP group. Of note, 8/23 (35%) of the LTH-NIV patients were withdrawn from the study before completion [60].

Two larger RCTs investigated the clinical efficacy of NIV as a bridging treatment from hospital to the home following a life-threatening exacerbation of COPD requiring acute NIV. In the RESCUE trial, 201 COPD patients admitted to hospital with a life-threatening episode of AHRF and prolonged hypercapnia (mean P_aCO2 ∼48 mmHg) greater than 48 h after termination of ventilatory support were randomised to NIV in addition to LTOT or LTOT alone. After 1 year, there was no difference between the two groups in the primary outcome of time to readmission or death. Although NIV was effective in reducing daytime and night-time P_aCO2, a similar reducing in P_aCO2 was observed in the control group [61].

The HOT-HMV trial studied 116 COPD patients with persistent hypercapnia (P_aCO2 >53 mmHg) at 2–4 weeks after a life-threatening episode of acute on chronic respiratory failure treated with acute NIV, were randomised to receive LTH-NIV, in addition LTOT, or LTOT alone. The NIV+LTOT group, compared to the LTOT group, resulted in an increased time to readmission or death within 12 months (4.3 months versus 1.4 months) [62].

It is difficult to translate the results from the earlier studies into advice for the practising clinician due to the small sample sizes, lack of standard definition of acute COPD exacerbation, and lower pressure support levels compared to the later studies. However, major clinical interest was raised by the latter trials, which despite similar trial design and primary outcome measure had differing results in terms of admission-free survival. It is likely that the higher level of P_aCO2 at enrolment (mean 48 mmHg versus 53 mmHg), the higher exacerbations rate prior to enrolment and the timing selection of patients with persistent hypercapnia at 2–4 weeks following a life-threatening exacerbation were major determinants of the enhanced outcome in the HOT-HMV trial. Conversely, the early within-hospital assessment of hypercapnia in the RESCUE trial may have led to the inclusion of a subset of patients with spontaneously reversible hypercapnia who do not take benefits from LTH-NIV treatment and consequently a better prognosis. The trajectory of recovery of hypercapnia is likely to have an influence on the outcome and the timing of this recovery needs clarification [24].

Another RCT evaluated the effects of stopping NIV after 6 months post-hospitalisation, finding that patients who remained hypercapnic after 6 months of therapy had clinical worsening and reduced 6 MWD after stopping NIV, compared to those who continued, indicating the importance of careful selection of patients who will continue to benefit from LTH-NIV [63].

Evidence summary

Use of LTH-NIV after AHRF was not associated with a reduction in mortality (RR 0.92, 95% CI 0.67 to 1.25; low certainty), but may reduce exacerbations (SMD 0.19 sd, 95% CI −0.40 to 0.01 sd; low certainty) and hospitalisations (RR 0.61, 95% CI 0.30–1.24; very low certainty) though the study by Cheung et al. [60], at high risk of bias, and with unclear definition of acute exacerbation, makes interpretation of these outcomes difficult. Reassuringly, sensitivity analysis excluding Cheung et al. [60] does not significantly affect the conclusions made for these outcomes. Similarly, NIV may be associated with improvements in dyspnoea scores measured using Medical Research Council Dyspnoea score (MD 0.8 points lower, 95% CI 2.17 lower to 0.58 higher; low certainty) and HRQL measured using SRI (MD 2.89 higher, 95% CI 1.03 lower to 6.8 higher) but these results are limited by imprecision and are of low certainty. NIV likely reduces P_aCO2 (MD −3.41 mmHg, 95% CI −4.09 to −2.73; moderate certainty).

Justification of recommendation

The recommendation was primarily based upon the desirable effects of LTH-NIV after a life-threatening episode of acute on chronic respiratory failure, which suggest a small potential reduction in exacerbations and hospitalisations, though the overall certainty of evidence is low, primarily due to imprecision as well as reservations about the risk of bias. The task force considered indirect evidence from PICO question 1 with regard to minor adverse effects and resources required to help to inform the recommendations here, and noted that reassuringly similar desirable effects of NIV were seen in the COPD population both in stable (PICO question 1) and in post-AHRF phase (PICO question 2), with few undesirable effects seen. Other outcome data from PICO question 1 was used for question 2 analysis or recommendation generation. Similarly, the task force considered that the potential significant variability in values and trade-offs between mortality and HRQL with the use of NIV may play a role in shared decision-making about its use in this population, and ultimately the acceptability of NIV as an intervention. The task force considered the resources used similar to that in PICO question 1, though the feasibility of initiating NIV post-exacerbation may be higher, as in some centres clinical pathways exist post-discharge to facilitate initiation of LTH-NIV. Considering all of the above in light of the limitations of the evidence, the task force panel chose to make only a conditional recommendation for the use of LTH-NIV after AHRF. Finally, there was discussion that patients may continue to improve for several weeks post-exacerbation; for this reason, reassessment of hypercapnia 2–4 weeks after the initial episode, as was done in the HOT-HMV trial, could be considered to identify those patients who are most likely to benefit from LTH-NIV.

Background

In the past two decades, a number of published RCTs aimed at exploring the role of LTH-NIV in those with hypercapnic COPD; however, most did not specifically target normalisation or significant reduction in P_aCO2 or directly address nocturnal alveolar hypoventilation. High-intensity NIV, a form of pressure-limited controlled ventilation, that combined stepwise titration of IPAP up to 30 cmH₂O with an high backup rate just below the patient's spontaneous breathing frequency, was introduced as a novel therapeutic option in an attempt to maximally decrease elevated P_aCO2 to normal levels and, at the same time, to achieve the total control of the patient's spontaneous respiratory activity aiming for substantial rest of the diaphragm [35, 64, 65]. Given to the greater capability of correcting nocturnal alveolar hypoventilation, high-intensity NIV has been reported to be more efficient in terms of clinical and physiological benefits (reduction of nocturnal and diurnal P_aCO2 levels; improvement in FEV₁, patient-reported exercise-related dyspnoea score, 6MWD and HRQL) than conventional “low-intensity” NIV. Paradoxically, delivery of higher levels of pressure support was associated with better compliance to the treatment, probably as consequence of a greater subjective benefits perceived by chronically symptomatic patients [64–67].

A strategy based on the combination of high pressure support levels and low backup rate, termed “high-pressure” NIV, has been shown to provide the same physiological and clinical improvement in stable hypercapnic COPD compared with “high-intensity” NIV, suggesting that the use of a high backup rate is not necessary to achieve these benefits in such patients [67]. However, the number of patients in this study was considerably small requiring further investigations.

In consideration of the greater haemodynamic impact of “high-intensity” NIV as compared to “low intensity” NIV, positive intrathoracic swing pressure-induced decrease in right heart preload and elevated lung volume-induced increase in pulmonary vascular resistance, detrimental cardiovascular effects (i.e. reduced cardiac output) could develop under very high IPAP levels in very selected phenotypes of COPD patients, especially if pre-existing severe cardiovascular diseases coexist [64, 65]. However, the clinical significance of these effects needs further evaluation. Although it appears that high inspiratory pressure NIV leads to a reduction in hypercapnia, the impact on some patient important outcomes, such as sleep quality, is less certain [66, 67].

Finally, it should be considered that the definition of hypercapnia used amongst the studies targeting NIV to P_aCO2 normalisation in stable hypercapnic COPD patients was quite different, sometimes with very low mean baseline P_aCO2 levels [61]. Independently from the baseline degree of hypercapnia, a normalisation of elevated P_aCO2 levels is unlikely to be achieved in all COPD patients even under high IPAP levels.

Evidence summary

Even though one short-term trial reported physiological benefits of NIV targeted to reduce chronic hypercapnia [34], we did not find any long-term RCTs directly comparing LTH-NIV strategies targeting P_aCO2 reduction in those with chronic COPD versus those that did not. For this reason, to address this question, we considered subgroup analysis from PICO question 1 comparing studies that targeted normalisation of P_aCO2 as compared to studies that did not target normalisation.

Pooled analysis of five RCTs demonstrated that while “high-intensity” NIV decreases P_aCO2 levels at 6 weeks (MD −4.93 mmHg, 95% CI −7.43 to −2.42; low certainty) as compared to “low-intensity” NIV, there was no effect on HRQL as assessed by the SRI (MD 0.95 points higher, 95% CI 8.33 lower to 6.42 higher; low certainty) in the “high-intensity” subgroup [34, 64–66]. There was no effect demonstrated with “high-intensity” NIV on FEV₁ (MD 0.04 L higher, 95% CI 0.34 lower to 0.42 higher; low certainty), 6MWD (MD 14 m higher, 95% CI 70.42 lower to 98.42 higher; low certainty), sleep comfort measured by visual analogue scale scale (MD 1 cm higher, 95% CI 28.42 lower to 30.42 higher; very low certainty) or P_aO2 levels at 6 weeks (MD 3.4 mmHg higher, 95% CI 2.39 lower to 9.19 higher; low certainty).

Justification

The task force panel decided on a conditional recommendation for targeted reduction of P_aCO2 in COPD patients with persistent hypercapnic respiratory failure. Although the benefit was uncertain, this recommendation was driven by the minimal potential harms of targeted P_aCO2 reduction [64, 65], though it is recognised that this is unlikely to be achieved in all patients. While there is low certainty of evidence of benefit, the anticipated harms have not been clearly demonstrated, and as such the panel felt the overall balance favoured the intervention. Setting NIV to target a reduction in P_aCO2 may require more time spent in hospital [34], and therefore possibly increase costs and decrease feasibility of NIV; however, adherence was significantly better using this strategy.

Background

In general, classical modes of LTH-NIV comprise both pressure-targeted and volume-targeted NIV. During pressure-targeted NIV, the inspiratory pressure is set, while the delivered inspiratory volumes vary according to the impedance of the respiratory system and the patient's respiratory efforts. In contrast, during volume-targeted NIV, a predetermined inspiratory volume is set, while inspiratory pressures are variable. Accordingly, the physiological advantage of volume-targeted NIV is the stability of tidal volume, while pressure-targeted NIV is advantageous regarding leak compensation when the inspiratory flow is increased in case of leak-related dropping pressure. Even though physiological and short-term clinical studies indicate that pressure-targeted NIV is better tolerated due to less varying peak inspiratory pressures, both modes are reported to be comparably effective in providing NIV, though the majority of studies have investigated heterogeneous patient cohorts and not exclusively patients with COPD [68–75]. Long-term studies comparing currently available ventilator modes do not exist, limiting the potential for strong conclusions. However, nearly all studies providing evidence for the use of LTH-NIV in COPD in PICO question 1 and PICO question 2 used pressure-targeted modes rather than volume-targeting modes of NIV, making pressure volume modes the de facto standard in LTH-NIV for COPD.

Recent developments seek to combine the advantages of volume- and pressure-targeted NIV, while avoiding their disadvantages [76]. In addition, there is a physiological rationale supporting the interest in continuously adapting ventilator parameters to fluctuating patient needs during the night and also over the long term. In addition, upper airway patency may vary with body position and sleep stage, especially during rapid eye movement (REM) sleep. Respiratory mechanics may also change as an individual's disease worsens over time. Ideally, LTH-NIV aims to deliver the adequate inspiratory pressure support to achieve targeted minute ventilation and sufficient expiratory pressure for complete stabilisation of the upper airway.

The so-called adaptive or auto-titrating modes have been designed to achieve these objectives even if applied with different software. There was also the hope that automatically identifying adequate settings for a given patient would allow implementation of NIV in non-specialised centres, thus favouring the widespread application of the technique. Conversely, there are certain complications and pitfalls related to these hybrid modes as depicted in detail elsewhere [76].

Evidence summary

Six RCTs compared adaptive or auto-titrating pressure modes (e.g. iVAPS, Resmed, Australia; AVAPS, Philips, USA) to classical pressure support modes [77–82]. These studies were generally not blinded, and of short duration, prohibiting assessment of long-term outcomes such as mortality or hospitalisations. Six studies demonstrated that use of adaptive or auto-titrating modes may result a small reduction in P_aCO2 (MD 1.95 mmHg lower, 95% CI 4.29 mmHg lower to 0.40 mmHg higher; low certainty) and little to no difference in oxygenation (SMD −0.04, 95% CI −0.33 to 0.26; low certainty) compared to conventional NIV. Adaptive or auto-titrating modes did not significantly improve HRQL using the SGRQ or the SRI (SMD 0.28, 95% CI −0.66 to 0.10 sd; low certainty evidence), sleep quality measured using a variety of validated instruments (SMD - 0.14, 95% CI −0.53 to 0.26 sd; very low certainty), or exercise tolerance (SMD −0.1, 95% CI −0.51 to 0.30; low certainty) compared to conventional fixed modes of NIV.

Adherence to NIV was equivalent when comparing adaptive or auto-titrating modes to conventional assist modes in five studies [77–81]. Regarding patient-centred outcomes, no improvement in self-reported tolerance [78, 80] or self-reported comfort [77, 78] was achieved with the newer modes. One study used a specific questionnaire to assess acceptability, but again no difference was demonstrated [82].

Justification

While the pooled analyses suggests a small potential benefit to adaptive or auto-titrating modes in P_aCO2 reduction, and acceptable adherence, our recommendation is conditional for fixed modes owing to substantial uncertainty of the effects of adaptive or auto-titrating modes, and the heterogeneity across studies for algorithms, brands of devices and lack of detailed information regarding the way adaptive modes function. Moreover, there is uncertain risk of harm with adaptive/auto-titrating modes when there is severe air leak, a common clinical scenario, as adaptive modes require the ventilator to accurately measure/estimate tidal volumes [76]. This raises safety concerns, as inappropriate low volumes could be delivered in this situation, resulting in hypoventilation. The short follow-up of the available trials means there is little data on this potentially serious risk. Furthermore, there may be substantial additional cost to patients to upgrade to a machine equipped with these newer ventilatory modes if a patient is already using an older ventilator; however, for patients starting with new devices the costs may be similar.

Patient-related factors

Equipment related factors

Many technical details with home ventilators, masks, tubes and humidification can decrease tolerance, efficacy and produce secondary effects, affecting adherence to the treatment [1, 86]. NIV can be delivered at home for COPD patients through nasal, oronasal or full face mask. Although nasal masks offer greater patient comfort, they often have the problem of oral leaks, especially during sleep, which in turn influence alveolar ventilation and sleep quality [1]. Currently, prescribers in Europe reported using oronasal masks more often as alveolar ventilation is much better with these than nasal masks, especially when high IPAP levels are used [27, 87–89]. Full face masks can serve as a supplement or an alternative to existing ventilation masks in the event of problems with pressure ulcers. Patients with frequent cough or abundant secretions, either chronically or during an exacerbation, usually do not tolerate oronasal masks and may use a nasal mask temporarily. There is no evidence that a particular interface guarantees greater benefit from LTH-NIV, so the choice should be carefully tailored to the patient choice.

Home ventilators can be used with a single circuit ventilation system with vented masks. The advantage of single circuits is their lower weight compared to double circuit systems and simpler handling, which is particularly important at home.

Circuits with expiratory valves can be also used. The expiration valve is located within the tubing circuit or in the ventilator. In an experimental study, the use of active valve circuits was associated with more efficient P_aCO2 reduction when compared to leak port circuits [90], but it remains unclear how this is translated in clinical long-term application.

Ventilators without battery will be used when NIV is used for less time in each 24-h period. If the patient uses it for a longer duration (approximately 12 h per day, depending on individual circumstances) a ventilator with internal battery should be considered.

However, upgrading to a device with an internal battery does incur a significantly greater cost and this added burden may be not be feasible across a range of health systems in lower income economies. In fact, the ventilator-dependence threshold for transitioning to a device with an internal battery may be variable among the different countries [57].

Active humidification is sometimes suggested for NIV [91] as it may improve adherence and comfort, but there is no clear consensus on whether additional heat and humidity are always necessary when the upper airway is not by-passed, such as in NIV. Thus, it could be added if mucosal dryness becomes an issue. Two systems, active humidification through a heated humidifier (HH) and passive humidification through a heat and moisture exchanger (HME), are available for warming and humidifying gases. Use of an HME is not beneficial in patients on NIV with intentional leaks, as the patient does not exhale enough tidal volume to replenish heat and moisture to adequately condition the inspired gas. HME may add additional work of breathing and use of an HME increases dead space and P_aCO2, and may increase ventilatory requirements [92]. With HH and intentional leaks, aerosolised contaminated condensate may increase the risk for infection.

Additional therapies