Test Data AC7-01: Difference between revisions
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'''Application Challenge AC7-01''' © copyright ERCOFTAC 2019 | '''Application Challenge AC7-01''' © copyright ERCOFTAC 2019 | ||
=Test Data= | =Test Data= | ||
==Overview of tests== | |||
Major portions of this section were adopted from Lizal ''et al.'' (2015). The positron emission | |||
tomography (PET) method provides the best spatial resolution | |||
(among radiological methods). In addition to local deposition in the various sections, | |||
the deposition hot spots can also be evaluated. However, in comparison to the PET methodology, | |||
which is routinely applied to clinical examination, using this method in the ''in vitro'' design | |||
requires major modifications both in the aerosol preparation and, in particular, in the experiment evalu— | |||
ation approach. The method, based on PET and fulfilling the above mentioned criteria, | |||
is presented in the following. | |||
<br/> | <br/> | ||
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Revision as of 11:16, 2 October 2019
Aerosol deposition in the human upper airways
Application Challenge AC7-01 © copyright ERCOFTAC 2019
Test Data
Overview of tests
Major portions of this section were adopted from Lizal et al. (2015). The positron emission tomography (PET) method provides the best spatial resolution (among radiological methods). In addition to local deposition in the various sections, the deposition hot spots can also be evaluated. However, in comparison to the PET methodology, which is routinely applied to clinical examination, using this method in the in vitro design requires major modifications both in the aerosol preparation and, in particular, in the experiment evalu— ation approach. The method, based on PET and fulfilling the above mentioned criteria, is presented in the following.
Contributed by: *** — ***
© copyright ERCOFTAC 2019