Bilayer networks within a hydrogel shell: A robust chassis for artificial cells and a platform for membrane studies
- Submitting institution
-
Cardiff University / Prifysgol Caerdydd
- Unit of assessment
- 12 - Engineering
- Output identifier
- 96146235
- Type
- D - Journal article
- DOI
-
10.1002/anie.201607571
- Title of journal
- Angewandte Chemie International Edition
- Article number
- -
- First page
- 14240
- Volume
- 55
- Issue
- 46
- ISSN
- 1433-7851
- Open access status
- Compliant
- Month of publication
- October
- Year of publication
- 2016
- URL
-
http://dx.doi.org/10.1002/anie.201607571
- Supplementary information
-
-
- Request cross-referral to
- -
- Output has been delayed by COVID-19
- No
- COVID-19 affected output statement
- -
- Forensic science
- No
- Criminology
- No
- Interdisciplinary
- Yes
- Number of additional authors
-
5
- Research group(s)
-
-
- Proposed double-weighted
- No
- Reserve for an output with double weighting
- No
- Additional information
- This research led to a patent (US2019/02529A1, 22.08.19) [https://patents.google.com/patent/US20190255529A1/en] and licensing agreement with Oxford University Spin-out, OxSybio Ltd. With the application potential focused in pharmaceuticals and healthcare, new licensing discussions continue with a new proposed replacement commercial vehicle from Oxford University. The output remains in the 93rd percentile and in the top 10% of all research outputs ever tracked by Altmetric [https://www.altmetric.com/details/12598933#score]. With another output (10.1002/anie.201607571;) it fundamentally contributed to the 2019 award of a €5M, EU-FET-Proactive Grant [No. 824060: Name; Artificial Cells with Distributed Cores, to Decipher Protein Function (https://acdch2020.eu/)].
- Author contribution statement
- -
- Non-English
- No
- English abstract
- -