Background

ACC

Acute and Critical Care

Acute Crit Care

2586-6052 2586-6060

Korean Society of Critical Care Medicine

10.4266/acc.2018.00311

acc-2018-00311

Original Article

Pulmonary

Protecting Postextubation Respiratory Failure and Reintubation by High-Flow Nasal Cannula Compared to Low-Flow Oxygen System: Single Center Retrospective Study and Literature Review

http://orcid.org/0000-0002-0098-8106

Lee

Minhyeok

¹ ²

http://orcid.org/0000-0003-4677-0513

Kim

Ji Hye

http://orcid.org/0000-0001-9587-5122

Jeong

In Beom

http://orcid.org/0000-0001-5951-5058

Son

Ji Woong

http://orcid.org/0000-0002-0941-5806

Moon Jun

http://orcid.org/0000-0002-0361-8629

Kwon

Sun Jung

¹ 1Division of Respiratory and Critical Care Medicine, Department of Internal Medicine, Konyang University Hospital, Daejeon, Korea 2The 2nd Infantry Division of Republic of Korea Army, Yanggu, Korea

Corresponding author Sun Jung Kwon Division of Respiratory and Critical Care Medicine, Department of Internal Medicine, Konyang University Hospital, 158 Gwanjeodong-ro, Seo-gu, Daejeon 35365, Korea Tel: +82-42-600-8820 Fax: +82-42-600-9100 E-mail: sjoongkwon@hanmail.net

2 2019

28 2 2019

34 1 60 70 18 09 2018 2 02 2019 21 02 2019

2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0/) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

Background

Use of a high-flow nasal cannula (HFNC) reduced postextubation respiratory failure (PERF) and reintubation rate compared to use of a low-flow oxygen system (LFOS) in low-risk patients. However, no obvious conclusion was reached for high-risk patients. Here, we sought to present the current status of HFNC use as adjunctive oxygen therapy in a clinical setting and to elucidate the nature of the protective effect following extubation.

Methods

The medical records of 855 patients who were admitted to the intensive care unit of single university hospital during a period of 5.5 years were analyzed retrospectively, with only 118 patients ultimately included in the present research. The baseline characteristics of these patients and the occurrence of PERF and reintubation along with physiologic changes were analyzed.

Results

Eighty-four patients underwent HFNC, and the remaining 34 patients underwent conventional LFOS after extubation. Physicians preferred HFNC to LFOS in the face of high-risk features including old age, neurologic disease, moderate to severe chronic obstructive pulmonary disease, a long duration of mechanical ventilation, low baseline arterial partial pressure of oxygen to fraction of inspired oxygen ratio, and a high baseline alveolar–arterial oxygen difference. The reintubation rate at 72 hours after extubation was not different (9.5% vs. 8.8%; P=1.000). Hypoxic respiratory failure was slightly higher in the nonreintubation group than in the reintubation group (31.9% vs. 6.7%; P=0.058). Regarding physiologic effects, heart rate was only stabilized after 24 hours of extubation in the HFNC group.

Conclusions

No difference was found in the occurrence of PERF and reintubation between both groups. It is worth noting that similar PERF and reintubation ratios were shown in the HFNC group in those with certain exacerbating risk factors versus not. Caution is needed regarding delayed reintubation in the HFNC group.

airway extubation high-flow nasal cannula postextubation respiratory failure

INTRODUCTION

Postextubation respiratory failure (PERF) and reintubation are related to ventilator-associated pneumonia, mortality rates, and a longer stay both in the intensive care unit (ICU) and hospital in general [1]. Adjuvant oxygen therapy has commonly been used to prevent these undesirable events. The conventional low-flow oxygen system (LFOS) approach that includes a nasal cannula and facial mask has been used widely. However, more recently, a high-flow oxygen system (HFOS) including noninvasive ventilation (NIV) and high-flow nasal cannula (HFNC) has been preferred due to its physiologic benefits [2-6].

NIV has been used as a substitute for LFOS in acute respiratory failure [2,7]. It has also recently been applied with adjuvant oxygen application after extubation and has shown lower PERF and reintubation rate than LFOS [2,7]. In terms of physiologic aspects, this device is helpful to reduce the arterial partial pressure of carbon dioxide (PaCO2) and increases the arterial partial pressure of oxygen (PaO2) relative to that of LFOS [2,6,7]. However, it cannot be universally used because of the inconvenient interface and its own associated complications (e.g., dyssynchrony, barotrauma, pneumonia) [8].

HFNC is a newly developed device that can supply heated and humidified gas at a relatively constant fraction of inspired oxygen (FiO₂, 0.21–1.0) and flow rate (up to 60 L/min) [9]. This device has also demonstrated more physiologic benefits than LFOS. For example, it can wash out PaCO₂ in an anatomical dead space and create a positive nasopharyngeal pressure that, in theory, consequently prevents alveolar collapse and increases lung volume [10,11]. Also, contrary to the dry oxygen supply, heated and humidified gas improves mucociliary function [9]. In addition, in comparison with NIV, which requires a sealed interface, HFNC has a more comfortable nasal cannula capable of allowing expectoration of sputum, so it can be used widely among both general and critically ill patients [5,6].

To ensure that these benefits are helpful after extubation, many studies have been conducted but have presented mixed results [4-6,12-16]. In low-risk patients, a large-scale study comparing HFNC with LFOS proved effective, but there was no obvious conclusion in the high-risk group.

Therefore, in this retrospective study, we tried to show the current status of HFNC use in the clinical setting and evaluate the efficacy of HFNC in PERF and reintubation in high-risk patients. Physiologic changes according to time were also analyzed to determine whether the benefit of HFNC plays a physiologic role in postextubation.

MATERIALS AND METHODS Study Design and Populations

This was a retrospective study conducted in an ICU of a single center at Konyang University Hospital, Daejeon, Korea. The medical records of 855 patients who were admitted to the ICU and received mechanical ventilator therapy between November 2011 and March 2017 were reviewed. Seven hundred thirty-six patients were ultimately removed due to the study exclusion criteria (Figure 1). Patients who had at least one high-risk factor (e.g., age older than 65 years, body mass index higher than 30 kg/m², Acute Physiologic and Chronic Health Evaluation (APACHE) II score greater than 12 points, duration of mechanical ventilation greater than 7 days, Charlson comorbidity index of 2 points or more, heart failure as a cause of intubation, moderate to severe chronic obstructive pulmonary disease (COPD), failure with first spontaneous breathing trial (SBT) were defined as high-risk patients for PERF and reintubation according to a previous study [6]. One patient who did not have any such risk factors was also excluded (Figure 1). Consequently, 118 patients were included in this study, 84 of whom had undergone HFNC, and the other 34 of whom had undergone conventional LFOS.

A physician evaluated the patient status each day and determined the possibility of extubation by awakening and a SBT according to the weaning protocol of the ICU of Konyang University Hospital. After and during the extubation, adjunctive O₂ supply (HFNC or LFOS) was provided. HFNC was delivered by the Optiflow system or Airbo-2 (Fisher & Paykel Healthcare, Auckland, New Zealand). The supplied FiO₂ and gas flow were operated and controlled by a bedside physician according to the patient’s conditions, respiratory effort, target oxygenation, and arterial blood gas analysis. After extubation, the patient’s condition was evaluated in terms of respiratory discomfort, arterial blood gas, and vital signs. When PERF occurred, reintubation was determined by the bedside physician. This study was approved by the Institutional Review Board of Konyang University Hospital (IRB No. 2017-11-006).

Data Collection

Data were collected from the medical records including the general characteristics of the patients, the cause of respiratory failure, arterial blood gas analysis findings, vital signs before intubation and after extubation, ventilator period, and interval to reintubation. PERF was defined according to three categories: hypercapnic respiratory failure (pH <7.35 and PaCO₂ >45 mmHg), hypoxic respiratory failure (PaO₂ <60 mmHg), and tachypneic respiratory failure (respiratory rate >35 breaths/min). Reintubation was also classified into three groups: early reintubation (reintubation in 72 hours after extubation), delayed reintubation (reintubation between 72 hours and 168 hours after extubation), and nonreintubation (no occurrence of reintubation up to 168 hours after extubation).

Statistical Analysis

Categorical and noncategorical variables are expressed as number (percentage) and median (25th–75th, interquartile range). Fisher exact test or the chi-square test was used to compare the categorical variables, and the Mann-Whitney U-test was used for comparisons of noncategorical variables. Changes in PaO₂/FiO₂, PaCO₂, respiratory rate, and heart rate according to time were analyzed using the Friedman test. Post-hoc analysis of the Friedman test was conducted using the Wilcoxon rank-sum test when the Freidman test showed significance. A P-value less than 0.05 was considered statically significant. The IBM SPSS ver. 22.0 (IBM Corp., Armonk, NY, USA) was used for data analysis.

RESULTS Baseline Characteristics of the Enrolled Patients

The baseline characteristics of 118 patients suitable for this study are presented in Table 1. The cause of invasive mechanical ventilation and the APACHE II score did not differ between the groups. However, there were differences in underlying disease and high-risk factors. Patients who had more baseline neurologic diseases (32.1% vs. 11.8%, P=0.023), a long duration of mechanical ventilation before extubation (median, 120.3 vs. 81.93 hours; P=0.012), and longer hospital stay before extubation (median, 7.5 vs. 4.5 days; P=0.005) were more likely to be supported by HFNC. The HFNC group also showed a lower baseline PaO₂/FiO₂ versus the LFOS group (130.78 vs. 255.71 mmHg, P=0.001) and a higher baseline alveolar–arterial oxygen difference (183.25 vs. 56.12, P=0.003). Patients with certain high-risk factors such as age older than 65 years (77.4% vs. 58.8%; P=0.042) and moderate to severe COPD (19.0% vs. 0%; P=0.005) were more frequently found in the HFNC group.

The baseline laboratory findings in the two groups were also analyzed (Supplementary Table 1). In the baseline laboratory findings before intubation, a high neutrophil fraction (80.50% vs. 73.70%, P=0.045), high potassium level (4.15 vs. 3.76 mmol/L, P=0.003), and low calcium concentration (8.44 vs. 8.83 mmol/L, P=0.032) were shown in the HFNC group. Low albumin at extubation was also observed in the HFNC group (2.77 vs. 3.00 g/dl, P=0.010).

Results of Extubation: PERF and Reintubation

The occurrences of reintubation and PERF were analyzed (Table 2). The early reintubation rate was eight of 84 (9.5%) and three of 34 (8.8%), respectively (P=1.000). The occurrences of all types of respiratory failures in both groups were 21 of 84 (25.0%) and 11 of 34 (32.4%), respectively (P=0.416). Subanalysis according to subtype of respiratory failure also did not show any statistical difference (Table 2). Hypoxic and hypercapnic respiratory failure occurred in seven of 84 (8.3%) and two of 84 (2.4%) patients in the HFNC group, respectively, and in four of 34 (11.8%) and three of 34 (8.8%) patients in the LFOS group.

In the additional analysis carried out during 168 hours, seven patients in the HFNC group had progressed to reintubation but showed no statistical difference in comparison with the LFOS group. The delayed reintubation rate was seven of 76 (9.2%) and none of 31, respectively (P=0.105). Occurrence of any type of respiratory failure in 48 hours in those who received HFNC was higher in the early reintubation group (6/8, 75.0%) and delayed reintubation group (4/7, 57.1%) versus the nonreintubation group (11/69, 15.9%; P=0.000). Time to reintubation, in-hospital mortality rate, and tracheostomy rate did not show a statistical difference between the two groups (Table 2). The hospital stay of the HFNC group was longer than that of the LFOS group (27.5 vs. 14.50 days; P=0.001).

Physiologic Effects of HFNC after Extubation

To elucidate the physiologic effects of HFNC on heart rate, respiratory rate, PaO₂/FiO₂, and PaCO₂ compared with LFOS, patient vital signs and arterial blood gas after extubation were analyzed according to time. Prior to extubation, baseline heart rate, respiratory rate, PaCO₂, and PaO₂/FiO₂ were not significantly different between the groups (Figure 2, Supplementary Table 2).

Heart rate during the SBT and at 1 hour after extubation was higher in the HFNC group (Mann-Whitney U-test, P=0.014 in SBT and P=0.018 at 1 hour after extubation extubation) . Compared with heart rate in SBT, the heart rate stabilized after 24 hours in the HFNC group (Friedman test, χ²= 27.033, P=0.000; Mann-Whitney U-test, P=0.001 at 24 hours after extubation and P=0.001 at 48 hours after extubation). No statistically significant difference was found in respiratory rate, PaCO₂, and PaO₂/FiO₂ between each time compared with the parameters during the SPT.

Predictors for Reintubation and Delayed Reintubation in the HFNC Group

Variables including underlying disease, cause of mechanical ventilation, and high-risk factors were analyzed to determine the risk factors that influence reintubations (Table 3). No risk factors were found except longer hospital stay before extubation (9.00 [8.00–14.00] vs. 6.00 [4.00–10.00], P=0.036). There was no difference in the type of respiratory failure at intubation in the HFNC group. Although there was no significant difference, hypoxemic respiratory failure was more frequently found in the nonreintubation group versus the reintubation group (22/69 [31.9%] vs. 1/15 [6.7%], P=0.058).

To find the cause of delayed reintubation in the HFNC group, multiple variables were analyzed between the delayed reintubation group and nonreintubation group (Supplementary Table 3). There was no difference among these groups except more frequent basement renal disease (3/7 [42.9%] vs. 7/69 [10.1%], P=0.044) in the delayed-reintubation group.

DISCUSSION

An obvious benefit of HFNC in the context of the prevention of PERF and reintubation versus in the LFOS group at 72 hours after extubation was not observed in high-risk patients. Regarding physiologic aspects, HFNC might have helped to stabilize the heart rate, but no effect on stabilization of the respiratory rate, PaCO₂, and PaO₂/FiO₂ was noted.

Contrary to the recent meta-analysis and several other articles that reported the superiority of HFNC over LFOS after extubation, in this study, no significant benefits were observed in preventing PERF and reintubation [4,17,18]. However, the results of previous studies cannot be generalized due to the limited constitution of study populations (Table 4) [4,17,18].

In postsurgical patients, HFNC has continued to show a benefit over LFOS after extubation [13,14,16]. However, it is not generalized to nonsurgical patients. Only three previous studies directly compared HFNC and LFOS in medical patients and presented confusing results (Table 4) [4,12,15]. Hernández et al. [4] showed a low PERF ratio and low reintubation rate in HFNC versus conventional LFOS in low-risk patients after extubation. However, this group did not compare the HFNC to LFOS in high-risk patients directly. Fernandez et al. [12] studied the efficacy of HFNC in high-risk patients who suffered from nonhypercapnic respiratory failure versus conventional LFOS but reported inconclusive results due to low recruitment. The other study conducted by Song et al. [15] in acute respiratory failure patients with mixed risk also failed to prove the protection of reintubation. In conclusion, according to the literature review, HFNC after extubation as adjunctive oxygen therapy in low-risk or postsurgical patients might be effective, but there is no conclusion regarding high-risk patients.

In our study, physicians preferred HFNC over LFOS in high-risk patients who were older than 65 years and had moderate to severe COPD and/or neurologic disease, which are wellknown risk factors for reintubation [19]. HFNC is also more likely to be applied in patients with a high baseline alveolar–arterial oxygen difference that implies impaired gas exchange and in those with longer ventilator duration before extubation, which is a risk factor for reintubation [1,20]. For these reasons, it is worth noting that similar PERF and reintubation ratios were shown in the HFNC patients who had more risk factors.

In the previous two studies, HFNC stabilized the respiratory rate and improved the oxygenation [15,21,22]. In the previous study by Frat et al. [22], in acute respiratory failure, HFNC is related to reduced mortality and low reintubation in severe hypoxemia patients (PaO₂/FiO₂ <200 mmHg) compared with standard oxygen and NIV. The authors [22] insisted that this effect originates from a reduction in work of breathing and improvement of gas exchange. However, these effects were not found in this study. The initial lower PaO₂/FiO₂ and high alveolar–arterial oxygen gradient in the HFNC group could explain these unfavorable results. Similar to previous studies, no reduction of PaCO₂ was observed here [4,12,15]. This result differs from that in some other reports, which showed reduction in vitro and in other clinical situations, except for extubation. Therefore, PaCO₂ reduction may not be expected generally in the use of HFNC after extubation.

In this study, patients who received HFNC had lower PaO₂/FiO₂ versus those who received LFOS. Although not statistically significant, considering the more frequent preintubation hypoxemic respiratory failure in the nonreintubation group, which was expected to be improved by HFNC and have no effect on respiratory rate and PaCO₂, HFNC may play a role more in in nonhypercapnic respiratory failure than ventilatory failure after extubation.

To determine who will obtain a benefit from HFNC after extubation in high-risk patients, a subanalysis was performed. Longer hospital stay before extubation, which reflects the possibility of poor patient condition, might be linked with a higher risk for reintubation.

Although no statistical difference was shown in time to reintubation and time to respiratory failure, it is worth noting that a tendency of delayed reintubation was shown in the HFNC group like in previous research [5,12]. The reason for the tendency of delayed reintubation in our study is not clear. In subanalysis, when considering the risk factors for delayed reintubation, there was no significant difference except in basement renal disease between the delayed-reintubation group and non-reintubation group. Considering that more than 50% of patients in the delayed-reintubation group already suffered respiratory failure within 48 hours, there is a possibility of a physician’s hesitancy to complete early reintubation due to an expectation about HFNC’s stabilizing effect. Also, there is the possibility of HFNC hiding the aggravation of PERF, resulting in erroneous determination of extubation success. Further evaluation is needed to clarify this undesirable complication.

Our study has several strengths. First, compared with the previous studies that only included limited characteristics [4,12], the patients in this study had more diverse characteristics including hypercapnic respiratory failure. Second, in this study, we provided information about the physiologic changes and serial arterial blood gas analysis findings after extubation with a longer duration than in the previous studies. Therefore, we can better comment on the long-term effects of HFNC after extubation. Third, due to the nature of retrospective studies, this study reflects a real-world situation without artificial interventions.

This study also has some limitations. First, due to the study design (single-center, retrospective investigation), confounding factors and bias may be present. Furthermore, important information including parameters of the mechanical ventilator that were unrecorded in the medical record could not be analyzed. For this reason, the well-known predictors for PERF and reintubation including rapid shallow breathing index, maximal inspiratory pressure, and modified burns wean assessment program outcomes could not be analyzed [23]. Second, we only compared HFNC to LFOS and did not compare it to NIV. To clarify the benefit of HFNC on postextubation, especially in high-risk patients, additional study including NIV is necessary. Third, the number of study participants and reintubation rates are too small to show statistical significance. The findings on who receives benefit from HFNC and who will progress to delayed reintubation cannot be deemed statistically significant due to the small number of study participants.

In conclusion, no difference was observed in the PERF and reintubation ratios between the HFNC and LFOS groups at 72 hours after extubation. It is better to understand HFNC after extubation does not work than to do further prospective randomized controlled studies to clarify this efficacy and concern in high-risk patients. Caution is needed due to the tendency of delayed reintubation of the HFNC group. In terms of physiologic aspects, HFNC after extubation might be linked to stabilization of the heart rate after extubation.

HIGHLIGHTS

▪ In high-risk patients, no difference was found in occurrence of postextubation respiratory failure (PERF) and reintubation between the high-flow nasal cannula (HFNC) and low-flow oxygen system groups.

▪ Physicians preferred applying HFNC in riskier patients. It is worth noting that similar PERF and reintubation ratios were shown in the HFNC patients with more risk factors versus less.

▪ When implementing HFNC in high-risk patients, caution is needed due to the possibility of delayed reintubation.

No potential conflict of interest relevant to this article was reported.

AUTHOR CONTRIBUTIONS

Conceptualization: SJK. Data curation: ML. Formal analysis: ML. Methodology: SJK. Visualization: ML. Writing - original draft: ML. Writing - review & editing: JHK, IBJ, JWS, MJN, SJK.

SUPPLEMENTARY MATERIALS

The online-only supplement data are available with this article online: https://doi.org/10.4266/acc.2018.00311.

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Figures and Tables Figure 1.

Study design and population. In 855 patients who experienced mechanical ventilator use during the analyzed periods, 737 who matched the exclusion criteria and/or who did not have risk factors were excluded. Finally, 118 patients were included and analyzed retrospectively. HFNC: high-flow nasal cannula; LFOS: low-flow oxygen system.

Figure 2.

Physiologic parameters after extubation. (A) Heart rate. (B) Respiratory rate. (C) Arterial partial pressure of carbon dioxide (PaCO₂). (D) The ratio of arterial oxygen partial pressure to fractional inspired oxygen (PaO₂/FiO₂). LFOS: low-flow oxygen system; HFNC: high-flow nasal cannula; SBT: spontaneous breathing trial. ^aStatically significant difference between SBTs at each time after extubation; ^bStatically significant difference between HFNC and LFOS at the same time.

Table 1.

Baseline characteristics of analyzed patients before intubation

Characteristics	HFNC (n=84)	LFOS (n=34)	P-value
Male sex	60 (71.4)	20 (58.8)	0.184
Age (yr)	73.0 (66.0–80.0)	71.00 (55.75–81.25)	0.454
Height (cm)	163.5 (158.0–170.0)	155.50 (160.00–169.50)	0.248
Body weight (kg)	56.65 (50.0–68.0)	58.00 (52.00–65.00)	0.983
Body mass index (kg/m²)	22.0 (18.8–24.5)	23.11 (19.44–24.92)	0.703
Underlying disease
Diabetes mellitus	19 (22.6)	6 (17.6)	0.549
Hypertension	31 (36.9)	12 (35.3)	0.869
Malignant disease	10 (11.9)	4 (11.8)	1.000^a
Chronic respiratory disease	47 (56.0)	15 (44.1)	0.244
Chronic heart disease	22 (26.2)	7 (20.6)	0.522^a
Chronic liver disease	1 (1.2)	0	1.000^a
Chronic renal disease	11 (13.1)	3 (8.8)	0.755^a
Neurologic disease	27 (32.1)	4 (11.8)	0.023
Cause of mechanical ventilation
Pneumonia	45 (53.6)	19 (55.9)	0.819
Airway disease	13 (15.5)	3 (8.8)	0.119
Hemoptysis	3 (3.6)	1 (2.9)	1.000^a
Drug intoxication	14 (16.7)	10 (29.4)	0.119
Post operation	2 (2.4)	0	1.000^a
Heat failure	3 (3.6)	0	0.556^a
Others	4 (4.8)	1 (2.9)	1.000^a
Type of respiratory failure at intubation^b
Tachypneic respiratory failure	6 (7.1)	2 (5.9)	1.000^a
Hypercapnic respiratory failure	38 (45.2)	12 (35.3)	0.322
Hypoxic respiratory failure	23 (27.4)	6 (17.6)	0.266^a
Others^c	22 (26.2)	14 (41.2)	0.109
Severity index
APACHE II score at ICU admission	22.0 (18.00–25.00)	22.00 (19.00–25.25)	0.466
APACHE II score at extubation	17.0 (14.0–19.0)	16.50 (14.00–19.00)	0.466
Vital sign and arterial blood gas before intubation
Heart rate	100.00 (85.00–120.00)	107.50 (85.75–121.00)	0.861
Respiratory rate	22.00 (18.00–27.50)	22.00 (18.75–27.25)	0.696
PaCO₂ (mmHg)	41.75 (31.72–60.97)	39.15 (32.15–53.55)	0.671
PaO₂/FiO₂ (mmHg)	130.78 (83.76–259.29)	255.71 (200.05–320.44)	0.001
(A–a) DO₂	183.25 (50.71–412.68)	56.12 (21.37–166.99)	0.003
Vital sign and arterial blood gas before extubation
Heart rate on ventilation	84.50 (74.25–101.75)	85.00 (68.00–90.25)	0.198
Respiratory rate on ventilation	18.00 (16.00–21.00)	17.00 (15.00–20.00)	0.155
PaCO₂ on ventilation (mmHg)	34.75 (30.05–40.35)	34.40 (28.70–36.15)	0.051
PaO₂/FiO₂ on ventilation (mmHg)	288.00 (208.31–363.81)	333.75 (279.37–379.37)	0.069
(A-a) DO₂ at spontaneous breathing trial	138.71 (95.60–167.74)	130.20 (88.29–130.20)	0.478
High risk patient
Age older than 65 years	65 (77.4)	20 (58.8)	0.042
Body mass index higher than 30 kg/m²	7 (8.3)	2 (5.9)	1.000^a
Ventilator duration more than 7 days	30 (35.7)	7 (20.6)	0.109
Charlson comorbidity index of 2 or more	33 (39.3)	7 (20.6)	0.052
APACHE II score of more than 12	80 (95.2)	32 (94.1)	0.802
Heart failure as a cause of intubation	3 (3.6)	0	0.556^a
Moderate to severe COPD	16 (19.0)	0	0.005^a
Failure with first SBT trial	52 (61.9)	17 (50.0)	0.235
Duration of mechanical ventilation before extubation (hr)	120.3 (74.9–213.8)	81.93 (47.45–139.09)	0.012
Hospital day before extubation trial (day)	7.5 (4.00–10.75)	4.5 (3.00–7.25)	0.005

Values are presented as number (%) or median (interquartile range).

HFNC: high-flow nasal cannula; LFOS: low-flow oxygen system; APACHE: Acute Physiologic and Chronic Health Evaluation; ICU: intensive care unit; PaCO₂: arterial partial pressure of carbon dioxide; PaO₂/FiO₂: ratio of arterial oxygen partial pressure to fractional inspired oxygen; (A–a) DO₂: alveolar–arterial oxygen difference; COPD: chronic obstructive pulmonary disease; SBT: spontaneous breathing trial.

Fisher exact test;

Type of respiratory failure can be classified according to each group, if it satisfies both criteria;

Respiratory failure that was not satisfy each criterion.

Table 2.

Clinical outcome after extubation between two groups

Variable	HFNC (n=84)	LFOS (n=34)	χ²	P-value
Reintubation
Early reintubation (in 72 hr)	8 (9.5)	3 (8.8)	-	1.000^a
Time to reintubation	10.41 (1.51–62.37)	5.00 (4.17–43.85)		0.838^b
Reintubation in 168 hr	15 (17.9)	3 (8.8)	1.528	0.216
Time to reintubation	69.00 (2.58–100.82)	5.00 (4.17–43.85)		0.260^b
Delayed reintubation (72–168 hr)	7/76c (9.2)	0/31^c	-	0.105^a
Postextubation respiratory failure
Hypoxia	7 (8.3)	4 (11.8)	-	0.727^a
Hypercapnia	2 (2.4)	3 (8.8)	-	0.143^a
Tachypnea	14 (16.7)	6 (17.6)	0.017	0.898
All types of respiratory failure	21 (25.0)	11 (32.4)	0.662	0.416
Clinical outcome
Tracheostomy	5 (6.0)	1 (2.9)	-	0.672^a
In hospital mortality	12 (14.3)	3 (8.8)	-	0.549^a
Hospital day	27.5 (16.0–49.7)	14.50 (9.0–31.0)	-	0.001^b

Values are presented as number (%) or median (interquartile range).

HFNC: high-flow nasal cannula; LFOS: low-flow oxygen system.

Fisher exact test;

Mann-Whitney U-test;

Number/total number.

Table 3.

Predictor for reintubation in HFNC group

Characteristics	Non-reintubation (n=69)	Reintubation (n=15)	P-value
Male sex	49 (71.0)	11 (73.3)	1.000^a
Age (yr)	74.0 (65.50–80.50)	72.00 (67.00–74.00)	0.245
Height (cm)	162.0 (158.0–170.0)	164.50 (160.00–165.00)	0.711
Body weight (kg)	58.0 (50.0–70.0)	55.30 (50.00–60.00)	0.656
Body mass index (kg/m²)	22.7 (18.7–24.9)	22.03 (19.59–23.44)	0.717
Underlying disease
Diabetes mellitus	15 (21.7)	4 (26.7)	0.736^a
Hypertension	25 (36.2)	6 (40.0)	0.784
Malignant disease	6 (8.7)	4 (26.7)	0.073^a
Chronic respiratory disease	40 (58.0)	7 (46.7)	0.424
Chronic heart disease	18 (26.1)	4 (26.7)	1.000^a
Chronic liver disease	1 (1.4)	0	1.000^a
Chronic renal disease	7 (10.1)	4 (26.7)	0.102^a
Neurologic disease	20 (29.0)	7 (46.7)	0.226^a
Cause of mechanical ventilation
Pneumonia	36 (52.2)	9 (60.0)	0.776
Airway disease	9 (13.0)	4 (26.7)	0.235^a
Hemoptysis	3 (4.3)	0	1.000^a
Drug intoxication	13 (18.8)	1 (6.7)	0.447^a
Post operation	2 (2.9)	0	1.000^a
Heat failure	3 (4.3)	0	1.000^a
Others	3 (4.3)	1 (6.7)	0.552^a
Type of respiratory failure at intubation^b
Tachypneic respiratory failure	5 (7.2)	1 (6.7)	1.000^a
Hypercapnic respiratory failure	31 (44.9)	7 (46.7)	0.902
Hypoxic respiratory failure	22 (31.9)	1 (6.7)	0.058^a
Others^c	15 (21.7)	7 (46.7)	0.058^a
Severity index
APACHE II score at ICU admission	22.0 (17.50–25.00)	22.00 (19.00–25.00)	0.516
APACHE II score at extubation	17.0 (15.0–19.0)	16.00 (13.00–22.00)	0.541
Vital sign and arterial blood gas before intubation
Heart rate	100.00 (84.00–124.50)	101.00 (88.00–118.00)	0.820
Respiratory rate	22.00 (18.00–26.00)	22.00 (18.00–28.00)	0.977
PaCO₂ (mmHg)	44.90 (30.50–60.95)	38.60 (32.00–86.00)	0.356
PaO₂/FiO₂ (mmHg)	131.97 (86.90–256.19)	120.86 (80.12–291.90)	0.907
(A–a) DO₂	186.97 (48.71–411.96)	179.53 (50.43- 465.58)	0.532
Vital sign and arterial blood gas before extubation
Heart rate on ventilation	82.00 (73.50–101.00)	87.00 (76.00–109.00)	0.272
Respiratory rate on ventilation	18.00 (16.00–21.00)	18.00 (15.00–20.00)	0.366
PaCO₂ on ventilation (mmHg)	34.60 (30.50–40.30)	35.40 (27.70–46.80)	0.717
PaO₂/FiO₂ on ventilation (mmHg)	286.75 (215.62–361.00)	321.00 (165.75–400.00)	0.939
(A–a) DO₂ at spontaneous breathing trial	143.62 (110.02–166.10)	123.42 (92.25–178.92)	0.640
High risk patient
Age older than 65 years	53 (76.8)	12 (80.0)	1.000^a
Body mass index higher than 30 kg/m²	6 (8.7)	1 (6.7)	1.000^a
Ventilator duration more than 7 days	22 (31.9)	8 (53.3)	0.116
Charlson comorbidity index of 2 or more	26 (37.7)	7 (46.7)	0.518^a
APACHE II score of more than 12	66 (95.7)	14 (93.3)	0.552^a
Heart failure as a cause of intubation	3 (4.3)	0	1.000^a
Moderate to severe COPD	15 (21.7)	1 (6.7)	0.282^a
Failure with first SBT trial	40 (58.0)	12 (80.0)	0.111
Duration of mechanical ventilation before extubation (hr)	117.15 (70.71–210.29)	181.46 (82.83–273.66)	0.197
Hospital day before extubation trial (day)	6.00 (4.00–10.00)	9.00 (8.00–14.00)	0.036

Values are presented as number (%) or median (interquartile range).

HFNC: high-flow nasal cannula; APACHE: Acute Physiologic and Chronic Health Evaluation; ICU: intensive care unit; PaCO₂: arterial partial pressure of carbon dioxide; PaO₂/FiO₂: ratio of arterial oxygen partial pressure to fractional inspired oxygen; (A–a) DO₂: alveolar–arterial oxygen difference; COPD: chronic obstructive pulmonary disease; SBT: spontaneous breathing trial.

Fisher exact test;

Type of respiratory failure can be classified according to each group, if it satisfies both criteria;

Respiratory failure that was not satisfy each criterion.

Table 4.

Literature review for previous studies comparing HFNC to other oxygen delivery devices after extubation

Study	Study’s characteristics	Patient’s characteristics	Control	Reintubation	PERF	Physiologic aspect
Futier et al. [13]	Prospective RCT	Surgical patient after major abdominal surgery	LFOS	No difference	No difference	-
Dhillon et al. [16]	Retrospective	Critically ill surgical patient	LFOS	No difference^a	-	-
Yu et al. [14]	Prospective RCT	Surgical patient after thoracoscopic lobectomy	LFOS	Less reintubation in HFNC	Less hypoxemic respiratory failure in HFNC	Better oxygenation, reduction of respiratory rate in HFNC
Hernández et al. [6]	Prospective RCT	High risk	NIV	Not inferior in HFNC	Not inferior in HFNC	No difference
Yoo et al. [5]	Retrospective	Mixed risk	NIV	No difference	-	-
Maggiore et al. [3]	Prospective RCT	Mixed risk	LFOS^b	Less reintubation in HFNC	Less PERF in HFNC	Better oxygenation, reduction of respiratory rate in HFNC
Hernández et al. [4]	Prospective RCT	Low risk	LFOS	Less reintubation in HFNC	Less PERF in HFNC	No difference
Fernandez et al. [12]	Prospective RCT	Mixed risk, but include only hypercapnic patient	LFOS	No difference	No difference	-
Song et al. [15]	Prospective RCT	Mixed risk	LFOS	No difference	-	Better oxygenation, reduction of respiratory rate in HFNC
This study	Retrospective	High risk	LFOS	No difference	No difference	No difference^c

HFNC: high-flow nasal cannula; PERF: postextubation respiratory failure; RCT: randomized controlled trial; LFOS: low-flow oxygen system; NIV: noninvasive ventilation.

In multivariable analysis, HFNC is associated with a lower risk of reintubation;

This study only used the venturi mask as LFOS;

In this study, HFNC shows stabilization of the heart rate after extubation.