High-flow Nasal Cannula In Patients Research Articles

High-Flow Nasal Cannula for Patients with COVID-19 Acute Hypoxemic Respiratory Failure

High-flow nasal cannula (HFNC) is a noninvasive oxygenation modality that delivers heated and humidified oxygen. It possesses several advantages due to the unique physiological effects on the lung and ventilation mechanics compared to other modes of oxygen therapy. The use of HFNC is tolerable, comfortable, and easy to set up. Current evidence indicates that the use of HFNC in critically ill patients with coronavirus disease 2019 (COVID-19)-acute hypoxemic respiratory failure (AHRF) is noninferior to noninvasive ventilation in the reduction of endotracheal intubation rate. Early identification of HFNC failure is vital to avoid delaying intubation. However, multiple knowledge gaps exist, and unpowered observational studies limit HFNC incorporation into strong recommendations. The low dispersion of particles demonstrates the feasibility of HFNC; yet, an appropriate setting and precautions should be maximized. Here, we review the recent evidence of HFNC implications in the management of patients with COVID-19-AHRF.

Reduction of PaCO2 by high-flow nasal cannula in acute hypercapnic respiratory failure patients receiving conventional oxygen therapy.

Background:It has been suggested that a high-flow nasal cannula (HFNC) could help to remove carbon dioxide (CO2) from anatomical dead spaces, but evidence to support that is lacking. The objective of this study was to elucidate whether use of an HFNC could reduce the arterial partial pressure of CO2 (PaCO2) in patients with acute hypercapnic respiratory failure who are receiving conventional oxygen (O2) therapy.Methods:A propensity score-matched observational study was conducted to evaluate patients treated with an HFNC for acute hypercapnic respiratory failure from 2015 to 2016. The hypercapnia group was defined as patients with a PaCO2 >50 mm Hg and arterial pH <7.35.Results:Eighteen patients in the hypercapnia group and 177 patients in the nonhypercapnia group were eligible for the present study. Eighteen patients in each group were matched by propensity score. Decreased PaCO2 and consequent pH normalization over time occurred in the hypercapnia group (P=0.002 and P=0.005, respectively). The initial PaCO2 level correlated linearly with PaCO2 removal after the use of an HFNC (R2=0.378, P=0.010). The fraction of inspired O2 used in the intensive care unit was consistently higher for 48 hours in the nonhypercapnia group. Physiological parameters such as respiratory rate and arterial partial pressure of O2 improved over time in both groups.Conclusions:Physiological parameters can improve after the use of an HFNC in patients with acute hypercapnic respiratory failure given low-flow O2 therapy via a facial mask. Further studies are needed to identify which hypercapnic patients might benefit from an HFNC.

Predictores de éxito del tratamiento con cánula nasal de alto flujo en el fallo respiratorio agudo hipoxémico

High-flow nasal cannula (HFNC) therapy is used in the treatment of acute respiratory failure (ARF) and is both safe and effective in reversing hypoxemia. In order to minimize mortality and clinical complications associated to this practice, a series of tools must be developed to allow early detection of failure. The present study was carried out to: (i)examine the impact of respiratory rate (RR), peripheral oxygen saturation (SpO2), ROX index (ROXI=[SpO2/FiO2]/RR) and oxygen inspired fraction (FiO2) on the success of HFNC in patients with hypoxemic ARF; and (ii)analyze the length of stay and mortality in the ICU, and the need for mechanical ventilation (MV). A retrospective study was carried out in the medical-surgical ICU of Hospital de Montilla (Córdoba, Spain). Patients diagnosed with hypoxemic ARF and treated with HFNC from January 2016 to January 2018 were included. Out of 27 patients diagnosed with ARF, 19 (70.37%) had hypoxemic ARF. Fifteen of them (78.95%) responded satisfactorily to HFNC, while four (21.05%) failed. After two hours of treatment, RR proved to be the best predictor of success (area under the ROC curve [AUROC] 0.858; 95%CI: 0.63-1.05; P=.035). For this parameter, the optimal cutoff point was 29rpm (sensitivity 75%, specificity 87%). After 8hours of treatment, FiO2 and ROXI were reliable predictors of success (FiO2: AUROC 0.95; 95%CI: 0.85-1.04; P=.007 and ROXI: AUROC 0.967; 95%CI: 0.886-1.047; P=.005). In the case of FiO2 the optimal cutoff point was 0.59 (sensitivity 75%, specificity 93%), while the best cutoff point for ROXI was 5.98 (sensitivity 100%, specificity 75%). Using a Cox regression model, we found RR<29rpm after two hours of treatment, and FiO2<0.59 and ROXI>5.98 after 8hours of treatment, to be associated with a lesser risk of MV (RR: HR 0.103; 95%CI: 0.11-0.99; P=.05; FiO2: HR 0.053; 95%CI: 0.005-0.52; P=.012; and ROXI: HR 0.077; 95%CI: 0.008-0.755; P=.028, respectively). RR after two hours of treatment, and FiO2 and ROXI after 8hours of treatment, were the best predictors of success of HFNC. RR<29rpm, FiO2<0.59 and ROXI>5.98 were associated with a lesser risk of MV.

Effects of flow rate on transnasal pulmonary aerosol delivery of bronchodilators via high-flow nasal cannula for patients with COPD and asthma: protocol for a randomised controlled trial

IntroductionBoth in vitro and in vivo radiolabelled studies on nebulisation via high-flow nasal cannula showed that inhaled dose decreases as the administered gas flow increases. In our previous in vitro...

High-flow nasal cannula oxygen therapy versus conventional oxygen therapy in patients after planned extubation: a systematic review and meta-analysis

BackgroundThe effect of high-flow nasal cannula (HFNC) therapy in patients after planned extubation remains inconclusive. We aimed to perform a rigorous and comprehensive systematic meta-analysis to robustly quantify the benefits of HFNC for patients after planned extubation by investigating postextubation respiratory failure and other outcomes.MethodWe searched MEDLINE, EMBASE, Web of Science, and the Cochrane Library from inception to August 2018. Two researchers screened studies and collected the data independently. Randomized controlled trials (RCTs) and crossover studies were included. The main outcome was postextubation respiratory failure.ResultsTen studies (seven RCTs and three crossover studies; HFNC group: 856 patients; Conventional oxygen therapy (COT) group: 852 patients) were included. Compared with COT, HFNC may significantly reduce postextubation respiratory failure (RR, 0.61; 95% CI, 0.41, 0.92; z = 2.38; P = 0.02) and respiratory rates (standardized mean differences (SMD), − 0.70; 95% CI, − 1.16, − 0.25; z = 3.03; P = 0.002) and increase PaO2 (SMD, 0.30; 95% CI, 0.04, 0.56; z = 2.23; P = 0.03). There were no significant differences in reintubation rate, length of ICU and hospital stay, comfort score, PaCO2, mortality in ICU and hospital, and severe adverse events between HFNC and COT group.ConclusionsOur meta-analysis demonstrated that compared with COT, HFNC may significantly reduce postextubation respiratory failure and respiratory rates, increase PaO2, and be safely administered in patients after planned extubation. Further large-scale, multicenter studies are needed to confirm our results.

A prospective randomized comparative study of high-flow nasal cannula oxygen and non-invasive ventilation in hypoxemic patients undergoing diagnostic flexible bronchoscopy.

Although oxygen supplementation during bronchoscopy in patients with pre-existing hypoxemia is provided, adequacy of oxygenation may not be achieved, resulting in the occurrence of respiratory failure that requires endotracheal tube intubation. The purpose of this study was to compare high-flow nasal cannula (HFNC) with non-invasive ventilation (NIV) in patients with pre-existing hypoxemia undergoing flexible bronchoscopy (FB) on the ability to maintain oxygen saturation during bronchoscopy. A prospective randomized study was conducted in patients who had hypoxemia [defined as partial pressure of arterial oxygen (PaO2) less than 70 mmHg at room air] and required FB for the diagnosis of abnormal pulmonary lesions. Patients were randomized to receive either HFNC or NIV during FB. The primary outcome was the lowest oxygen saturation level during FB. Fifty-one patients underwent randomization to HFNC (n=26) or NIV (n=25). Baseline characteristics in terms of age, Simplified Acute Physiologic Score II values, and cardiorespiratory parameters were similar in both groups. After receiving HFNC or NIV, oxygen saturation as measured by pulse oximeter (SpO2) increased to greater than 90% in all cases. During FB, although the lowest SpO2 was similar in both groups, the lowest SpO2 <90% tended to occur more often in the HFNC group (34.6% vs. 12.0%; P=0.057). In patients with baseline PaO2 <60 mmHg on ambient air, a decrease in PaO2 from preprocedure to the end of FB was less in the NIV group (-13.7 vs. -57.0 mmHg; P=0.019). After FB, the occurrence of SpO2 <90% was 15.4% and 4.0% in the HFNC group and NIV group, respectively (P=0.17). In overall, NIV and HFNC provided the similar effectiveness in prevention of hypoxemia in hypoxemic patients undergoing FB. However, in subgroup analysis, NIV provided greater adequacy and stability of oxygenation than HFNC in patients with baseline PaO2 <60 mmHg on ambient air.

Is high flow nasal cannula as an effective oxygen delivery alternative in intensive care unit?

Background: High-flow nasal cannula (HFNC) oxygen therapy is carried out using an air/oxygen blender, active humidifier, single heated tube, and nasal cannula. It is an oxygen delivery system which uses air blender to deliver accurate oxygen concentration to the patient from 21% to 100% at desired temperature. It can be administered via wide bore nasal cannula or to the tracheostomy tube via connector. It can give upto 60L/min flow hence can generate positive end expiratory pressure between 2 to 7 cmH20. By providing humidified oxygen along with the high flow rates it satisfies air hunger and reduces work of breathing for the patient.Methods: This is a retrospective observational study. Patients with persistent hypoxia in spite of conventional oxygen therapy were treated with HFNC. Patients with possible need for immediate invasive ventilator support were excluded. Clinical respiratory parameters and oxygenation were compared under conventional and HFNC oxygen therapy.Results: Thirty patients, aged more than 18 years admitted in intensive respiratory care unit with acute hypoxemic respiratory failure from June 2017 to January 2018 were included in the study. Study period was of 6 months. Etiology of acute respiratory failure (ARF) was mainly pneumonia (n = 17), interstitial lung disease (n = 5), bronchial asthma (n=3) and others (n = 5). There was statistically significant reduction in respiratory rate (29.40 before Vs 23.50 after; P- &lt;0.0001) and significant improvement in comfort level of the patient after HFNC therapy. Median duration of HFNC was 48 hrs (24-360) hours. Five patients were intubated later on and 4 died in the intensive care unit.Conclusions: Use of HFNC in patients with persistent ARF was associated with significant and sustained improvement of clinical parameters (respiratory rate). It can be used comfortably for prolonged periods.

Noninvasive approach for de novo acute hypoxemic respiratory failure: noninvasive ventilation, high-flow nasal cannula, both or none?

To summarize the recent evidence regarding the use of noninvasive strategies for de novo acute hypoxemic respiratory failure (AHRF). New guidelines for the use of noninvasive ventilation (NIV) in acute respiratory failure have been published. In parallel, high-flow nasal cannula (HFNC) is an emerging noninvasive strategy for AHRF patients. Although some have cautioned against the use of NIV in AHRF, new encouraging data about the use of a helmet interface for NIV in acute respiratory distress syndrome may overcome the limitations of facemask NIV. In the last two decades, the use of NIV and HFNC in patients with AHRF has considerably expanded, changing the paradigm of management of AHRF. Choice of each technique should be based according to centre experience and patient tolerability. However, when using noninvasive strategies for AHRF, it is crucial to predefine specific criteria for intubation and monitor patients closely for early detection of clinical deterioration to avoid delayed intubation.

Satisfactory use of high flow nasal cannula in a patient with acute pulmonary embolism

High Flow Nasal Cannula (HFNC) oxygen therapy is a recent technique that delivers a high flow of heated and humidified gas to the patient.1 Compared to noninvasive ventilation (NIV), HFNC has been proved to be an effective alternative treatment for acute respiratory failure. HFNC also has a significant number of physiological advantages compared with other commonly used oxygen-based therapies, including PEEP, reduced anatomical dead space, constant FiO2 and it is better tolerated than NIV.2 After a thorough bibliographical research, only one article was found assessing the benefits of using HFNC in patients with acute pulmonary embolism.3 We present the case of an 86-year-old patient with acute pulmonary embolism and desaturation refractory to noninvasive ventilation that was successfully treated with high flow therapy.

Application of high-flow nasal cannula in patients with critical respiratory disease

In recent years, high-flow nasal cannula is a relatively new type of oxygen therapy. It can not only regulate the constant oxygen concentration, provide low level positive airway pressure, reduce the dead cavity of nasopharynx, fully heat and humidified gas, but also can improve the airway mucosal clearance function and the comfort level of patients, so it has gained a good reputation among the medical staff. This article summarized the application of high-flow nasal cannula in patients with critical respiratory disease, and we hope that this article will be helpful for our colleagues. Key words: Review; High-flow nasal cannula; Critical respiratory disease

Preoxygenation with non-invasive ventilation versus high-flow nasal cannula oxygen therapy for intubation of patients with acute hypoxaemic respiratory failure in ICU: the prospective randomised controlled FLORALI-2 study protocol

IntroductionEndotracheal intubation in intensive care unit (ICU) is a procedure at high risk of life-threatening complications. Among them, severe oxygen desaturation, usually defined as a drop of pulse oxymetry (SpO2)...

CLINICAL EFFICACY OF HIGH‐FLOW NASAL CANNULA IN PATIENTS WITH ACUTE EXACERBATION OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE

RespirologyVolume 22, Issue S3 p. 185-185 APSR Poster Abstracts CLINICAL EFFICACY OF HIGH-FLOW NASAL CANNULA IN PATIENTS WITH ACUTE EXACERBATION OF CHRONIC OBSTRUCTIVE PULMONARY DISEASE First published: 23 November 2017 https://doi.org/10.1111/resp.13207_257Citations: 1Read the full textAboutPDF ToolsRequest permissionExport citationAdd to favoritesTrack citation ShareShare Give accessShare full text accessShare full-text accessPlease review our Terms and Conditions of Use and check box below to share full-text version of article.I have read and accept the Wiley Online Library Terms and Conditions of UseShareable LinkUse the link below to share a full-text version of this article with your friends and colleagues. Learn more.Copy URL Share a linkShare onFacebookTwitterLinkedInRedditWechat No abstract is available for this article.Citing Literature Volume22, IssueS3Supplement: 22nd Congress of the Asian Pacific Society of Respirology, International Convention Centre, Sydney, Australia, 23–26 November 2017November 2017Pages 185-185 RelatedInformation

Sorting Out the Mechanisms of Benefit of High Flow Nasal Cannula in Stable COPD.

Progressive dyspnea and exercise intolerance are common reasons why patients with severe chronic obstructive pulmonary disease (COPD) seek medical help.1 Patients with COPD have expiratory flow limitation that causes air trapping.2 Respiratory infections or environmental factors (seasonal change, poor air quality, etc.) can lead to increases in airway resistance and mucous production and complicate expiratory flow limitation, thus leading to worsened air trapping. Hyperinflation from air trapping has multiple negative physiologic consequences such as increased dyspnea, decreased exercise tolerance and worsened quality of life.3 Therapies that can reduce hyperinflation may improve respiratory symptoms as well as outcomes in patients with COPD. High flow nasal cannula (HFNC) has been shown to be an effective modality in treating critically ill patients with acute hypoxemic respiratory failure.4 Multiple reasons have been suggested to account for the benefits associated with HFNC and include improved oxygenation, reduced work of breathing, an increase in end expiratory lung volume, washout of nasopharyngeal dead space, altered breathing pattern and improved mucociliary clearance.5-7 Most of these mechanistic studies have been conducted using bench or animal models or healthy volunteers.8 Data regarding its use in patients with COPD, however, are limited and the mechanisms of potential benefit in this patient population are uncertain. In this issue, Atwood and colleagues provide important insight into the possible benefits associated with HFNC in patients with moderate to severe, stable COPD.9 They sequentially studied 32 patients with stable COPD treated with 1-2 L minute home oxygen, on no therapy and then subsequently randomly assigned them to HFNC and their prescribed level of low flow oxygen. HFNC reduced respiratory rates compared to the no therapy and low flow oxygen conditions without any increase in tidal volume or change in levels of arterial carbon dioxide. Oxygenation with HFNC was lower when compared to low flow oxygen but similar to the control. The reduction in ventilatory effort with HFNC with no change in carbon dioxide or oxygenation parameters suggests that HFNC purges the anatomic dead space of carbon dioxide and thereby improves ventilatory efficiency. These data support prior studies showing that HFNC reduces respiratory rate in COPD patients during hospitalization or performing exercise. However, these studies were limited because supplemental oxygen was also administered to treat concurrent moderate to severe hypoxemia.10,11 In this study, the use of HFNC independent of oxygen administration in stable COPD provides important information that washout of nasopharyngeal dead space results in a reduction in respiratory rate and stable oxygenation and carbon dioxide levels thus indicating an improved respiratory efficiency. Limitations of the study includes its short-term assessment period, lack of assessment of the add on effects of supplemental oxygen on gas exchange changes and no information on the benefits, if any, of enhanced humidification. Its strengths are that the population represented stable COPD and the opportunity to assess patients without supplemental oxygenation allowed the investigators to detail the impact of purging the conducting airway of carbon dioxide on improving ventilatory efficiency. HFNC may have important benefits for patients with COPD by improving gas exchange, decreasing breathlessness and improving exercise tolerance. To understand the clinical benefits that can be achieved due to these mechanistic effects, additional studies that explore the impact of long term use of HFNC on important clinical parameters such as exacerbation frequency, hospitalization, sleep quality and quality of life are needed.

Changes in arterial blood gases after use of high-flow nasal cannula therapy in the ED

IntroductionA high-flow nasal cannula (HFNC) has been used to treat patients with dyspnea. We identified changes in arterial blood gas (ABG) of patients visiting the emergency department (ED) with hypercapnic and nonhypercapnic respiratory failure after use of an HFNC. MethodsThis study was a retrospective chart review of patients with respiratory failure who visited the hospital and used an HFNC in the ED. The study period was July 1, 2011, to December 31, 2013. Patients with Paco2 greater than 45 mm Hg before the HFNC ABG analyses were included in the hypercapnia group; others comprised the nonhypercapnia group. Primary outcomes were the changes in ABG before and after use of an HFNC in the hypercapnia and nonhypercapnia groups. Progression to noninvasive or invasive ventilation and mortality rates were also assessed. ResultsA total of 173 patients were included after exclusion of 92 according to exclusion criteria. Eighty-one patients (hypercapnia group, 46, and nonhypercapnia group, 35) were included. Paco2 significantly decreased among all patients after use of HFNC (from 54.7 ± 26.4 mm Hg to 51.3 ± 25.8 mm Hg; P = .02), but the reduction was significant only in the hypercapnia group (from 73.2 ± 20.0 to 67.2 ± 23.4; P = .02). Progression to noninvasive or invasive ventilation and mortality rates were similar between the groups. ConclusionsUse of an HFNC in patients with hypercapnia could show a significant trend of decrease in Paco2. Progression to noninvasive or invasive ventilation and mortality rates were similar in patients with and without hypercapnia.

High-flow nasal cannula supportive therapy in chronic heart failure: Author's reply

We thank Dr Esquinas [1] for his interesting and constructive comments on our article [2]. We agree that the study has several limitations that should be borne in mind when interpreting the results. As we pointed out in the discussion, we think that variations not only in intrathoracic pressure but also in lung volume may be responsible for the changes observed in inferior vena cava collapse. Previousstudies have consistently reported animmediate reduction in the respiratory rate after initiating high-flow nasal cannula (HFNC) treatment[3-5]. However, one of them[4] alsodescribed a concomitant reduction in the heart rate (HR). Furthermore, this reduction was observed after 6 hours of treatment with HFNC in patients with a mean baseline HR above 100 beats/min. Patients included in those studies were severely hypoxemic and, consequently, may have presented strong sympathetic activation. Several variables may influence HR in severely hypoxemic patients, such as correction of hypoxemia or reduction of upper respiratory resistance and work of breathing. In contrast, we included patients with stable (nondecompensated) heart failure (HF) who were treated with β-blockers and had a median baseline HR value less than 60 beats/min [2]. Thus, in the present study, thesevariablesmayhavelimitedtheinfluenceofsympatheticactivation on the respiratory pattern. The increases reported in end-expiratory lung volume (EELV) [5,6] and the fact that reported values of PaCO2 in previous studies remained invariable before and during HFNC therapy [3,4,7]suggest that the decrease in respiratory rate is due to an increase in tidal volume. Finally, all patients included in our study had a stable respiratory pattern before, during, and after the study. Unfortunately, according to the study design, it is impossible to determine whether the changes observed were due to EELV, endexpiratory positive pressure, or both. We hypothesize that EELV may play amoreimportantrolethanend-expiratorypositivepressureintheresults

Use of high flow nasal cannula in critically ill infants, children, and adults: a critical review of the literature

High flow nasal cannula (HFNC) systems utilize higher gas flow rates than standard nasal cannulae. The use of HFNC as a respiratory support modality is increasing in the infant, pediatric, and adult populations as an alternative to non-invasive positive pressure ventilation. This critical review aims to: (1) appraise available evidence with regard to the utility of HFNC in neonatal, pediatric, and adult patients; (2) review the physiology of HFNC; (3) describe available HFNC systems (online supplement); and (4) review ongoing and planned trials studying the utility of HFNC in various clinical settings. Clinical neonatal studies are limited to premature infants. Only a few pediatric studies have examined the use of HFNC, with most focusing on this modality for viral bronchiolitis. In critically ill adults, most studies have focused on acute respiratory parameters and short-term physiologic outcomes with limited investigations focusing on clinical outcomes such as duration of therapy and need for escalation of ventilatory support. Current evidence demonstrates that HFNC generates positive airway pressure in most circumstances; however, the predominant mechanism of action in relieving respiratory distress is not well established. Current evidence suggests that HFNC is well tolerated and may be feasible in a subset of patients who require ventilatory support with non-invasive ventilation. However, HFNC has not been demonstrated to be equivalent or superior to non-invasive positive pressure ventilation, and further studies are needed to identify clinical indications for HFNC in patients with moderate to severe respiratory distress.