ISSN:
1553-7366
eISSN:
1553-7374
Disciplines
(Field of Science):
- Biomedical engineering (Engineering and Technology)
- Pharmacology and pharmacy (Medical and Health Sciences )
- Medical sciences (Medical and Health Sciences )
- Health sciences (Medical and Health Sciences )
- Forestry (Agricultural sciences)
- Agriculture and horticulture (Agricultural sciences)
- Nutrition and food technology (Agricultural sciences)
- Veterinary science (Agricultural sciences)
- Biological sciences (Natural sciences)
- Chemical sciences (Natural sciences)
Ministry points: Help
2021 | 140 | Ministry Scored Journals List 2019 |
Year | Points | List |
---|---|---|
2021 | 140 | Ministry Scored Journals List 2019 |
2020 | 140 | Ministry Scored Journals List 2019 |
2019 | 140 | Ministry Scored Journals List 2019 |
2018 | 45 | A |
2017 | 45 | A |
2016 | 45 | A |
2015 | 45 | A |
2012 | 50 | A |
2011 | 50 | A |
Model:
Open Access
Punkty CiteScore:
2019 | 11 |
Year | Points |
---|---|
2019 | 11 |
2018 | 11.1 |
2017 | 11.5 |
2016 | 12.5 |
2015 | 12.9 |
2014 | 12.9 |
2013 | 13.3 |
2012 | 13.7 |
2011 | 12.3 |
Impact Factor:
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Publishing policy:
Green
Help
SHERPA RoMEO status
- Pre-print
- author's version of the article before the review
- Post-print
- author's version of the article after the review
Status table SHERPA RoMEO
RoMEO color | Archiving policy |
---|---|
Green | can archive pre-prints and post-prints or a version of the publisher |
Blue | can archive post-prints |
Yellow | can archive pre-prints |
White | can not archive any materials |
Gray | unknown |
Papers published in journal
Filters
total: 1
Catalog Journals
2020
-
A shear stress micromodel of urinary tract infection by the Escherichia coli producing Dr adhesin
PublicationIn this study, we established a dynamic micromodel of urinary tract infection to analyze the impact of UT-segment-specific urinary outflow on the persistence of E. coli colonization. We found that the adherence of Dr+ E. coli to bladder T24 transitional cells and type IV collagen is maximal at lowest shear stress and is reduced by any increase in flow velocity. The analyzed adherence was effective in the whole spectrum of physiological...
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