A methodology to study impactor particle reentrainment and a proposed stage coating for the NGI

Jenny Rissler; Lars Asking; Jakob Kisbye Dreyer

A methodology to study impactor particle reentrainment and a proposed stage coating for the NGI

Jenny Rissler, Lars Asking, Jakob Kisbye Dreyer

6 Citations (Scopus)

Abstract

BACKGROUND: Mass-weighted aerodynamic particle-size distribution (APSD) is a key attribute for pharmaceutical products developed to deliver drugs to or through the lungs. In development and quality control, APSD is primarily determined using multistage cascade impactors. For impactor techniques, particle reentrainment is critical because it may lead to an overestimation of the respirable fraction. To avoid reentrainment, the collection surfaces need to be coated with a suitable material. METHODS: In this study a method was developed to test flow dependence of particle reentrainment in the Next Generation Pharmaceutical Impactor (NGI) at flow rates ranging from 20 to 80 L/min, and was used to test three coating materials: glycerol coating, aqueous coating with, and without soaked filter paper. Uncoated cups were also tested. In the experimental setup a Vilnius Aerosol Generator generated a flow-independent dry powder aerosol, consisting of micronized insulin. RESULTS: The glycerol coating was not well suited to reduce particle reentrainment at flows >or=40 L/min. The soaked filter paper coating was found to give nearly the same particle size distributions regardless of flow and was therefore judged to be the best of those tested. Using liquid only, without the filter paper, gave the same particle size distributions as soaked filter paper for flows or=60 L/min particle reentrainment increased with flow. However, for most applications liquid coating reduced particle reentrainment to an extent at which further reduction was irrelevant. Particle reentrainment was prevalent for uncoated cups at all flow rates tested. CONCLUSIONS: This study shows the advantage of using a stable and flow-independent aerosol generation method to examine particle reentrainment at various flows through the NGI. For insulin dry powder, the use of an aqueous solution as cup coating, preferably with a filter, reduced particle reentrainment to a minimum. The results were confirmed in a study with a DPI.

Original language	English
Journal	Journal of Aerosol Medicine
Volume	22
Issue number	4
Pages (from-to)	309-16
Number of pages	7
ISSN	0894-2684
Publication status	Published - 2009

Cite this

@article{36c689a0b50111df825b000ea68e967b,

title = "A methodology to study impactor particle reentrainment and a proposed stage coating for the NGI",

abstract = "BACKGROUND: Mass-weighted aerodynamic particle-size distribution (APSD) is a key attribute for pharmaceutical products developed to deliver drugs to or through the lungs. In development and quality control, APSD is primarily determined using multistage cascade impactors. For impactor techniques, particle reentrainment is critical because it may lead to an overestimation of the respirable fraction. To avoid reentrainment, the collection surfaces need to be coated with a suitable material. METHODS: In this study a method was developed to test flow dependence of particle reentrainment in the Next Generation Pharmaceutical Impactor (NGI) at flow rates ranging from 20 to 80 L/min, and was used to test three coating materials: glycerol coating, aqueous coating with, and without soaked filter paper. Uncoated cups were also tested. In the experimental setup a Vilnius Aerosol Generator generated a flow-independent dry powder aerosol, consisting of micronized insulin. RESULTS: The glycerol coating was not well suited to reduce particle reentrainment at flows >or=40 L/min. The soaked filter paper coating was found to give nearly the same particle size distributions regardless of flow and was therefore judged to be the best of those tested. Using liquid only, without the filter paper, gave the same particle size distributions as soaked filter paper for flows or=60 L/min particle reentrainment increased with flow. However, for most applications liquid coating reduced particle reentrainment to an extent at which further reduction was irrelevant. Particle reentrainment was prevalent for uncoated cups at all flow rates tested. CONCLUSIONS: This study shows the advantage of using a stable and flow-independent aerosol generation method to examine particle reentrainment at various flows through the NGI. For insulin dry powder, the use of an aqueous solution as cup coating, preferably with a filter, reduced particle reentrainment to a minimum. The results were confirmed in a study with a DPI.",

author = "Jenny Rissler and Lars Asking and Dreyer, {Jakob Kisbye}",

note = "Keywords: Administration, Inhalation; Aerosols; Chemistry, Pharmaceutical; Drug Delivery Systems; Equipment Design; Glycerol; Humans; Insulin; Nebulizers and Vaporizers; Particle Size; Powders; Quality Control; Technology, Pharmaceutical",

year = "2009",

language = "English",

volume = "22",

pages = "309--16",

journal = "Journal of Aerosol Medicine and Pulmonary Drug Delivery",

issn = "1941-2711",

publisher = "Mary AnnLiebert, Inc. Publishers",

number = "4",

}

TY - JOUR

T1 - A methodology to study impactor particle reentrainment and a proposed stage coating for the NGI

AU - Rissler, Jenny

AU - Asking, Lars

AU - Dreyer, Jakob Kisbye

N1 - Keywords: Administration, Inhalation; Aerosols; Chemistry, Pharmaceutical; Drug Delivery Systems; Equipment Design; Glycerol; Humans; Insulin; Nebulizers and Vaporizers; Particle Size; Powders; Quality Control; Technology, Pharmaceutical

PY - 2009

Y1 - 2009

N2 - BACKGROUND: Mass-weighted aerodynamic particle-size distribution (APSD) is a key attribute for pharmaceutical products developed to deliver drugs to or through the lungs. In development and quality control, APSD is primarily determined using multistage cascade impactors. For impactor techniques, particle reentrainment is critical because it may lead to an overestimation of the respirable fraction. To avoid reentrainment, the collection surfaces need to be coated with a suitable material. METHODS: In this study a method was developed to test flow dependence of particle reentrainment in the Next Generation Pharmaceutical Impactor (NGI) at flow rates ranging from 20 to 80 L/min, and was used to test three coating materials: glycerol coating, aqueous coating with, and without soaked filter paper. Uncoated cups were also tested. In the experimental setup a Vilnius Aerosol Generator generated a flow-independent dry powder aerosol, consisting of micronized insulin. RESULTS: The glycerol coating was not well suited to reduce particle reentrainment at flows >or=40 L/min. The soaked filter paper coating was found to give nearly the same particle size distributions regardless of flow and was therefore judged to be the best of those tested. Using liquid only, without the filter paper, gave the same particle size distributions as soaked filter paper for flows or=60 L/min particle reentrainment increased with flow. However, for most applications liquid coating reduced particle reentrainment to an extent at which further reduction was irrelevant. Particle reentrainment was prevalent for uncoated cups at all flow rates tested. CONCLUSIONS: This study shows the advantage of using a stable and flow-independent aerosol generation method to examine particle reentrainment at various flows through the NGI. For insulin dry powder, the use of an aqueous solution as cup coating, preferably with a filter, reduced particle reentrainment to a minimum. The results were confirmed in a study with a DPI.

AB - BACKGROUND: Mass-weighted aerodynamic particle-size distribution (APSD) is a key attribute for pharmaceutical products developed to deliver drugs to or through the lungs. In development and quality control, APSD is primarily determined using multistage cascade impactors. For impactor techniques, particle reentrainment is critical because it may lead to an overestimation of the respirable fraction. To avoid reentrainment, the collection surfaces need to be coated with a suitable material. METHODS: In this study a method was developed to test flow dependence of particle reentrainment in the Next Generation Pharmaceutical Impactor (NGI) at flow rates ranging from 20 to 80 L/min, and was used to test three coating materials: glycerol coating, aqueous coating with, and without soaked filter paper. Uncoated cups were also tested. In the experimental setup a Vilnius Aerosol Generator generated a flow-independent dry powder aerosol, consisting of micronized insulin. RESULTS: The glycerol coating was not well suited to reduce particle reentrainment at flows >or=40 L/min. The soaked filter paper coating was found to give nearly the same particle size distributions regardless of flow and was therefore judged to be the best of those tested. Using liquid only, without the filter paper, gave the same particle size distributions as soaked filter paper for flows or=60 L/min particle reentrainment increased with flow. However, for most applications liquid coating reduced particle reentrainment to an extent at which further reduction was irrelevant. Particle reentrainment was prevalent for uncoated cups at all flow rates tested. CONCLUSIONS: This study shows the advantage of using a stable and flow-independent aerosol generation method to examine particle reentrainment at various flows through the NGI. For insulin dry powder, the use of an aqueous solution as cup coating, preferably with a filter, reduced particle reentrainment to a minimum. The results were confirmed in a study with a DPI.

M3 - Journal article

C2 - 19415989

SN - 1941-2711

VL - 22

SP - 309

EP - 316

JO - Journal of Aerosol Medicine and Pulmonary Drug Delivery

JF - Journal of Aerosol Medicine and Pulmonary Drug Delivery

IS - 4

ER -

A methodology to study impactor particle reentrainment and a proposed stage coating for the NGI

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