ICON Web & News
Virtual Journal
Everything
Resources
Virtual Journal
Analyze Database
GoodNanoGuide
ICON Reports
ICON Backgrounders
Glossary
Policy Reports
Ratings Comment
Guidelines
Links
Quick Search:
Keywords:
Search:
Search Using OECD Database
Details
Return to Previous Page
Addition or Correction
Title:
Nanoparticle diffusion in respiratory mucus from humans without lung disease
Date:
4/2013
Link to Journal Abstract
Abstract:
A major role of respiratory mucus is to trap inhaled particles, including pathogens and environmental particulates, to limit body exposure. Despite the tremendous health implications, how particle size and surface chemistry affect mobility in respiratory mucus from humans without lung disease is not known. We prepared polymeric nanoparticles densely coated with low molecular weight polyethylene glycol (PEG) to minimize muco-adhesion, and compared their transport to that of uncoated particles in human respiratory mucus, which we collected from the endotracheal tubes of surgical patients with no respiratory comorbidities. We found that 100 and 200 nm diameter PEG-coated particles rapidly penetrated respiratory mucus, at rates exceeding their uncoated counterparts by approximately 15- and 35-fold, respectively. In contrast, PEG-coated particles ¡Ý500 nm in diameter were sterically immobilized by the mucus mesh. Thus, even though respiratory mucus is a viscoelastic solid at the macroscopic level (as measured using a bulk rheometer), nanoparticles that are sufficiently small and muco-inert can penetrate the mucus as if it were primarily a viscous liquid. These findings help elucidate the barrier properties of respiratory mucus and provide design criteria for therapeutic nanoparticles capable of penetrating mucus to approach the underlying airway epithelium.
Non-technical Summary:
For this study, the authors prepared polymeric nanoparticles densely coated with low molecular weight polyethylene glycol (PEG) to minimize muco-adhesion, and compared their transport to that of uncoated particles in human respiratory mucus, which were collected from the endotracheal tubes of surgical patients with no respiratory comorbidities.
Content Emphasis
Peer Reviewed Journal Article
Exposure Or Hazard Target
Mammalian
Exposure Pathway
Inhalation
Method Of Study
In Vitro
Paper Type
Exposure
Particle Type
Organic/Polymers
Production Method
Engineered
Risk Exposure Group
General Population
Target Audience
Technical Research
Citation:
Biomaterials, 34(13): 3439-3446 (April 2013)
Publication:
Biomaterials
Author:
Schuster BS, Suk JS, Woodworth GF, Hanes J
Volume:
34
Number:
13
Pages:
3439-3446
Last updated on March 18, 2013
Permalink
Join Us
|
About
|
Newsroom
|
Working Groups
|
Projects
|
Resources
|
Virtual Journal
|
Events
|
Logout
This work is supported in part by the Nanoscale Science and Engineering Initiative of the National Science Foundation
under NSF Award Number EEC-0118007.
Why Join Us?
Mission and Strategy
Background
Organization
Sponsors
Participants
Contact Us
ICON Releases
News
Media Alert
RSS
Governance
Knowledge Base
Best Practices
Communications
Virtual Journal
Analyze Database
Good Nano Guide
ICON Reports
ICON Backgrounders
Glossary
Policy Reports
Links
Council Events
Other Events
Virtual Journal
Analyze Database
The GoodNanoGuide
Nano EHS Research Needs
Current Practices Survey