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Abstract

Background:

Predictable delivery of aerosol medication for a given patient and drug-device combination is crucial, both for therapeutic effect and to avoid toxicity. The gold standard for measuring pulmonary drug deposition (PDD) is gamma scintigraphy. However, these techniques expose patients to radiation, are complicated, and are relevant for only one patient and drug-device combination, making them less available. Alternatively, in vitro experiments have been used as a surrogate to estimate in vivo performance, but this is time-consuming and has few “in vitro to in vivo” correlations for therapeutics delivered by inhalation. An alternative method for determining inhaled mass and PDD is proposed by deriving and validating a mathematical model, for the individual breathing patterns of normal subjects and drug-device operating parameters. This model was evaluated for patients with cystic fibrosis (CF).

Methods:

This study is comprised of three stages: mathematical model derivation, in vitro testing, and in vivo validation. The model was derived from an idealized patient's respiration cycle and the steady-state operating characteristics of a drug-device combination. The model was tested under in vitro dynamic conditions that varied tidal volume, inspiration-to-expiration time, and breaths per minute. This approach was then extended to incorporate additional physiological parameters (dead space, aerodynamic particle size distribution) and validated against in vivo nuclear medicine data in predicting PDD in both normal subjects and those with CF.

Results:

The model shows strong agreement with in vitro testing. In vivo testing with normal subjects yielded good agreement, but less agreement for patients with chronic obstructive lung disease and bronchiectasis from CF.

Conclusions:

The mathematical model was successful in accommodating a wide range of breathing patterns and drug-device combinations. Furthermore, the model has demonstrated its effectiveness in predicting the amount of aerosol delivered to “normal” subjects. However, challenges remain in predicting deposition in obstructive lung disease.

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References

Leung

, Louca

, Coates

. Comparison of breath enhanced to breath actuated nebulizers for rate, consistency and efficiency. Chest, 2004; 26:1619–1627.

, Kwong

WTJ

, Coates

. Evaluation of four breath-enhanced nebulizers for home use. J Aerosol Med, 2001; 14:467–475.

Coates

, MacNeish

, Allen

, Ho

, Lands

. Do sinusoidal models of respiration accurately reflect the respiratory events of cystic fibrosis patients breathing on nebulizers? J Aerosol Med, 1999; 12:265–273.

Bosco

, Rhem

, Dolovich

. In vitro estimations of in vivo jet nebulizer efficiency using actual and simulated tidal breathing patterns. J Aerosol Med, 2005; 18:427–438.

Coates

, Green

, Leung

, Chan

, Ribeiro

, Louca

, Ratjen

, Charron

, Tservistas

, Keller

. Rapid pulmonary delivery of inhaled tobramycin for Pseudomonas infection in cystic fibrosis: a pilot project. Pediatr Pulmonol, 2008; 43:753–759.

Coates

, Green

, Leung

, Louca

, Tservistas

, Chan

, Ribeiro

, Charron

. The challenges of quantitative measurement of lung deposition using ^99mTc-DTPA from delivery systems with very different delivery times. J Aerosol Med, 2007; 20:320–330.

Katz

, Ho

, Coates

. Nebulizer choice for treatment of cystic fibrosis patients with inhaled colistin. Chest, 2001; 119:250–255.

Ramsey

, Dorkin

, Eisenberg

, Gibson

. Efficacy of aerosolized tobramycin in patients with cystic fibrosis. N Engl J Med, 1993; 328:1740–1746.

Geller

, Pitlick

, Nardella

, Tracewell

, Ramsey

. Pharmacokinetics and bioavailability of aerosolized tobramycin in cystic fibrosis. Chest, 2002; 122:219–226.

10.

Deterding

, Lavange

, Engels

, Mathews

, Coquillette

, Brody

, Millard

, Ramsey

. Phase 2 randomized safety and efficacy trial of nebulized denufosol tetrasodium in cystic fibrosis. Am J Respir Crit Care Med, 2007; 176:362–369.

11.

O'Callaghan

, Clarke

, Milner

. Inaccurate calculation of drug output from nebulisers. Eur J Pediatr, 1989; 148:473–474.

12.

Evans

, Walker

, Brittain

, Paterson

. The metabolism of salbutamol in man. Xenobiotica, 1973; 3:113–120.

13.

Coates

, MacNeish

, Lands

, Meisner

, Kelemen

, Vadas

. A comparison of the availability of tobramycin for inhalation from vented versus unvented nebulizers. Chest, 1998; 113:951–956.

14.

Kwong

, MacNeish

, Meisner

, Kelemen

, Vadas

, Coates

. The use of osmometry as a means of determining changes in drug concentration during jet nebulization. J Aerosol Med, 1998; 11:89–100.

15.

MacNeish

, Meisner

, Thibert

, Kelemen

, Vadas

, Coates

. A comparison of pulmonary availability between Ventolin (albuterol) nebules and Ventolin (albuterol) Respirator Solution. Chest, 1997; 111:204–208.

16.

Kwong

WTJ

, Ho

, Coates

. Comparison of nebulized particle size distribution with Malvern laser diffraction analyzer versus Andersen cascade impactor and low-flow Marple personal cascade impactor. J Aerosol Med, 2000; 13:303–314.

17.

Mitchell

, Nagel

, Nichols

, Nerbrink

. Laser diffractometry as a technique for rapid assessment of aerosol particle size from inhalers. J Aerosol Med, 2006; 19:409–433.

18.

Clark

. The use of laser diffraction for the evaluation of the aerosol clouds generated by medical nebulizers. Int J Pharm, 1995; 115:69–78.

19.

Coates

, MacNeish

, Dinh

, Rollin

, Gagnon

, Ho

, Lands

. Accounting for radioactivity before and after nebulization of tobramycin to insure accuracy of quantification of lung deposition. J Aerosol Med, 2000; 13:169–178.

20.

Chernick

, West

. The functional basis of respiratory disease. Chernick

, Boat

, Wilmott

, Bush

. Kendig's Disorders of the Respiratory Tract in Children. Saunders/Elsevier: Philadelphia, PA, 29–64. 2006.

21.

Bland

, Altman

. Statistical methods for assessing agreement between two methods of clinical measurement. Lancet, 1986; 1:307–310.

22.

Cherniack

, Vosti

, Saxton

, Lepper

, Dowling

. Pulmonary function tests in fifty patients with bronchiectasis. J Lab Clin Med, 1959; 53:693–707.

23.

Coates

, Denk

, Leung

, Ribeiro

, Chan

, Green

, Martin

, Charron

, Edwardes

, Keller

. Higher tobramycin concentration and vibrating mesh technology can shorten antibiotic treatment time in cystic fibrosis. Pediatr Pulmonol, 2011; 46:401–408.

24.

Fleming

, Epps

, Conway

, Martonen

. Comparison of SPECT aerosol deposition data with a human respiratory tract model. J Aerosol Med, 2006; 19:268–278.

25.

Hess

, Fisher

, Williams

, Pooler

, Kacmarek

. Medication nebulizer performance: effects of diluent volume, nebulizer flow and nebulizer brand. Chest, 1996; 110:498–505.

26.

Chatburn

, McPeck

. A new system for understanding nebulizer performance. Respir Care, 2007; 52:1037–1050.

27.

Finlay

, Stapleton

, Chan

H-K

, Zuberbuhler

, Gonda

. Regional deposition of inhaled hygroscopic aerosols: in vivo SPECT compared with mathematical model. J Appl Physiol, 1996; 82:374–383.

28.

Weers

, Metzheiser

, Taylor

, Warren

, Meers

, Perkins

. A gamma scintigraphy study to investigate lung deposition and clearance of inhaled amikacin-loaded liposomes in healthy male volunteers. J Aerosol Med Pulm Drug Deliv, 2009; 22:131–138.

29.

Tiddens

HAM

, Geller

, Challoner

, Speirs

, Kesser

, Overbeek

, Humble

, Shrewbury

, Standaert

. Effect of dry powder inhaler resistance on the inspiratory flow rates and volumes of cystic fibrosis patients of six years and older. J Aerosol Med, 2006; 19:456–465.

30.

Corcoran

, Venkataramanan

, Mihelc

, Marcinkowski

, Ou

, McCook

, Weber

, Carey

, Paterson

, Pilewski

, McCurry

, Husain

. Aerosol deposition of lipid complex amphotericin-B (Abelcet) in lung transplant recipients. Am J Transplant, 2006; 6:2765–2773.

31.

Heyder

, Gebhart

, Rudolf

, Schiller

, Stahlhofen

. Deposition of particles in the human respiratory tract in the size range 0.005–15 μm. J Aerosol Sci, 1986; 17:811–825.

Modeling Breath-Enhanced Jet Nebulizers to Estimate Pulmonary Drug Deposition

Abstract

Abstract

Background:

Methods:

Results:

Conclusions:

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