key: cord-0951390-31qluk68 authors: Veiga, Viviane Cordeiro; Silva, Lígia Maria Coscrato Junqueira; Sady, Érica Regina Ribeiro; Maia, Israel Silva; Cavalcanti, Alexandre Biasi title: Epistaxis as a complication of high-flow nasal cannula therapy in adults date: 2021 journal: Rev Bras Ter Intensiva DOI: 10.5935/0103-507x.20210090 sha: 36103f2a4da689ce96e86ae2c7bdf6e48e53535c doc_id: 951390 cord_uid: 31qluk68 nan High-flow nasal cannula (HFNC) therapy has emerged as a valuable therapy for adult patients with acute respiratory failure (1, 2) or to prevent postextubation respiratory failure. (3, 4) Currently, HFNC therapy is recommended in guidelines on the management of patients with coronavirus 2019 disease (COVID-19). (5) HFNC therapy delivers humidified and heated gas at a high flow that can exceed the patient's inspiratory demand of flow, contributing to alleviating breathlessness. (6) It promotes washout of the nasopharyngeal space, creating a pharyngeal reserve of fresh gas for subsequent inspiration. (7) These mechanisms result in improved oxygenation and reduced work of breathing. (8) Clinical complications of HFNC therapy have rarely been reported. (9) Some studies have described mild complaints, such as feeling too warm, unpleasant smell or thoracic discomfort. (9) Epistaxis is a rare adverse event associated with HFNC therapy in children. (10) However, HFNC-related epistaxis in adults has been reported only in one patient under higher than recommended flow (65L/min). (11) Here, we report 7 cases of epistaxis we observed in a series of 70 adults treated with HFNC therapy. Retrospective case series including all adult patients treated with HFNC therapy in the intensive care unit (ICU) over a 1-year period (September 2017 to October 2018). Indications for HFNC therapy were support to patients with acute respiratory failure or to prevent postextubation failure. The study was approved by the Research Ethics Committee of BP-A Beneficência Portuguesa de São Paulo. High-flow nasal cannula therapy was delivered via Precision Flow  (Vapotherm, Inc, Exeter, NH) using small-bore nasal cannulas, sizes 2.7mm and 4.8mm. Flow was initiated at 30L/ minute with adjustments up to 40L/minute aiming to reduce respiratory distress. The fraction of inspired oxygen (FiO 2 ) was adjusted to maintain peripheral oxygen saturation higher than 92%. The temperature was adjusted between 35°C and 37°C. Data were extracted from the electronic medical records of patients. We collected data on the following variables at ICU admission: age, sex, main diagnosis, comorbidities, severity of illness (Simplified Acute Physiology Score 3 -SAPS 3), Sequential Organ Failure Assessment (SOFA) score, and type of acute respiratory failure (hypoxemic or hypercapnic). We obtained the following data at the initiation of HFNC therapy: respiratory characteristics (the ratio of peripheral oxygen saturation -SpO 2 to FiO 2 , respiratory rate, and the ROX index -a ratio of SpO 2 /FiO 2 to respiratory ratio), HFNC therapy settings (FIO 2 , flow and temperature), and the results of selected laboratory tests (activated partial thromboplastin time -aPTT, prothrombin time -PT, and platelets). We collected data on the following clinical outcomes during the ICU stay: epistaxis, failure of HFNC, mortality and length of stay. A total of 70 patients were treated with HFNC therapy in this period (Table 1) . Seven patients (10%) developed epistaxis while on HFNC therapy. Median age was 67 years and 40% of patients were female. A HFNC was indicated for support in acute respiratory failure in 84% of cases. The distribution of diagnosis was apparently different between the patients with and without epistaxis (p = 0.02), with a lower prevalence of pneumonia and a higher prevalence of nonpulmonary sepsis in patients with epistaxis. The mean SAPS 3 score was 53.9 (standard deviation -SD 16.8), the mean SOFA score was 9.2 (SD 1.7), and 14 patients (20%) were on vasopressors, without statistically significant differences for these variables. There were no statistically significant differences between patients with and without epistaxis in platelet count and aPTT, Although International Normalized Ratio (INR) was slightly lower among patients with epistaxis (1.2 versus 1.3; p = 0.03). There were no statistically significant differences between patients with and without epistaxis in HFNC settings (flow, temperature and FiO 2 ) at initiation and at end of therapy (Table 2 ). There also were no differences in the duration of HFNC therapy. There were no statistically significant differences in the incidence of adverse clinical outcomes (need for mechanical ventilation, ICU and hospital mortality, as well as ICU and hospital length of stay) between patients with and without epistaxis ( Table 3 ). Significant epistaxis occurred in only one patient, and it requiring an epistaxis device (Rapid Rhino © ). Two other cases used topical epinephrine. There was no need for transfusion of blood products in any of the cases. We observed epistaxis as an adverse event occurring in 7 of 70 patients administered HFNC therapy. Reasons for using HFNC therapy were diverse, and none of the baseline characteristics of patients were associated with epistaxis. Initial and final HFNC settings were also not associated with epistaxis. However, the number of epistaxis events was small; therefore, our study has limited power to identify risk factors. In addition to this study, only one study by Velasco Sanz et al. (11) reported epistaxis in one adult from a series of 12 administered HFNC therapy. The authors attributed the adverse event to the high flow rate in use (65L/minute). In our study, the maximum flow rate was 40L/minute and was not different between patients with or without epistaxis. Baudin et al. (10) reported complications associated with the use of HFNC therapy in a retrospective observational study in critically ill children. Significant epistaxis occurred in only one patient, without identifying potential causes for the adverse event. Small-bore nasal cannulas promote faster purging of the extrathoracic dead space with lower flow rates than large-bore nasal cannulas. (12) This happens because of a smaller prong configuration at the tip that increases the velocity of the gas. A possible explanation for epistaxis is the jetting effect from the tip of the cannula, which could result in undue shear stress on the mucosal tissue of the airway. There are several limitations in this study. First, we reported a small case series with only 7 patients experiencing the outcome. Therefore, the precision around our incidence estimate is large. In addition, the study has limited power to identify risk factors for bleeding. Second, HFNC therapy was assessed in many clinical trials and case series involving hundreds of patients, with only 1 previous case of epistaxis being reported. Therefore, the true incidence of epistaxis among patients administered HFNC therapy is likely lower than the number (10%) we observed in our study. In conclusion, epistaxis is a possible complication related to the use of a high-flow nasal cannula. In our small study sample, none of the characteristics of patients or high -flow nasal cannula settings were associated with epistaxis. Effect of high-flow nasal oxygen vs standard oxygen on 28-day mortality in immunocompromised patients with acute respiratory failure: the HIGH randomized clinical trial High-flow oxygen through nasal cannula in acute hypoxemic respiratory failure Effect of postextubation high-flow nasal cannula vs noninvasive ventilation on reintubation and postextubation respiratory failure in high-risk patients: a randomized clinical trial Effect of postextubation high-flow nasal cannula vs conventional oxygen therapy on reintubation in low-risk patients: a randomized clinical trial Surviving Sepsis Campaign: Guidelines on the Management of Critically Ill Adults with Coronavirus Disease 2019 (COVID-19) High-flow nasal cannula oxygen in adults: an evidence-based assessment Research in high flow therapy: mechanisms of action Optimum support by high-flow nasal cannula in acute hypoxemic respiratory failure: effects of increasing flow rates High flow nasal cannula compared with conventional oxygen therapy for acute hypoxemic respiratory failure: a systematic review and meta-analysis Modalities and complications associated with the use of high-flow nasal cannula: experience in a pediatric ICU Computational fluid dynamics modeling of extrathoracic airway flush: evaluation of high flow nasal cannula design elements