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Research ArticleOriginal Research

Continuous High-Frequency Oscillation Therapy in Invasively Ventilated Pediatric Subjects in the Critical Care Setting

Stephen Morgan, Christoph P Hornik, Niyati Patel, Walter L Williford, David A Turner and Ira M Cheifetz
Respiratory Care November 2016, 61 (11) 1451-1455; DOI: https://doi.org/10.4187/respcare.04368
Stephen Morgan
Respiratory Care Services, Duke University Hospital, Duke University Medical Center, Durham, North Carolina.
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Christoph P Hornik
Division of Pediatric Critical Care Medicine
Division of Quantitative Sciences, Department of Pediatrics, Duke Children's Hospital, Duke University Medical Center, Durham, North Carolina.
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Niyati Patel
Division of Pediatric Critical Care Medicine, Department of Pediatrics, University of Minnesota, Minneapolis, Minnesota.
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Walter L Williford
Respiratory Care Services, Children's Hospital of the King's Daughters, Norfolk, Virginia.
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David A Turner
Division of Pediatric Critical Care Medicine
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Ira M Cheifetz
Respiratory Care Services, Duke University Hospital, Duke University Medical Center, Durham, North Carolina.
Division of Pediatric Critical Care Medicine
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Abstract

BACKGROUND: Continuous high-frequency oscillation (CHFO) creates a pressure gradient in the small airways that accelerates expiratory flow. The intended use of CHFO therapy is to facilitate secretion removal and treat atelectasis. Our objective was to assess the feasibility, safety, and efficacy of CHFO in the mechanically ventilated pediatric population.

METHODS: After institutional review board approval, we retrospectively reviewed medical records of mechanically ventilated children treated with CHFO (the MetaNeb system) at our institution from July 1, 2007 through August 31, 2012. Patients supported with extracorporeal membrane oxygenation were excluded. We evaluated changes in ventilator settings in subjects with ventilator data documented within 6 h pre- and post-treatment. We evaluated arterial blood gas (ABG) results for individual treatments, comparing ABG results within 8 h pre-therapy to ABG results within 3 h post-treatment. Oxygen index and PaO2/FIO2 were calculated. Demographic data, blood pressure, heart rate, and development of new air leak while being treated with CHFO were recorded. Pre- and post-CHFO measurements were compared using Wilcoxon signed-rank testing.

RESULTS: Our cohort included 59 invasively ventilated subjects. Median age was 2 y (range 1 month to 19 y), and median weight was 14 kg (2–81 kg). We evaluated data on 528 total treatments (range per subject 1–39 treatments). Peak inspiratory pressure significantly decreased with CHFO, whereas other parameters, including PaCO2 and breathing frequency, remained stable. There was no significant change in systolic blood pressure, diastolic blood pressure, or heart rate following treatment with CHFO. One subject (2%) developed a clinically insignificant pneumothorax during CHFO.

CONCLUSIONS: CHFO is feasible and seems safe in our cohort of mechanically ventilated pediatric subjects. The rate of pneumothorax was consistent with that seen in similar pediatric ICU populations. These preliminary results suggest that CHFO may be beneficial by improving lung compliance in pediatric subjects with secretion-induced atelectasis. Prospective clinical studies are needed to further evaluate the clinical efficacy and safety of CHFO in children receiving invasive mechanical ventilation.

  • atelectasis
  • intrapulmonary percussive ventilation
  • mucociliary clearance
  • airway clearance
  • pediatric
  • gas exchange
  • mechanical ventilation

Introduction

As many as 10% of the estimated 115,000 mechanically ventilated infants and children in the United States each year develop atelectasis.1,2 Risk factors for atelectasis in ventilated neonatal and pediatric patients include small, collapsible airways, a compliant chest wall, and the absence of intra-alveolar and bronchoalveolar pores.3 Additional risk factors for atelectasis, which may be present in critically ill patients, include disruption of the mucociliary escalator and ineffective cough. These changes may lead to difficulty with secretion clearance that may cause airway obstruction and accumulation of secretions,4 potentially increasing the risk of ventilator-associated pneumonia.5 Inadequate secretion clearance can also create secondary areas of lung hyperexpansion. Untreated atelectasis and impaired mucociliary clearance may result in prolonged duration of mechanical ventilation and, ultimately, a prolonged pediatric ICU stay.

In an effort to potentially improve therapy for atelectasis, intrapulmonary percussive ventilation (IPV) was introduced in 1985 by Dr Forrest Bird as an alternative treatment for atelectasis and secretion clearance. Continuous high-frequency oscillation (CHFO) is similar to IPV in that both technologies deliver high-flow minibursts of air to the lungs6 and are designed for use either in conjunction with a conventional ventilator or as a stand-alone device.

CHFO creates a mean airway pressure that helps to prevent premature closure of lung regions while actively recruiting already collapsed areas. In addition, the continuous sub-tidal volume oscillation creates a cephalad counterflow of air that promotes upward movement of secretions (Fig. 1). The intended use of CHFO therapy is to facilitate secretion removal and treat atelectasis.

Fig. 1.
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Fig. 1.

Mechanism of intrapulmonary percussive ventilation. Adapted from PercussiveNeb user's guide.

Despite the importance of atelectasis prevention and secretion clearance in mechanically ventilated patients, data addressing the optimal treatment for atelectasis are lacking. To date, evidence for CHFO or IPV as effective therapies for atelectasis remains limited to case reports and retrospective studies.7–10 Published evidence for the use of CHFO in invasively ventilated pediatric patients is lacking. Thus, our objective was to assess the feasibility, safety, and efficacy of CHFO in the mechanically ventilated pediatric population.

QUICK LOOK

Current knowledge

Continuous high-frequency oscillation (CHFO) creates a pressure gradient in the small airways that accelerates expiratory flow. Gas flow associated with CHFO therapy may facilitate secretion removal and treat atelectasis.

What this paper contributes to our knowledge

CHFO is feasible and seems safe in mechanically ventilated pediatric patients, within the modes and ventilatory approaches used in this group of subjects. These preliminary results suggest CHFO may be beneficial by improving lung compliance in pediatric patients with secretion-induced atelectasis.

Methods

Subjects

We retrospectively reviewed the medical records of all invasively ventilated infants and children treated with CHFO at our institution from January 1, 2007 through August 31, 2012. Exclusion criteria included those patients supported with extracorporeal life support (eg, extracorporeal membrane oxygenation). CHFO was employed at clinician discretion using the MetaNeb system (Hill-Rom, Batesville, Indiana). It should be noted that the device was used off label because the device is currently FDA-cleared for use in patients ≥2 y of age. All subjects were ventilated with the AVEA ventilator (CareFusion, Yorba Linda, California). A spring-loaded T with a one-way valve was placed on the inspiratory limb of the ventilator circuit. The subject was positioned with the head of bed elevated at >30° unless contraindicated. MetaNeb mode was set to CHFO with the higher option selected. The green selector ring from the subject end of the handset was removed and replaced with the black occlusion ring, ensuring that the exhalation orifice was occluded. A nebulizer adapter with a one-way valve and a 15-mm adapter were used to connect the MetaNeb to the spring-loaded T placed in the inspiratory limb.

The use of nebulized medications, including albuterol, N-acetylcysteine, and dornase alfa, administered via the MetaNeb system was not directed by protocol. For medication delivery, an Aero Eclipse nebulizer (Trudell Medical International, London, Canada) in continuous mode was used. Standard medication dosing was applied with a maximum nebulizer volume of 6 mL. The treatment duration of medication delivery was approximately 10 min. The study was approved by the institutional review board at Duke University Medical Center, and the requirement for informed consent was waived.

Data Collection

Electronic medical records were reviewed for each patient admitted to our pediatric ICU or pediatric cardiac ICU who received CHFO while being invasively ventilated. Clinical data included heart rate, breathing frequency, blood pressure, arterial blood gases, and ventilator parameters (peak inspiratory pressure and tidal volume). Baseline data were recorded as the most recent arterial blood gas and most recent documented ventilator parameters within 12 h of initiation of CHFO therapy. Subsequent data were obtained before and after each CHFO episode, comparing ventilator data documented within 6 h pre- and post-treatment and comparing arterial blood gas (ABG) results within 8 h pretherapy with ABG results within 3 h post-treatment. Complications were recorded, including new development or worsening of pneumothorax, pneumomediastinum, or other air leak.

Data Analysis

We used medians and ranges to describe continuous variables and counts and percentages for categorical variables. Hemodynamic, blood gas, and ventilator data were compared pre- and post-CHFO therapy using the non-parametric Wilcoxon signed-rank test. We considered P < .05 statistically significant and conducted all analyses using Stata 13.1 (Stata Corp, College Station, Texas).

Results

Subjects

Fifty-nine pediatric subjects were studied, of which 63% were male. These subjects had a median age of 2 y (range 1 month to 19 y) and a median weight of 14 kg (2–81 kg). Demographic data are shown in Table 1. This patient series includes 528 CHFO treatments (1–39 treatments/subject). Seventy-five percent of these subjects received ≤10 CHFO treatments.

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Table 1.

Distribution of Subject Age and Clinical Diagnoses

Eighty percent of the subjects were supported with pressure control/synchronized intermittent mandatory ventilation + pressure support, 10% with pressure-regulated volume control ventilation, and 10% with other modes of ventilation (pressure support or airway pressure release ventilation). Ventilator and gas exchange parameters are shown in Table 2. No significant change in systolic blood pressure, diastolic blood pressure, or heart rate was seen following treatment with CHFO (data not shown). One subject (2%) developed an air leak following initiation of CHFO.

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Table 2.

Ventilator and Gas Exchange Data

Peak inspiratory pressure significantly decreased (14 [IQR 12–18] cm H2O versus 8 [IQR 6–11] cm H2O, P < .001) following CHFO therapy. FIO2 was slightly higher (0.35 [IQR 0.30–0.40] vs 0.40 [IQR 0.35–0.45], P = .002), and SaO2/FIO2 was slightly lower (259 [IQR 210–313] versus 243 [IQR 198–277], P = .003) following CHFO, but these changes do not appear clinically important. pH following CHFO was slightly lower (7.41 [IQR 7.36–7.46] versus 7.39 [IQR 7.35–7.43], P = .001) but remained in the normal range. Other parameters, including PaCO2, PaO2/FIO2, oxygenation index, exhaled tidal volume, and breathing frequency showed no significant changes with CHFO therapy.

Discussion

Thousands of children who are mechanically ventilated in the United States each year develop atelectasis. Atelectasis may prolong the duration of mechanical ventilation and increase the risk of ventilator-associated pneumonia, both of which are sources of morbidity and prolonged hospitalization.5 Additionally, impaired mucociliary clearance leads to areas of plugging and hyperexpansion, resulting in increased dead space and resultant increased risk of extubation failure.11 For this reason, treatment of atelectasis and effective augmentation of mucociliary clearance are important in mechanically ventilated children.

Although data are limited, previous studies suggest that CHFO and similar therapies may be effective for secretion clearance and treatment of atelectasis.11–13 Deakins and Chatburn12 conducted a retrospective analysis to evaluate the impact of IPV in 46 mechanically ventilated pediatric subjects. Following the retrospective analysis, a randomized controlled trial was conducted and reported as part of the same publication.12 In this study, 12 subjects were randomly assigned to receive either IPV therapy or standard chest physiotherapy. In both phases of their study, the authors assessed the impact of atelectasis on chest radiograph scores. In the retrospective phase of the study, a statistically significant improvement in atelectasis scores was found following treatment with IPV therapy. In the prospective portion, a statistically significant improvement in atelectasis score was seen in the IPV-treated group but not in the group receiving standard chest physiotherapy. Additionally, time of treatment to the resolution of atelectasis was significantly less in the IPV group as compared with the chest physiotherapy group.12

Our retrospective study was conducted with the primary aim of assessing the feasibility, effectiveness, and safety of CHFO in a heterogeneous population of infants and children requiring invasive mechanical ventilation. The impact on ventilator and gas exchange parameters in a population of critically ill patients has not been studied previously.

The current study, although underpowered, represents the largest reported sample of such subjects. CHFO therapy was well tolerated in a population of mechanically ventilated pediatric patients. Vital signs remained stable, and the rate of pneumothorax was consistent with that seen in similar pediatric ICU populations.13,14 In addition, peak inspiratory pressure significantly decreased following CHFO therapy, whereas other parameters, including PaCO2 and breathing frequency, remained stable.

In our pediatric ICU, patients are typically ventilated in pressure ventilation modes. In the current study, the majority (80%) of subjects were supported with pressure control/synchronized intermittent mandatory ventilation + pressure support. As such, the results suggest that weaning of peak pressure was possible following CHFO therapy, although it is possible that the decrease in peak pressure could have occurred without the therapy. The dramatic change that we observed in the short time following therapy, however, suggests that the intervention may have contributed to the result.

The retrospective design has inherent limitations, and our study was not designed or adequately powered for efficacy or safety. Larger, prospective clinical studies are needed to fully evaluate CHFO therapy in children receiving invasive mechanical ventilation. Despite the limitations, however, our data support the feasibility and apparent safety of CHFO in mechanically ventilated infants and children. Our data also suggest that CHFO may be beneficial by improving lung compliance in pediatric patients with secretion-induced atelectasis. Further investigation with a prospective study is needed to confirm (or refute) our findings.

Conclusions

CHFO is feasible and seems safe in our cohort of mechanically ventilated pediatric subjects, within the modes and ventilatory approaches used in this group of subjects. The rate of pneumothorax is consistent with that seen in similar pediatric ICU populations. These preliminary results suggest CHFO may be beneficial by improving lung compliance in pediatric patients with secretion-induced atelectasis. Prospective clinical studies are needed to further evaluate the clinical efficacy and safety of CHFO in children receiving invasive mechanical ventilation.

Footnotes

  • Correspondence: Ira M Cheifetz MD FAARC, Division of Pediatric Critical Care Medicine, Duke University Medical Center, Box 3046, Durham, NC 27710. E-mail: ira.cheifetz{at}duke.edu.
  • This work was supported in part by a research grant from Hill-Rom. Dr Cheifetz has disclosed relationships with Philips and Ikaria.

  • Copyright © 2016 by Daedalus Enterprises

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Continuous High-Frequency Oscillation Therapy in Invasively Ventilated Pediatric Subjects in the Critical Care Setting
Stephen Morgan, Christoph P Hornik, Niyati Patel, Walter L Williford, David A Turner, Ira M Cheifetz
Respiratory Care Nov 2016, 61 (11) 1451-1455; DOI: 10.4187/respcare.04368

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Continuous High-Frequency Oscillation Therapy in Invasively Ventilated Pediatric Subjects in the Critical Care Setting
Stephen Morgan, Christoph P Hornik, Niyati Patel, Walter L Williford, David A Turner, Ira M Cheifetz
Respiratory Care Nov 2016, 61 (11) 1451-1455; DOI: 10.4187/respcare.04368
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Keywords

  • atelectasis
  • intrapulmonary percussive ventilation
  • mucociliary clearance
  • airway clearance
  • pediatric
  • gas exchange
  • mechanical ventilation

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