Pressures and Oscillation Frequencies Generated by Bubble-Positive Expiratory Pressure Devices

Discussion

This is the first study to compare the therapist-made bubble-PEP devices Bubble-PEP-3cm and Bubble-PEP-0cm with the commercially available bubble-PEP devices AguaPEP, Hydrapep, and Therabubble. Bubble-PEP-3cm had the smallest change in expiratory pressure with increasing flow, whereas Therabubble had the largest change in expiratory pressure with increasing flow. When compared with the other devices investigated, the Bubble-PEP-3cm produced the most stable expiratory pressure regardless of flow, and the level of expiratory pressure was consistent with the height of the water within the tubing. Thus, Bubble-PEP-3cm could be considered a threshold resistor device (ie, the pressure generated remained constant, and approximately equal to the height of the water column, at any expiratory flow).

All devices investigated had tubing and air escape orifices with ID ≥8 mm, which would be expected to generate pressures equal to the height of the water column independent of expiratory flow.⁸ Despite this, there were differences between devices in the expiratory pressures generated. The differences in PEP generated with increasing flow were most likely due to design characteristics of the devices (Table 1), such as the distance of the tubing from the base of the container or the connector joining the internal and external tubings (AguaPEP and Therabubble). Both of these factors could increase pressures.

To our knowledge, this is the first study to investigate the effect of placement of tubing in the container on the amount of PEP generated. Bubble-PEP-0cm generated higher PEP than Bubble-PEP-3cm at all flows. Although the water height within the tubing in both devices was 10 cm, this was achieved in the Bubble-PEP-3cm by having a water height in the container of 13 cm with the tubing resting 3 cm from the base of the container, whereas in the Bubble-PEP-0cm, the water height in the container was 10 cm with the tubing resting on the base of the container. The resistance to air flow into the water at the distal end of the tubing when the tubing rested on the base of the container could have increased the expiratory pressures generated (ie, the base of the container may have increased the resistance to air escaping from the distal end of the tubing, thus increasing the PEP). The Bubble-PEP-0cm and Hydrapep had very similar design characteristics, but the Bubble-PEP-0cm had consistently higher PEP generated at all flows. The authors hypothesized that the difference in PEP generated between devices may have been due to the type of tubing. The therapist-made Bubble-PEP-0cm device had a rigid plastic tubing that did not deviate from its position at the base of the container, thereby providing constant resistance to air flow, whereas the Hydrapep had flexible plastic tubing that was able to deviate its position from the base of the container, thereby providing less resistance to air flow.

The AguaPEP and Hydrapep also had tubing resting at the base of the container, but the AguaPEP had higher pressures than the Hydrapep at flows >10 L/min. This was probably due to the connector between the internal (inside the container) and external (outside the container) tubings in the AguaPEP having a smaller ID than the tubing ID, which would increase resistance to air flow and thereby increase the PEP as described by Hagen-Poiseuille's law. This was also true for the Therabubble, where the connector between the 2 tubings had an ID of approximately 5 mm and was most likely the reason for the demonstrated increase in pressure with increasing flow (Fig. 3). A previous study has shown that if tubing has an ID of <8 mm, the pressure generated increases with increasing air flow.⁸

Whereas the AguaPEP, Hydrapep, and Therabubble were filled with water to the 10 cm mark indicated on the devices, the distal end of the Therabubble tubing was 4 cm from the base of the container, unlike the AguaPEP and Hydrapep, were the distal end of the tubing was at the base of the container. Thus, in the Therabubble, the actual height of the column of water providing resistance to expiration was only 6 cm, which may explain the low pressures generated at a flow of 5 L/min in this device. The AguaPEP and Hydrapep did not generate the expected 10 cm H₂O pressure at a flow of 5 L/min with a 10 cm water column height, which indicates that flows >5 L/min may be required to generate pressures equal to the height of the water column in these devices.

Although the Bubble-PEP-3cm, Bubble-PEP-0cm, AguaPEP, Hydrapep, and Therabubble generated different expiratory pressures with increasing flow, these differences may not be clinically relevant, since the expiratory pressure generated by all devices ranged from 8 to 13 cm H₂O. Currently, it is unknown whether such differences would affect the ability of the devices to assist airway clearance. Only a low flow of 5 L/min was required to generate PEP of 8–11 cm H₂O in the devices investigated, which may make these PEP devices suitable for people with impaired ability to generate expiratory flow.

All 5 devices investigated produced oscillation frequencies of 11–17 Hz, comparable with those of the Acapella (DHD Healthcare, Wampsville, New York) and Flutter (VarioRaw SA, Aubonne, Switzerland) devices.^10–12 Oscillation frequencies similar to ciliary beat frequency of 13.2 Hz¹³ may aid secretion clearance by increasing the amplitude and frequency of the cilia, potentially increasing mucociliary transport.¹¹ A study investigating the clearance of mucus in the trachea of dogs found that the enhancement of clearance was most pronounced if the oscillation frequency was between 11 and 15 Hz,¹⁴ whereas another study investigating the Flutter device in children and adults with cystic fibrosis found that airway oscillations of approximately 19 Hz reduced sputum viscoelasticity in vitro,¹⁵ making it easier to move airway secretions. In our study, flow as low as 5 L/min produced oscillation frequencies between 11 and 15 Hz. This may make the PEP devices investigated suitable to aid secretion clearance in people with impaired respiratory function.

A limitation of this study was that the tests were done in a laboratory setting and may not be reproducible in a clinical setting with human participants. However, this study clarifies the pressures and oscillations that are generated with a range of flows in these clinically available PEP devices.

The PEP generated by these bubble-PEP devices may splint airways open during expiration, thereby preventing early airway closure.⁴ PEP may also promote movement of air through collateral channels, enabling air to enter alveoli distal to the retained secretions, potentially aiding secretion clearance by expiratory air flow.⁶ The oscillations produced by the devices investigated may improve secretion clearance through the effect on mucociliary transport and sputum viscoelasticity. The particular design of Bubble-PEP-3cm in this study showed that the PEP generated was equal to the height of the water column in the tubing regardless of flow and that only a low flow of 5 L/min is required to generate 10 cm H₂O PEP and oscillation frequency of 13 Hz required to aid airway clearance. Because the therapist-made Bubble-PEP-3cm can be constructed from easily attainable and inexpensive materials, this PEP device provides a cheaper alternative than commercially available PEP devices and may be more attainable for people with limited health-care resources.