Clinical Trials Logo

Clinical Trial Details — Status: Recruiting

Administrative data

NCT number NCT03788304
Other study ID # High flow nasal cannula
Secondary ID
Status Recruiting
Phase N/A
First received
Last updated
Start date May 1, 2019
Est. completion date December 1, 2020

Study information

Verified date October 2019
Source Assiut University
Contact Entsar H mohamed, MD
Phone +201019968106
Email dr.entsar_hsanen@yahoo.com
Is FDA regulated No
Health authority
Study type Interventional

Clinical Trial Summary

Oxygen therapy is first-line treatment in the management of acute respiratory failure (ARF). Different oxygen devices have become available over recent decades, such as low-flow systems (nasal cannula, simple facemask, non-rebreathing reservoir mask) and high-flow systems (Venturi mask) . Since the 90's, non-invasive ventilation (NIV) has been largely used with strong level of evidence in cardiogenic pulmonary edema and chronic obstructive pulmonary disease (COPD) exacerbation. NIV improves gas exchange and reduces inspiratory effort through positive pressure. However, good tolerance to NIV is sometimes difficult to achieve due to frequent leaks around the mask, possibly leading to patient-ventilator asynchrony and even to intubation . High-flow nasal oxygen therapy (HFNO) is an innovative high-flow system that allows for delivering up to 60 liters\ min of heated and fully humidified gas with a FIO2 ranging between 21% and 100% . It is a new method of respiratory support in adults that has been used in neonatal ARF for some years. The reason this study is necessary is because, even though NIV has been demonstrated to prevent endotracheal intubation (and its associated complications) in a broad range of ARF patients, HFNC has been proposed to have the same effect as NIV while being easier tolerated, more physiological , allowing patients to continue to talk, eat and drink through mouth while on HFNC


Description:

Oxygen therapy is the first-line treatment in management of acute respiratory failure (ARF). Different oxygen delivery devices have become available over recent decades, either low-flow systems (nasal cannula, simple facemask, non-rebreathing reservoir mask) or high-flow systems (Venturi mask) . The choice of a specific device in management of ARF is based on the severity of hypoxemia, the underlying mechanisms, the patient's breathing pattern and tolerance .

Critically ill patients often require high-flow devices to meet their oxygen needs . Tachypneic patients with ARF, have a peak inspiratory flow rate that is usually high and often exceeds the oxygen flow delivered by the traditional oxygen devices . Using conventional devices, oxygen flow is limited to no more than 15 L/min. Meanwhile, the required inspiratory flow for patients with respiratory failure varies widely in a range from 30 to120 L/min. The difference between patient inspiratory flow and delivered flow is large with conventional oxygen devices leading to patient discomfort . Moreover; high respiratory rate can generate significant entrainment of room air in the mask and dilution of the inspired oxygen with an insufficient oxygen concentration. The suboptimal humidification of the inhaled oxygen provided by standard bubble humidifiers and the limited and unknown inspiratory oxygen fraction (FIO2) delivery are additional drawbacks of these devices .

Since the 90's, noninvasive ventilation (NIV) has been largely used with strong level of evidence in cardiogenic pulmonary edema and chronic obstructive pulmonary disease (COPD) exacerbation. NIV improves gas exchange and reduces inspiratory effort through positive pressure. However, good tolerance to NIV is sometimes difficult to achieve due to frequent leaks around the mask, possibly leading to patient-ventilator asynchrony and even to intubation. It may have other deleterious effects such as delayed intubation by masking signs of respiratory distress, or barotrauma by the high tidal volume potentially generated under positive pressure .

To ensure good results, an appropriate interface is more important than the ventilation mode . Oronasal masks, nasal masks, and hoods are most commonly used for NIV. Oronasal masks are usually tried first because they ensure the effects of NIV better than other interfaces. Unfortunately, it is not comfortable, and many patients find it hard to tolerate. It is also associated with a relatively high incidence of air leakage. Also, skin lesions at the nose induced by long-term use of this device may result in frequent treatment interruptions and discontinuation.

High-flow nasal oxygen therapy (HFNO) is an innovative high-flow system that allows for delivering up to 60 liters/ min of heated and fully humidified gas with a FIO2 ranging between 21% and 100% [.

- HFNO delivery systems: main technical characteristics: - The administration of HFNO requires the following: high pressure sources of oxygen and air, an air-oxygen blender or a high-flow 'Venturi' system (which permits delivery of an accurate FIO2 between 21% and 100%), a humidifying and heating system for conditioning the gas to optimal temperature (37 ÂșC) and humidity (44mg H2O/ liters), a sterile water reservoir, a non-condensing circuitry, and an interface . The two most widely marketed HFNO systems are the Precision Flow by Vapotherm and Optiflow by Fisher & Pykel Healthcare Ltd.

- Physiological effects of HFNC: - Gas from an air/oxygen blender that can generate a total flow of up to 60 L/min is heated and humidified with an active humidifier and subsequently delivered through a heated circuit. High flow of adequately heated and humidified gas is considered to have a number of physiological effects

1. Washout of nasopharyngeal dead space: Washout of upper airway dead space from the delivery of a large amount of oxygen can improve the efficiency of ventilation and enhance oxygen delivery . HFNC is the only noninvasive respiratory support that does not increase dead space. With an oxygen mask, especially at low flow, carbon dioxide is rebreathed .

2. Warming and humidification of secretions: Warming of inspired oxygen and heating it to core temperature is more effective at high flow rates (typically >40 L/minute) than low flow rates. Thus, HFNC is better at heating and humidifying inspired oxygen than conventional high-flow systems such as Venturi masks or nonrebreathers (flow rate typically 10 to 15 L/minute) or low-flow systems (flow rates typically <10 L/minute) . Increased humidification results in increased water content in mucous, which can facilitate secretion removal and may also decrease the work of breathing and avoid airway desiccation and epithelial injury

3. Continuous positive airway pressure (CPAP) effect: Several studies in adults have shown that, similar to infants and neonates, HFNC increases nasopharyngeal airway pressure that peaks at the end of expiration (ie, "PEEP effect") . This "PEEP effect" can potentially unload auto-PEEP, decrease work of breathing, and enhance oxygenation in patients with alveolar filling diseases such as congestive heart failure or acute respiratory distress syndrome (ARDS). As flow increases, nasopharyngeal pressure increases (ie, a dose effect) . The CPAP effect is greatest with the mouth closed. In general, every increase of 10 L/minute of flow yields approximately 0.7 cm H2O of airway pressure when the mouth is closed and 0.35 cm of H2O when the mouth is open.

4. Small pliable nasal prongs: HFNC nasal prongs are generally soft and pliable. Consequently, several studies have reported improved patient comfort with HFNC when compared with conventional low-flow oxygen delivered through nasal cannula or high-flow oxygen delivered through a face mask .

5. High flow rates: High flow rates result in minimal entrainment of room air when HFNC is used; this results in more accurate delivery of oxygen. Patients in respiratory distress generate high inspiratory flow rates that exceed flow rates of standard oxygen equipment, resulting in entrainment of room air and a reduction in the delivery of the set FIO2. The rate of flow in HFNC generally exceeds that of the patient, entraining very little room air and resulting in an FIO2 that is more reliably delivered . High flow rates have also been shown to result in an improved breathing pattern by increasing tidal volume and decreasing respiratory rate .

6. Reduction of work of breathing: The HFNO system may significantly reduce the energy requirement (metabolic work) associated with gas conditioning. By providing high gas flows, HFNO reduces the resistance of the upper airway and then decreases the resistive breathing effort .


Recruitment information / eligibility

Status Recruiting
Enrollment 100
Est. completion date December 1, 2020
Est. primary completion date April 30, 2020
Accepts healthy volunteers No
Gender All
Age group 18 Years and older
Eligibility Inclusion Criteria:

- Participants admitted to the RICU with acute hypoxemic respiratory failure requiring NIV support with the following criteria:

1. RR> 25 breath/minute

2. Use of accessory muscles of respiration, paradoxical breathing, thoracoabdominal asynchrony.

3. Hypoxemia evidenced by PaO2 / FiO2 ratio <300

Exclusion Criteria:

Patients who have any of the following:

I. Indication for emergency endotracheal intubation. II. HR <50 beat\minute with decreased level of consciousness III. Persistent hemodynamic instability with

- Systolic blood pressure <90 mmHg after infusing a bolus of crystalloid solution at a dose of 30 ml / kg

- life-threatening arrhythmia. IV. Undrained pneumothorax or Pneumothorax with persistent air leak. V. Extensive facial trauma or burn VI. Refusal to participate. VII. Usual long-term treatment with NIV for chronic disease VIII. Altered mental status with decreased consciousness and/or evidence of inability to understand .

IX. Tracheotomy or other upper airway disorders X. Active upper gastrointestinal bleeding

Study Design


Related Conditions & MeSH terms


Intervention

Device:
non-invasive ventilation
conventional NIV
high flow nasal cannula
HFNC ventilation

Locations

Country Name City State
Egypt Assiut University hospital Assiut

Sponsors (1)

Lead Sponsor Collaborator
Assiut University

Country where clinical trial is conducted

Egypt, 

References & Publications (1)

1-Renda, T., Corrado, A., Iskandar, G., et al. High-flow nasal oxygen therapy in intensive care and anaesthesia . British journal of anaesthesia 2018 , 120(1), 18-27 2-Kallstrom TJ. AARC clinical practice guideline: oxygen therapy for adults in the acute care facility: 2002 revision and update. Respir Care 2002; 47: 717-20. 3-O'Driscoll BR, Howard LS, Davison AG, on behalf of the British Thoracic Society. BTS guideline for emergency oxygen use in adult patients. Thorax 2008; 63: 1-68. 4-Sim MA, Dean P, Kinsella J, et al. Performance of oxygen delivery devices when the breathing pattern of respiratory failure is simulated. Anaesthesia 2008; 63: 938-40 5-Nishimura, M. High-flow nasal cannula oxygen therapy in adults: physiological benefits, indication, clinical benefits, and adverse effects. Respiratory Care 2016, 61(4), 529-541.

Outcome

Type Measure Description Time frame Safety issue
Primary Endotracheal intubation rate. needs escalation to invasive mechanical ventilation one week
Secondary In hospital mortality. death one week
Secondary length of hospital stay hospital coast one week
Secondary duration of ICU stay icu occupancy one week
Secondary duration of intervention need ventilatory support one week
Secondary development of complications due to devices one week
See also
  Status Clinical Trial Phase
Completed NCT03909854 - Pragmatic Investigation of Volume Targeted Ventilation-1 N/A
Recruiting NCT03662438 - HOPE (Home-based Oxygen [Portable] and Exercise) for Patients on Long Term Oxygen Therapy (LTOT) N/A
Recruiting NCT05308719 - Nasal Oxygen Therapy After Cardiac Surgery N/A
Recruiting NCT05535543 - Change in the Phase III Slope of the Volumetric Capnography by Prone Positioning in Acute Respiratory Distress Syndrome
Completed NCT04030208 - Evaluating Safety and Efficacy of Umbulizer in Patients Requiring Intermittent Positive Pressure Ventilation N/A
Recruiting NCT04668313 - COVID-19 Advanced Respiratory Physiology (CARP) Study
Recruiting NCT04542096 - Real Time Evaluation of Dynamic Changes of the Lungs During Respiratory Support of VLBW Neonates Using EIT
Recruiting NCT05883137 - High-flow Nasal Oxygenation for Apnoeic Oxygenation During Intubation of the Critically Ill
Completed NCT04505592 - Tenecteplase in Patients With COVID-19 Phase 2
Completed NCT03943914 - Early Non-invasive Ventilation and High-flow Nasal Oxygen Therapy for Preventing Delayed Respiratory Failure in Hypoxemic Blunt Chest Trauma Patients. N/A
Active, not recruiting NCT03472768 - The Impact of Age-dependent Haptoglobin Deficiency on Plasma Free Hemoglobin Levels During Extracorporeal Membrane Oxygenation Support
Not yet recruiting NCT04538469 - Absent Visitors: The Wider Implications of COVID-19 on Non-COVID Cardiothoracic ICU Patients, Relatives and Staff
Not yet recruiting NCT02542423 - Endocan Predictive Value in Postcardiac Surgery Acute Respiratory Failure. N/A
Completed NCT02265198 - Relationship of Pulmonary Contusion to Pulmonary Inflammation and Incidence of Acute Respiratory Distress Syndrome N/A
Completed NCT02105298 - Effect of Volume and Type of Fluid on Postoperative Incidence of Respiratory Complications and Outcome (CRC-Study) N/A
Completed NCT01885442 - TryCYCLE: A Pilot Study of Early In-bed Leg Cycle Ergometry in Mechanically Ventilated Patients N/A
Completed NCT02814994 - Respiratory System Compliance Guided VT in Moderate to Severe ARDS Patients N/A
Completed NCT01659268 - Performance of Baccalaureate Nursing Students in Insertion of Laryngeal Mask: a Trial in Mannequins N/A
Completed NCT01249794 - Non Invasive Ventilation After Cardiac Surgery N/A
Completed NCT01204281 - Proportional Assist Ventilation (PAV) in Early Stage of Critically Ill Patients Phase 4