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Research ArticleOriginal Research

Effect of a Nebulizer Holding Chamber on Aerosol Delivery

Rania M Sarhan, Ahmed A Elberry, Nada Saed Abdelwahab, Hoda Rabea, Mohamed Nabil Salem and Mohamed EA Abdelrahim
Respiratory Care September 2018, 63 (9) 1125-1131; DOI: https://doi.org/10.4187/respcare.06061
Rania M Sarhan
Clinical Pharmacy Department, Faculty of Pharmacy, Beni-suef University, Beni-suef, Egypt.
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Ahmed A Elberry
Clinical Pharmacology Department, Faculty of Medicine, Beni-suef University, Beni-suef, Egypt.
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Nada Saed Abdelwahab
Analytical Chemistry Department, Faculty of Pharmacy, Beni-Suef University, Beni-Suef, Egypt.
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Hoda Rabea
Clinical Pharmacy Department, Faculty of Pharmacy, Beni-suef University, Beni-suef, Egypt.
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Mohamed Nabil Salem
Internal Medicine Department, Faculty of Medicine, Beni-suef University, Beni-suef, Egypt.
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Mohamed EA Abdelrahim
Clinical Pharmacy Department, Faculty of Pharmacy, Beni-suef University, Beni-suef, Egypt.
Clinical Pharmacy Department, Faculty of Pharmacy, Ahram Canadian University, Giza, Egypt.
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  • For correspondence: [email protected]
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Abstract

BACKGROUND: A new holding chamber was designed to be used with the Aerogen Solo nebulizer to increase the aerosol emitted that reach the patient. The aim of this study was to evaluate the efficacy of this holding chamber with the nebulizer and determine its usability with other nebulizers.

METHODS: The study was divided into 2 parts. In the first part, aerosol emitted of 1 mL respirable solution (nominal dose of 5000 μg salbutamol), delivered by using the mesh nebulizer, Pro nebulizer, and jet nebulizer, connected to a T-piece or a holding chamber, was determined by using a breathing simulator set to provide a tidal volume of 500 mL, frequency of 15 breaths/min, and the inspiratory-expiratory ratio of 1:1 for adults as the quiet breathing pattern. Aerodynamic particle size characterizations were determined by using a cooled cascade impactor at an inhalation flow of 15 L/min. In the second part of the study, 12 healthy nonsmoking subjects (6 females) >18 y, with an FEV1 > 90% were enrolled. Inhaled aerosol of 1 mL respirable solution (5,000 μg salbutamol) was delivered through the mesh nebulizer–holding chamber and an mesh nebulizer–T-piece using normal tidal breathing. The subjects provided urine samples 30 min after dosing and cumulatively collected their urine for 24 h. The samples were analyzed for salbutamol content.

RESULTS: The holding chamber significantly increased aerosol emitted by the 3 nebulizers compared with the T-piece (P < .01) and relatively decreased the mass median aerodynamic diameter but with no significant difference. The mesh nebulizer–holding chamber resulted in significantly higher aerosol emitted compared with any other delivery method tested (P < .01). The mesh nebulizer–holding chamber resulted in higher urine samples 30 min after dosing (as an index of lung deposition) and cumulatively collected urine for 24 h (as an index of systemic absorption) compared with the nebulizer–T-piece (P < .05).

CONCLUSIONS: The use of the holding chamber with a jet nebulizer, Pro nebulizer, and the Solo nebulizer significantly increased the aerosol delivery. The Solo nebulizer–holding chamber had the highest aerosol emitted compared with all nebulizer-adapter combinations and higher urine samples 30 min after dosing and cumulatively collected urine for 24 h compared with the nebulizer–T-piece.

  • jet nebulizer
  • nebulizer holding chamber
  • T-piece
  • Anderson cascade impactor
  • vibrating mesh nebulizer

Introduction

At present, there are many types of nebulizers with different mechanisms and designs.1,2 Inhaled aerosols can be delivered to patients by using nebulizers with different adapters, for example, a T-piece, holding chamber, mouthpiece, or oronasal mask.3–5 A newly designed holding chamber for use with the Aerogen Solo vibrating mesh nebulizer (Aerogen, Galway, Ireland), is designed to improve effectiveness and decrease the loss due to exhalation and condensation. This Solo–holding chamber combination could result in much higher aerosol delivery to patients in need of frequently administered nebulized medication.5,6 However, the high price of the Solo compared with jet nebulizers could be a barrier for some patients. This proposed beneficial effect of the holding chamber with the Solo, in addition to the cost issues, raises a question about the possibility of holding chamber use with a jet nebulizer or design of similar holding chambers for a jet nebulizer. The aim of the present study was to evaluate the efficacy of using the holding chamber and a T-piece with a jet nebulizer and the Aerogen Pro vibrating mesh nebulizer, and to compare their results with those of the Solo.

QUICK LOOK

Current knowledge

Aerosol delivery by nebulizer results in a great loss of the drug into the surrounding, which results in less delivery to the patient. Holding chambers and holding chamber design can increase aerosol delivery.

What this paper contributes to our knowledge

The holding chamber with the jet nebulizer, Aerogen Pro vibrating mesh nebulizer, and Aerogen Solo vibrating mesh nebulizer increased the aerosol delivery more than with the T-piece. Aerogen Solo with the holding chamber had the highest delivery compared with all nebulizer-adapter combinations.

Methods

Amount of Aerosol Emitted

The nebulizers studied were the Solo, the Pro, and the Oxycare jet nebulizer (Ceren Uretim, Istanbul, Turkey) attached to a PortaNeb compressor (Philips Respironics, Murraysville, PA). The PortaNeb compressor provides an air flow of 6 L/min into the jet nebulizer to aerosolize the liquid. The nebulizers were connected to either the standard nebulizer T-piece with a mouthpiece adapter or to the Aerogen Ultra as a holding chamber. The holding chamber adapter connections to the 3 different nebulizers studied are shown in Figure 1.

Fig. 1.
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Fig. 1.

The holding chamber connected to the Aerogen Solo vibrating mesh nebulizer (A), jet nebulizer (B), and Aerogen Pro vibrating mesh nebulizer (C).

A lung simulator (model 5600i; Michigan Instruments, Grand Rapids, MI) was used to provide spontaneous breathing, with a tidal volume of 500 mL, frequency of 15 breaths/min, and inspiratory-to-expiratory ratio of 1:1, which represent adults with a quiet breathing pattern, in accordance with the European Standard EN 13544–16 (CEN methodology).7 An electrostatic filter enclosed within a filter holder (Pari, Starnberg, Germany) was attached to the simulator from one side and the nebulizer-adapter combination from the other side, as shown in Figure 2. This filter traps all the aerosol produced during the inhalation period of a breathing cycle and thus provides a good measure of the in vitro emitted aerosol available for inhalation.8,9 The lung simulator was switched on 30 s before delivering the aerosol. The salbutamol respirable solution, 5,000 μg in 1 mL (Farcolin respirator solution, μg/mL; Pharco Pharmaceuticals, Alexandria, Egypt), was nebulized to sputtering for the jet nebulizer and to dryness for the Solo and Pro nebulizers.

Fig. 2.
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Fig. 2.

Schematic diagram of the experimental setting for the determination of the amount of aerosol emitted.

For each nebulizer-adapter combination, 5 determinations were made. The amounts of salbutamol deposited on the filter, left in the nebulizer reservoir chamber, and deposited inside the adapters used were recovered by rinsing with 20% acetonitrile. The amounts deposited on the filter were sonicated with 20% acetonitrile before rinsing. High-performance liquid chromatography with ultraviolet detection was used to identify the amounts of salbutamol. This method used a 25 mm × 4.6 mm ZORBAX Eclipse Plus C18, ODS1 column (Agilant, Santa Clara, CA) through which a mobile phase that consisted of a mixture of acetonitrile and water (which contained 0.1% phosphoric acid) (90:10, v/v), which was pumped at 1 mL/min by using an Agilent 1260 Infinity preparative pump (G1361A). An Agilent 1260 Infinity Diode array detector VL (G131SD) was set at 225 nm, with an injection volume of 100 μL. Calibration solutions ranged from 4 to 100 μg/mL (weight/volume). The limit of detection was 0.35 μg/mL, and the lower limit of quantification was 2.55 μg/mL.

Particle Size Distribution of the Aerosol Emitted

A cooled Anderson cascade impactor (Copley Scientific, Nottingham, United Kingdom) was used to determine the particle droplet size distribution of the aerosolized medication delivered. The Anderson cascade impactor, with its plates in situ, was placed in a refrigerator at 5°C for 60 min before use.10 Immediately after removing the Anderson cascade impactor from the refrigerator, the inhalation flow was adjusted to 15 L/min and the induction port of the Anderson cascade impactor was connected directly into the mouthpiece of the nebulizer-adapter combination and was tested, as shown in Figure 3. The vacuum flow through the Anderson cascade impactor was provided by a Gast pump (Brook Crompton, Huddersfield, United Kingdom). The flow was measured by using an electronic digital flow meter (MKS Instruments, Andover, MA). The salbutamol respirable solution, 5,000 μg/mL, was nebulized to sputtering for the jet nebulizer and to dryness for the Solo and Pro nebulizers. For each nebulizer adapter combination, 3 determinations were made.

Fig. 3.
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Fig. 3.

Schematic diagram of the experimental setting for the determination of particle-size distribution of the aerosol emitted.

Salbutamol deposited onto each plate of the Anderson cascade impacter, nebulizer reservoir chamber, and adapters was recovered by rinsing with 20% acetonitrile. Similarly, the mass entrained in the filter was recovered by sonication and rinsing. High-performance liquid chromatography was used as previously described. The fine-particle dose, fine-particle fraction, and the mass median aerodynamic diameter were determined by using Copley Inhaler Testing Data Analysis Software (CITDAS; Copley Scientific) impactor data.

In Vivo Study

Hindle and Chrystyn11 developed a urinary pharmacokinetic method to determine relative lung and systemic bioavailability of salbutamol after inhalation.11 This method used the amount of drug excreted in the first 30 min as an index of lung deposition and the amount of drug excreted over a 24-h period after inhalation as an index of the systemic absorption.11 This noninvasive pharmacokinetic method has been used to detect lung deposition of an aerosolized drug to healthy volunteers,12 subjects admitted with an exacerbation of either asthma or COPD,13 and subjects who were on ventilation.14–18 Similarly, we used this methodology to compare lung deposition and systemic absorption.

This study was conducted in accordance with the amended Declaration of Helsinki. Local institutional review boards and independent ethics committees approved the protocol, and written informed consent was obtained from all the subjects. Twelve non-smoking healthy subjects (6 females) >18 y with an FEV1 > 90% agreed to inhale a nebulized aerosol of salbutamol respiratory solution when using normal tidal breathing. They were first trained on how to inhale through the nebulizers. The subjects were trained to place the mouthpiece between their lips and breathe in and out gently through their mouth. Each subject randomly inhaled 1 mL of salbutamol respirable solution (5,000 μg/mL) from the holding chamber and the T-piece with the nebulizer that resulted in the greatest aerosol emitted in the in vitro part of the study. The dose was loaded into the nebulizer for the subject before use according to the patient information leaflet.

Both the volumes of the drug excreted in the first 30 min and the drug excreted over a 24-h period after inhalation were measured and then assayed by using high-performance liquid chromatography. Bambuterol hydrochloride was added as the internal standard to the collected urine samples. Salbutamol and bambuterol were extracted from the urine sample by using solid-phase extraction.16 The eluent was then injected into the high-performance liquid chromatography system, which was composed of an ODS 5 μm, (4.6 × 250 mm; ZORBAX Eclipse) C-18 high-performance liquid chromatography column with a (4 × 3 mm, Agilent) C-18 (ODS) guard column. The mobile phase, composed of acetonitrile water that contained 0.1% orthophosphoric acid (90:10, v/v), was pumped through the columns at a flow of 1 mL/min, maintained with a 25–photodiode-array detector set at 220 nm. The lower detection limit and lower quantification limit for salbutamol were 0.36 and 1.00 μg/mL, respectively.15

Statistical Analysis

All data are expressed as mean ± SD. One-way analysis of variance with the application of least significant difference correction was used to compare the 6 different nebulizer adapter combinations. The urine samples were compared by using the Kruskal-Wallis analysis of variance, followed by the Mann-Whitney test for pairwise comparison by using SPSS V15.0 (SPSS, Chicago, Illinois).

Results

A summary of the in vitro results is provided in Table 1. The holding chamber significantly increased the emitted aerosol deposited onto the filter delivered by the 3 nebulizers compared with the T-piece (P < .01). The 2 tested vibrating mesh nebulizers (Solo and Pro) used, had significantly higher aerosol emitted (P < .001) and lower residual volume (P < .001) compared with the jet nebulizer. The Solo–holding chamber resulted in a significantly higher aerosol emitted compared with any other nebulizer adapter combination tested (P < .01). No significant difference was found between the amount deposited in the T-piece and the holding chamber when using the jet nebulizer. However, when using the Solo or Pro, the amount deposited inside the holding chamber was significantly higher than in the T-piece (P < .05 and P < .001, respectively).

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Table 1.

Results of Aerodynamic Characterization of 1 mL Respirable Solution (5,000 μg nominal dose) Delivered By Using Solo, Pro, and Jet Nebulizers With the T-Piece and Holding Chamber Adapter (n = 5)

The aerodynamic droplet-size distributions from the 6 different nebulizer-adapter combinations are shown in Table 1. The mass median aerodynamic diameter of the holding chamber with the 3 nebulizers was relatively lower compared with those with the T-piece, but no significant difference was found. The Pro–holding chamber resulted in significantly higher fine-particle fraction (P < .001) compared with the Pro–T-piece. However no significant difference was found in the MMAD.

From the in vitro results, the Solo resulted in the highest aerosol emitted and so we chose it for the in vivo part of the study. Twelve subjects (6 females) with a mean ± SD age, weight, and height of 33.3 ± 5.6 y, 82.7 ± 7.4 kg, and 168.0 ± 4.9 cm, respectively, completed the study. The FEV1 of all the subjects were >90% of predicted value, with a mean ± SD of 95.4 ± 4.0% of the predicted value.

The mean ± SD salbutamol excreted after inhalation from the Solo–holding chamber and Solo–T-piece during the 30 min after the start of the inhalation and cumulatively pooled for the next 24 h are presented in Table 2. The amount of drug excreted in the first 30 min and amount of drug excreted over a 24-h period after inhalation from the Solo–holding chamber were significantly higher than from the Solo–T-piece (P = .034 and .02, respectively).

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Table 2.

Salbutamol Excreted After Inhalation From Solo–Holding Chamber and Solo–T-Piece

Discussion

The performance of 20 disposable jet nebulizers had previously been evaluated to help the Aerosol Group of the French Cystic Fibrosis Society recommend a jet nebulizer for use in real life.19 However, any chosen jet nebulizer would deliver much lower aerosol emitted compared with vibrating mesh nebulizers.8,10,20,21 We found similar results in our study. The Solo and the Pro resulted in a much higher aerosol emitted than jet nebulizer (P < .001).

Use of the holding chamber resulted in significantly higher amounts of delivered aerosol compared with the T-piece (P < .01) with all the nebulizers studied. Hence, the holding chamber saved some of the exhaled aerosol when using the T-piece and decreased the fugitive aerosol.22 The holding chamber significantly increased (P < .001) the aerosol emitted to double from the Solo.5 Also, the use of the holding chamber with a jet nebulizer significantly increased (P < .01) the aerosol emitted to double that of the jet nebulizer–T-piece. These results extended the benefit of the tested holding chamber as an aerosol saver to the jet nebulizer. So, the patient who cannot afford the vibrating mesh nebulizers could use the present holding chamber or a similar holding chamber with the jet nebulizer for better delivery. Even though the aerosol emitted of jet nebulizer–holding chamber was 0.75 that of the Solo–T-piece, the use of the holding chamber with jet nebulizer would be beneficial in aerosol delivery compared with the T-piece or mouthpiece adapters. Furthermore, to increase the benefit of the holding chamber with a jet nebulizer, health-care providers would be asked to increase the fill volume by diluting the respirable dose placed in the jet nebulizer's nebulizer reservoir chamber, which was previously proven to increase the inhalable mass.22

The Pro–holding chamber also showed an increase in the aerosol emitted (1.25-fold) but not as much as when the holding chamber was used with the Solo or jet nebulizer. This might be due to the placement of the holding chamber below the Pro, as shown in Figure 1C. This setup could allow some condensation to occur on the walls of the holding chamber, with the help of aerosol inertial impaction and gravity, which would not occur with the Solo because the holding chamber and the Solo were placed side by side, as shown in Figure 1A. With the jet nebulizer, the position of the holding chamber was above the jet nebulizer, as shown in Figure 1B, so any condensation on the walls will return to the nebulizer reservoir chamber to be re-nebulized.8,9,23,24 The significant increases (P < .001) of the amount left in the holding chamber compared with that in the T-piece with the Pro support this rationale and suggest that the 25% increase in the aerosol emitted with the Pro–holding chamber was from the exhaled aerosol not the condensate.24

The Solo–holding chamber resulted in much better delivery than the Pro and the jet nebulizer or even the Solo itself with its T-piece.5,25 These results might have occurred because the holding chamber studied was designed for the Solo, with which it gives maximum advantage.

The uses of the holding chamber with the 3 nebulizers did not have much effect on the aerodynamic characterization. A relative insignificant decrease in the mass median aerodynamic diameter with the use of the holding chamber with all the nebulizers and a very slight increase in the fine-particle fraction were observed in the study. This was due to the nature of the nebulized aerosol, which does not contain propellant, like the metered-dose inhaler, which allows evaporation to take place when using a holding chamber or spacers.7,24 However, the main effect of the holding chamber is not to decrease the particle size of the aerosolized medication but to hold the nebulized aerosol from release to the surrounding area.26

The urinary data from the in vivo study showed similar results. The Solo–holding chamber significantly increased the amount of drug excreted over a 24-h period after inhalation by 1.8-fold (P = .02) and the amount of drug excreted in the first 30 min by 1.3-fold (P = .034) compared with the Solo–T-piece. Suggesting that the aerosol emitted determines the whole amount delivered to the patient but not the fraction deposited into the lungs.5,27,28

The holding chamber would deliver more medication to the patient, as presented here by the significant increase of the aerosol emitted, amount of drug excreted in the first 30 min, and amount of drug excreted over a 24-h period after inhalation. These increases would be accompanied by a reduction of the aerosol lost to the atmosphere that may be inhaled by the health-care provider in the vicinity of the patient.22,29 Hence, we recommend the use of the holding chamber with the jet nebulizer and the Pro for better aerosol delivery or the development of a holding chamber similar to that studied here for use with such nebulizers. Because the tested holding chamber with the Solo, the nebulizer designed to be used with the holding chamber had the greatest aerosol emitted (P < .01). However, this should be done with caution, and a dose adjustment to avoid any possible adverse effects of the increase in systemic absorption.

Conclusions

The holding chamber did not have much effect on the mass median aerodynamic diameter and the fine-particle fraction. The use of a holding chamber with the jet nebulizer, Pro, and Solo significantly increased aerosol delivery compared with the T-piece. Therefore, the holding chamber could be of benefit when used with a jet nebulizer or Pro. It might be much better to develop a special holding chamber for the Pro and jet nebulizer, such as the holding chamber studied here because the Solo–holding chamber had the highest aerosol emitted compared with all nebulizer-adapter combinations and higher amount of drug excreted in the first 30 min and amount of drug excreted over a 24-h period after inhalation compared with the Solo–T-piece.

Footnotes

  • Correspondence: Mohamed E Abdelrahim PhD, Department of Clinical Pharmacy, Faculty of Pharmacy, Ahram Canadian University, Giza, Egypt, E-mail: mohamedemam9{at}yahoo.com
  • The authors have disclosed no conflicts of interest.

  • Copyright © 2018 by Daedalus Enterprises

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Respiratory Care: 63 (9)
Respiratory Care
Vol. 63, Issue 9
1 Sep 2018
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Effect of a Nebulizer Holding Chamber on Aerosol Delivery
Rania M Sarhan, Ahmed A Elberry, Nada Saed Abdelwahab, Hoda Rabea, Mohamed Nabil Salem, Mohamed EA Abdelrahim
Respiratory Care Sep 2018, 63 (9) 1125-1131; DOI: 10.4187/respcare.06061

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Effect of a Nebulizer Holding Chamber on Aerosol Delivery
Rania M Sarhan, Ahmed A Elberry, Nada Saed Abdelwahab, Hoda Rabea, Mohamed Nabil Salem, Mohamed EA Abdelrahim
Respiratory Care Sep 2018, 63 (9) 1125-1131; DOI: 10.4187/respcare.06061
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