Nasal high flow therapy: a novel treatment rather than a more expensive oxygen device

Benefit

Conventional low- and high-flow oxygen systems are traditionally used as first-line supportive treatment of hypoxaemic ARF. Unfortunately, in both systems, at high inspiratory flow rates there is a limitation of heating and humidifying of inspired oxygen as well as increased entrainment of room air, which leads to dilution of oxygen and lowering of F_iO2 [21]. The principles and mechanisms of action of NHF make it an attractive and promising oxygen delivery device for adult patients with hypoxaemic ARF. The beneficial effects of NHF in both objective parameters (respiratory rate and arterial oxygen saturation measured by pulse oximetry (S_pO2)) and subjective ones, such as the degree of sensed dyspnoea, were confirmed in two studies on patients with ARF receiving oxygen through NHF or face mask. NHF was associated with less dyspnoea, a lower respiratory rate and greater overall oxygenation and comfort [19, 22]. The short (30 min) implementation period of NHF [22] and the late initiation of its use [19] did not allow any further conclusions regarding the effectiveness of NHF on ARF.

Sztrymf et al. [23] studied the efficacy, safety and outcome of the immediate application of NHF in intensive care unit (ICU) patients with hypoxaemic ARF without any time limitation of its application. Use of NHF was associated with a significant reduction in respiratory rate, heart rate, dyspnoea score, supraclavicular retraction and thoraco-abdominal asynchrony and a significant improvement in S_pO2. These improvements were evident within the first 15–30 min after applying NHF and lasted throughout the study period without any unexpected side-effects. >75% of patients avoided intubation, and thus the authors concluded that NHF has a favourable effect on clinical signs and oxygenation in critically ill patients with ARF [23]. These encouraging results were further confirmed by the same group of authors 1 year later in a prospective observational study on patients with ARF caused by community-acquired pneumonia and sepsis [24]. Moreover, NHF may be more effective in treating mild to moderate hypoxaemic ARF compared to oxygen delivered through a face mask, with fewer desaturations and less need for NIV, as reported in a prospective randomised study by Parke et al. [25].

Although the aforementioned studies included patients with hypoxaemic ARF and various level of hypoxaemia, none of them assessed the effect of NHF on other important clinical outcomes, such as intubation rate and mortality. In a recent randomised controlled trial involving patients admitted to the ICU with hypoxaemic ARF, NHF, NIV and standard oxygen therapy (SOT) were evaluated for their effect on endotracheal intubation and outcome [26]. Neither NIV nor NHF decreased the rate of intubation among the overall studied population. However, the intubation rate was significantly lower with NHF in the subgroup of patients with more severe respiratory insufficiency (arterial oxygen tension (P_aO2)/F_iO2 ≤200). Moreover, therapy with NHF resulted in a significantly lower ICU and 90-day mortality, as compared with SOT or NIV, which was attributed to lower intubation rates among patients with severe hypoxaemia. Thereafter, it seems that NHF can be used in every stage of hypoxaemic ARF, even in patients with acute respiratory distress syndrome [27].

No benefit

As with NIV [28], there is a great concern about the optimum duration of NHF use. The potential masking of any respiratory deterioration may increase mortality due to delayed intubation [29]. In fact, findings from a retrospective observational study in ICU patients suggested that early intubation (i.e. within 48 h of NHF initiation) was associated with lower overall ICU mortality, better extubation success and more ventilator-free days than late intubation when patients had received NHF therapy that failed [29]. The 48 h time frame is in accordance with that of Moretti et al. [28], who recorded particularly high mortality (67.7%) in patients with NIV failure who were intubated after the aforementioned time. Some significant factors could have influenced the results of this study [29]. Flow settings of NHF were not provided, which is crucial since the benefits arising from its application are all flow dependent. In addition, more patients in the late group were intubated because of acute-on-chronic respiratory failure, in whom only NIV is recommended to date [30].

In the HOT-ER study [31] performed in patients admitted to the emergency department with ARF, no differences were detected between NHF and SOT regarding the rate of initiation of mechanical ventilation (invasive or noninvasive) in the emergency department, the length of emergency department or hospital stay and 90-day mortality. However, during the study, it became apparent that some participants received NIV soon after leaving the emergency department, and a post hoc analysis showed that fewer participants in the NHF group required mechanical ventilation either in the emergency department or within 24 h of leaving the emergency department. It is possible that NHF exerts its benefit beyond the first few hours because the developed airway pressures are low and thus a longer time period is needed to recruit any atelectatic lung areas. A significant message that can be drawn from these two studies [29, 31] could be that although NHF application in patients with ARF seems to be very effective, we need more randomised trials to define predictors of success or failure in order to avoid early discontinuation of the therapy, or, in contrast, for timely diagnosis of treatment failure and intubation, thus avoiding any undesired evolution. A summary of these studies is shown in table 1.

Benefit

The incidence of extubation failure in ICU varies between 6% and 47%, with respiratory failure being its most common cause, and is associated with a significant morbidity and mortality more than double that of successful extubation [32]. SOT devices are used to treat this complication, but they may be inadequate in patients with high inspiratory flow, since they can provide oxygen at flow rates <15 L·min⁻¹ [21, 32, 33]. Rittayamai et al. [34], in a crossover study, compared 30-min interventions with NHF and a non-rebreathing mask in recently extubated patients. They reported significant reductions in dyspnoea, respiratory rate and heart rate with NHF [34]. These results were further confirmed and strengthened by another study comparing NHF with the Venturi mask in critically ill patients requiring oxygen therapy after extubation (P_aO2/F_iO2 <300) [35]. It was found that use of NHF was associated with a lower respiratory rate, less discomfort and better oxygenation for the same set F_iO2, until 48 h after extubation, with fewer episodes of oxygen desaturation. Moreover, the use of NHF in the post-extubation period was associated with less need for NIV and endotracheal intubation than the Venturi mask (7.5% versus 34.6%) [35]. Both these studies [34, 35] support the protective role of NHF after extubation, attributing this effect to higher flow of the administered gas with the NHF system, which could meet the ventilator demand of the patient after extubation. Given the fact that the patients included in these studies [34, 35] had residual respiratory impairment, these results could not be generalised to the overall population. Indeed, even in patients at low risk of re-intubation, NHF successfully reduced re-intubation rates from 12.2% [36, 37] to 4.9%, compared to SOT devices, without any reported complications, which was attributed to NHF-favourable mechanisms on the work of breathing and the conditioning of the inspired gas, even at high flow rates [38].

No benefit

Although the consistent benefit in comfort and tolerance is confirmed in almost all studies applying NHF after extubation [34, 35, 38, 39], there are conflicting data about its effect on gas exchange and physiological parameters. In a crossover study [39], patients were randomised after extubation to either NHF followed by high-flow face mask or high-flow face mask followed by NHF. No differences in gas exchange, heart rate, blood pressure or respiratory rate were found between the two groups [39]. However, the fact that the face mask was applied with similar flow rates as NHF, i.e. 30 L·min⁻¹, could explain the results. In another study of patients at high risk of re-intubation [40], NHF was not inferior to NIV in re-intubation rates and time to re-intubation, although NHF group had lower post-extubation respiratory failure rates. It is possible that the 24 h limit of using NHF as a preventive measure for re-intubation might have influenced the results, since the application of NHF for 48 h in the study of Maggiore et al. [35] showed persistent improvement in oxygenation and comfort parameters and achieved a lower re-intubation rate than the former study [40]. Conversely, delaying intubation is associated with increased morbidity and mortality, as previously reported using NHF or NIV to treat ARF [29, 41]. Perhaps more studies are needed to clarify whether specific clinical parameters should be used instead of fixed periods of time in order to achieve the greatest benefit from NHF use while avoiding any delay in intubation. A summary of these studies is shown in table 2.

Benefit

Respiratory complications play a significant role after major surgery, and can determine morbidity and mortality and substantially increase healthcare cost [42, 43]. Traditionally, low- and high-flow oxygen systems have been used to reverse post-surgical respiratory complications. NHF might be superior in post-cardiac and thoracic surgery patients, since it can provide a high flow of heated and hydrated oxygen while the positive airway pressure created by the high gas flow can recruit alveoli and increase the EELV [5, 6, 25, 44, 45]. In two studies conducted by the same authors [25, 45], NHF was compared with SOT after extubation in patients undergoing cardiovascular surgery. Patients on NHF had significantly fewer desaturations and succeeded more in their allocated therapy, with less need for NIV or intubation, although respiratory (S_pO2, respiratory rate and forced expiratory volume in 1 s) and cardiovascular (systolic and diastolic arterial pressure and heart rate) variables did not differ between groups. Positive airway pressure, enabling the recruitment of atelectatic lung areas, along with facilitation of mucociliary clearance by the heated and humidified gas administered by NHF, were the possible key features that improved overall treatment effectiveness in both studies [25, 45], given that atelectasis is the more common respiratory complication after surgery, presenting in 90% of patients undergoing general anaesthesia [42].

The specific mechanisms of benefits of NHF on post-surgical respiratory complications were studied further by Corley et al. [5] and it was found that NHF compared to low-flow oxygen on post-cardiac surgery patients significantly increased mean airway pressure by 3.0 cmH₂O, tidal volume by 10.5% and EELV by 25.6%, regardless of whether they breathed with the mouth open or closed. There was a linear correlation between the increase in gas flow and EELV [5]. These findings were more apparent in patients with higher BMI, although they were not confirmed in a subsequent study by the same group of authors [46], probably because of the difference in the study protocols and the limited exposure to NHF (only 8 h) in the latter study.

No benefit

Recent randomised controlled trials have demonstrated that continuous positive airway pressure (CPAP) or bi-level positive airway pressure are better than standard oxygen devices in the postoperative period [47, 48] and are increasingly used in patients undergoing cardiothoracic surgery in order to prevent or treat postoperative ARF [49–51]. In an attempt to compare NHF with these techniques, a current randomised noninferiority trial [52] in post-cardiothoracic surgery patients compared the use of NHF to NIV; similar rates of treatment failure, discomfort and ICU mortality were detected in both study groups. Although NIV was associated with a higher P_aO2/F_iO2 ratio, probably because of the higher applied PEEP, NHF was associated with lower values of P_aCO2 and respiratory rate, with possible explanations being higher tidal volumes, improved inspiratory flow dynamics and a carbon dioxide washout effect [52]. Given the noninferiority of NHF compared to NIV in this group of patients, NHF could be used as a first option, since it provides the advantages of ease of application and lower nurse workload without hampering a patient's prognosis.

Few studies have investigated the role of NHF application in other types of surgery. There is only one study [53] in patients with lung resection surgery where immediate application of NHF versus low-flow oxygen did not improve early functional recovery as assessed by 6-min walk test and standard spirometry, although it resulted in reduced hospital length of stay and improved patient satisfaction. However, most patients included in the study had a good 6-min walk test before surgery. In another study, the preventive application of NHF directly after extubation was compared to SOT in patients undergoing major abdominal surgeries. NHF was ineffective at reducing the incidence of hypoxaemia as well as other postoperative outcomes such as pulmonary complications and length of hospital stay [54]. The small sample size, along with the lower than expected rate of hypoxaemia after surgery might have influenced the results, and thus more studies are needed to clarify the role of NHF after abdominal surgery. A summary of these studies is shown in table 3.

Benefit

Endotracheal intubation in the ICU is one of the highest risk procedures, resulting in complications up to 40% or cases [55]. Pre-existing hypoxaemia and haemodynamic instability of ICU patients are the main reasons for insufficient pre-oxygenation and severe desaturations during laryngoscopy, throughout which pre-oxygenation is interrupted, even for a short period [55–58]. NHF (60 L·min⁻¹) has been evaluated as an alternative technique for pre- and peri-oxygenation (i.e. oxygenation during laryngoscopy) during the intubation procedure in comparison with non-rebreathing bag reservoir face mask (15 L·min⁻¹) in a nonrandomised prospective study [59]. Oxygen with 6 L·min⁻¹ flow was administered to patients through a nasopharyngeal catheter during intubation in the face mask group, while in the NHF group the initial flow rate and F_iO2 were maintained throughout the intubation procedure. The median S_pO2 was significantly lower and the prevalence of severe hypoxaemia (S_pO2 <80%) was present exclusively in the face mask group. Similar results were observed in a recent study, comparing the combination of NHF and NIV versus NIV alone, during the intubation procedure in patients with severe hypoxaemic respiratory failure [60]. Even without lung expansion, oxygen diffusion from the alveoli to the capillaries decreases alveolar pressure, and by increasing pharyngeal oxygen content a flow of air is generated from the pharynx to the distal airway, which is called apnoeic oxygenation [61]. High flow rates with NHF create a great oxygen reservoir in nasopharyngeal area, which together with carbon dioxide elimination by flushing of the dead space [11, 12] and the generated CPAP [3–8] make NHF a promising oxygenation device in the peri-intubation period, which maintains oxygenation without a rapid and dangerous rise in carbon dioxide concentration [62].

No benefit

In contrast to the study by Miguel-Montanes et al. [59], in which patients with severe hypoxaemia were excluded, and given that severe hypoxaemia before endotracheal intubation is an independent risk factor for severe desaturation during intubation [55], a multicentre controlled randomised study was conducted, comparing NHF versus a non-rebreathing bag reservoir face mask in the pre-oxygenation of severely hypoxaemic patients [63]. In the NHF group, the initials settings were F_iO2 100% with a flow rate of 60 L·min⁻¹, and they were maintained throughout the procedure in order to achieve apnoeic oxygenation. In the face mask group, the flow rate was set at 15 L·min⁻¹ and the mask was removed after pre-oxygenation to enable laryngoscopy. There was no difference between the two oxygenation devices in preventing desaturation, not even during the apnoeic period, regardless of the severity of respiratory distress. The main difference between the studies by Miguel-Montanes et al. [59] and Vourc'h et al. [63], which could explain the discordant results, was the level of hypoxia of the patients included, which was more severe in the latter study. In addition, apnoeic oxygenation has been the subject of debate in recent literature, with conflicting results regarding the prevention of desaturation [64, 65]. However, in both studies [64, 65] lower flow rates were used (≤15 L·min⁻¹) for apnoeic oxygenation; thus, it is evident that further studies are needed to define the effectiveness of different levels of flow rate for apnoeic oxygenation in distinct groups of patients.

Benefit

Choosing the optimal device for delivering oxygen in immunocompromised patients with ARF is extremely important, since invasive mechanical ventilation is associated with high mortality rates up to 40–60%. In order to avoid intubation and invasive mechanical ventilation, NIV is traditionally used as first-line treatment in this group of patients, although NIV failure has also been associated with increased mortality [66–68].

In two studies, the effects of NHF and NIV were assessed in immunocompromised patients admitted to the ICU for ARF [69, 70]. In both studies, the rates of intubation and mortality were lower in patients treated with NHF than in those randomly assigned to NIV. Moreover, NIV remained independently associated with increased rate of intubation and mortality [69, 70]. The results could be attributed to the better tolerance of NHF and the potential harmful effects of NIV through increasing tidal volumes, thus leading to high transpulmonary pressure and ventilator-induced lung injury [70].

In another study including patients with cancer and ARF, NHF in combination with NIV was associated with a lower 28-day mortality rate compared to either NHF alone or to a combination of SOT with NIV [71]. These results contrast with the results of the FLORALI (Clinical Effect of the Association of Non-invasive Ventilation and High Flow Nasal Oxygen Therapy in Resuscitation of Patients with Acute Lung Injury) study [26], in which the combination of NHF–NIV in an unselected population with hypoxaemic ARF was associated with high mortality. It is possible that the differences in the NIV application protocol (time and number of sessions) as well as the different study populations could explain the dissimilar results between studies [26, 71]. The beneficial effects of NHF have been highlighted in two further studies in patients with solid tumours [72] and haematologic malignancies [73], where more than one-third of the patients improved while on NHF and another large percentage (44%) remained stable [72], often obviating the need for ICU admission or invasive mechanical ventilation. Tolerance of the device was good with few complaints (e.g. nasal discomfort) [72].

Lung transplant patients comprise another group of immunocompromised patients who often require admission to the ICU and intubation because of ARF, with high mortality rates. NHF has been shown to reduce this risk by ∼29.8% compared to conventional oxygen therapy; the number of patients needed to treat with NHF in order to prevent one intubation was three [74]. Failure of NHF treatment and further need for mechanical ventilation was not associated with higher mortality [74].

No benefit

In contrast to the aforementioned studies, when NHF was compared to Venturi mask in immunocompromised patients admitted to the ICU with clinical signs of respiratory distress or hypoxaemia, NHF application neither decreased the need for invasive mechanical ventilation or NIV nor improved the patient's comfort, dyspnoea, respiratory rate or heart rate [75]. These results could be explained by the fact that the study was underpowered to demonstrate the potential inferiority of NHF compared to Venturi mask. In addition, sources of discomfort were not assessed, since the underlying disease associated with immunodeficiency may have been a significant source of patient discomfort, not influenced by the mode of oxygen delivery.

In another retrospective study in patients with haematologic diseases complicated by ARF, it was found that although NHF therapy was safe and well tolerated, only 20% of the patients showed a good response to NHF therapy, while the remaining 80% required a second-line intervention including endotracheal intubation and mechanical ventilation, NIV or narcotic palliation alone [76]. A significant factor that could have led to underestimation of NHF efficacy in this study was that a lot of the patients underwent palliation therapy or died while they were on NHF, and they were then classified as nonresponders to NHF regardless of the response.

A question that is raised in cases of NHF failure in immunocompromised patients is the delay of optimal treatment initiation, which could further increase the mortality rates in this group of patients at very high risk of death, as shown with NIV failure in the general population [28]. To date, only one study has shown that NHF failure was not associated with higher mortality rates [74], but undoubtedly, further studies are needed to clarify the safe time frame of NHF application as well as the specific indications of NHF oxygen delivery in immunocompromised patients. A summary of these studies is shown in table 4.