High-frequency Oscillatory Ventilation (HFOV) in Preterm Infants With Severe Respiratory Distress Syndrome (RDS)
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| ClinicalTrials.gov Identifier: NCT01496508 |
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Recruitment Status :
Completed
First Posted : December 21, 2011
Last Update Posted : December 21, 2011
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Sponsor:
Zhengzhou Children's Hospital, China
Information provided by (Responsible Party):
Changlian Zhu, Zhengzhou Children's Hospital, China
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Brief Summary:
Respiratory distress syndrome (RDS) is common in preterm infants born at less than 32 weeks gestation; surfactant and mechanical ventilation have been the standard treatment. However, despite advances in neonatal respiratory care, a considerable number of preterm infants develop chronic lung disease, termed bronchopulmonary dysplasia (BPD), which is associated with neonatal death, prolonged neonatal intensive care stay, and impaired neurodevelopment. High-frequency oscillatory ventilation (HFOV) was developed as a new ventilation technique in the late 1970s. It was expected to result in less BPD and death as a primary model of ventilation compared to conventional ventilation (CV) in the treatment of RDS. However, there is disagreement concerning the advantage of HFOV over CV in the treatment of RDS in preterm infants regarding the prevention of death, BPD, intraventricular hemorrhage, and periventricular leucomalacia in the short term. The purpose of this study was to compare the efficacy and safety of HFOV and CV in preterm infants with severe RDS.
| Condition or disease | Intervention/treatment | Phase |
|---|---|---|
| Respiratory Distress Syndrome | Device: mechanical ventilation (SLE 5000, Servo-i-Maquet) | Phase 2 |
All patients were monitored including blood pressure, heart rate, oxygen saturation, ventilator settings, and arterial blood gases pre- or during mechanical ventilation. PaO2/FIO2 was calculated. After 2 hours ventilation, if PaO2/FIO2 <200, patients were given rescue surfactant therapy (Curosurf 200mg/kg). A subsequent dose (100mg/kg) was administered when PaO2/FIO2 <200 12 hours after the previous dose. Surfactant was administered with use of in-line catheters. Suctioning was performed 6 hours after surfactant administration, except for some patients needed suction soon, with use of an in-line suction catheter. Ventilation continued during the administration of surfactant and suctioning.
| Study Type : | Interventional (Clinical Trial) |
| Actual Enrollment : | 360 participants |
| Allocation: | Randomized |
| Intervention Model: | Parallel Assignment |
| Masking: | Single (Outcomes Assessor) |
| Primary Purpose: | Prevention |
| Official Title: | Principal Investigator |
| Study Start Date : | June 2007 |
| Actual Primary Completion Date : | December 2009 |
| Actual Study Completion Date : | June 2011 |
Resource links provided by the National Library of Medicine
| Arm | Intervention/treatment |
|---|---|
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Experimental: HFOV
A SLE5000 infant ventilator was used as the high-frequency ventilator.HFOV setting were as follows: initial frequency was set between 11 and 15Hz; pressure amplitude of oscillation was initially adjusted to provide adequate chest wall movement and was subsequently titrated to maintain the PaCO2 between 40 and 55 mmHg.Extubation was considered when the patient's condition was stable for 12-24h, while adequate oxygenation could be maintained with an FIO2 <0.3 and respiratory rate <25/min.
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Device: mechanical ventilation (SLE 5000, Servo-i-Maquet)
Ventilation strategies for both groups were to emphasize lung recruitment and avoid atelectasis and over distention. The optimum lung volume was determined as expansion to 8 to 9.5 ribs for most infants, and 7 to 8 ribs for infants with air leak. HFOV setting were as follows: initial frequency was set between 11 and 15Hz; pressure amplitude of oscillation was initially adjusted to provide adequate chest wall movement and was subsequently titrated to maintain the PaCO2 between 40 and 55 mmHg; The initial mean airway pressure (MAP) was set at 8-10 cmH2O. MAP and FIO2 were set to maintain arterial oxygen saturation between 88 to 95%, an arterial pH of at least 7.25. Extubation was considered when MAP was ≤7 cmH2O and the pressure amplitude of oscillation reach 10 to 15 cmH2O.
Other Name: conventional mechanical ventilation |
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Experimental: CV
A Servo-i-Maquet will be used as the conventional mechanical ventilator. CV settings were: exhaled tidal volumes set at 5-6 mL/kg, initial peak inspiratory pressure (PIP) of 15-25 cmH2O; positive expiratory end pressure (PEEP) set to 4-6 cmH2O; inspiratory times of 0.25-0.40s; rates set to <60/min. The weaning process was initiated when the following parameters were achieved: PIP <18 cmH2O, PEEP <4 cmH2O, and FIO2 <0.4. Extubation was considered when the patient's condition was stable for 12-24h, while adequate oxygenation could be maintained with an FIO2 <0.3 and respiratory rate <25/min. All infants extubated onto nasal continuous positive airway pressure (Infant Flow, Electro Medical Equipment) and then weaned to a nasal cannula, and then to room air.
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Device: mechanical ventilation (SLE 5000, Servo-i-Maquet)
Ventilation strategies for both groups were to emphasize lung recruitment and avoid atelectasis and over distention. The optimum lung volume was determined as expansion to 8 to 9.5 ribs for most infants, and 7 to 8 ribs for infants with air leak. HFOV setting were as follows: initial frequency was set between 11 and 15Hz; pressure amplitude of oscillation was initially adjusted to provide adequate chest wall movement and was subsequently titrated to maintain the PaCO2 between 40 and 55 mmHg; The initial mean airway pressure (MAP) was set at 8-10 cmH2O. MAP and FIO2 were set to maintain arterial oxygen saturation between 88 to 95%, an arterial pH of at least 7.25. Extubation was considered when MAP was ≤7 cmH2O and the pressure amplitude of oscillation reach 10 to 15 cmH2O.
Other Name: conventional mechanical ventilation |
Primary Outcome Measures :
- Incidence of bronchopulmonary dysplasia [ Time Frame: defined as requirement of oxygen at 36 weeks of postmenstrual age ]To count the number of patients with bronchopulmonary dysplasia at 36 weeks of postmenstrual age.
Secondary Outcome Measures :
- duration of mechanical ventilation [ Time Frame: number of days on mechanical ventilation after birth to 36weeks of postmenstrual age ]To calculate how many days of the newborn baby with mechanical ventilation either HFOV or CV at 36 weeks postmenstrual age.
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| Ages Eligible for Study: | up to 24 Hours (Child) |
| Sexes Eligible for Study: | All |
| Accepts Healthy Volunteers: | No |
Criteria
Inclusion Criteria:
- Preterm infants admitted to the NICU with gestational age <32 weeks, birth weight <1500g and less than 24 hours of age
- Who developed RDS requiring mechanical ventilation
- Presented a partial pressure of oxygen (PaO2): fraction of inspired oxygen (FIO2) ratio <200
- Radiograph criteria of severe RDS
Exclusion Criteria:
- Infants with genetic metabolic diseases
- Congenital abnormalities
- Pneumothorax
- Grade III-IV intracranial hemorrhage
Information from the National Library of Medicine
To learn more about this study, you or your doctor may contact the study research staff using the contact information provided by the sponsor.
Please refer to this study by its ClinicalTrials.gov identifier (NCT number): NCT01496508
Locations
| China, Henan | |
| Zhengzhou Children's Hospital | |
| Zhengzhou, Henan, China, 450003 | |
Sponsors and Collaborators
Zhengzhou Children's Hospital, China
Investigators
| Study Director: | Hong Xiong, MD | Zhengzhou Children's Hospital |
Publications automatically indexed to this study by ClinicalTrials.gov Identifier (NCT Number):
| Responsible Party: | Changlian Zhu, Professor, Zhengzhou Children's Hospital, China |
| ClinicalTrials.gov Identifier: | NCT01496508 |
| Other Study ID Numbers: |
ZZ-HFOV |
| First Posted: | December 21, 2011 Key Record Dates |
| Last Update Posted: | December 21, 2011 |
| Last Verified: | December 2011 |
Keywords provided by Changlian Zhu, Zhengzhou Children's Hospital, China:
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high-frequency oscillatory ventilation respiratory distress syndrome preterm infants neurodevelopment preterm infants with severe respiratory distress syndrome |
Additional relevant MeSH terms:
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Respiratory Distress Syndrome Respiratory Distress Syndrome, Newborn Syndrome Disease Pathologic Processes |
Lung Diseases Respiratory Tract Diseases Respiration Disorders Infant, Premature, Diseases Infant, Newborn, Diseases |