User:Alexis Courbet: Difference between revisions
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[[Image:Alexis_Courbet.jpg|thumb|right|Alexis Courbet]] | [[Image:Alexis_Courbet.jpg|thumb|right|Alexis Courbet]] | ||
* Cellular/molecular engineering | * Cellular/molecular engineering | ||
* Biosensing | * Biocomputing & Biosensing | ||
* Synthetic biological circuits | * Synthetic biological circuits | ||
* CAD for synthetic biology | * CAD & computational design for synthetic biology | ||
* Autonomous & programmable biosystems | * Autonomous & programmable biosystems | ||
* Protocells & minimal systems | * Protocells & minimal systems | ||
* Microfluidics | * Microfluidics | ||
* Medical sciences, translational medicine | * Biomolecular prosthetics, diagnostics & theranostics | ||
* Medical sciences, translational medicine | |||
* Multidisciplinary science | * Multidisciplinary science | ||
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I developped concepts, systematic methods, computational tools and biological standards to: | I developped concepts, systematic methods, computational tools and biological standards to: | ||
1. Engineer next-generation diagnostics. I engineered autonomous and programmable biosensors integrating multiplexed pathological biomarker detection and complex biological signal processing as ''intelligent'' diagnostic devices. | *1. Engineer next-generation diagnostics. I engineered autonomous and programmable biosensors integrating multiplexed pathological biomarker detection and complex biological signal processing as ''intelligent'' diagnostic devices. | ||
*2. Engineer novel biocomputing devices that solve complex problems and process/interface biological information at the microscale. I developed microfluidic and computer assisted methodologies to program these synthetic biosystems from the bottum-up (e.g. protocells). | |||
I believe that collaboration between scientists and promotion of interdisciplinarity is the key to understand and engineer biology. | I believe that collaboration between scientists and promotion of interdisciplinarity is the key to understand and engineer biology. | ||
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* 2012-2015, PhD at The National Center for Scientific Research (CNRS)&Bio-Rad/Stanford University | * 2012-2015, PhD at The National Center for Scientific Research (CNRS)&Bio-Rad/Stanford University | ||
* 2012, MS in Molecular and Cellular Biophysics, University of Montpellier | * 2012, MS in Molecular and Cellular Biophysics, University of Montpellier | ||
* 2011-2015, Residency in Clinical Toxicology, Pharmaceutical innovation and Research | * 2011-2015, Residency in Clinical Toxicology, Pharmaceutical innovation and Biomedical Research | ||
* 2011, MS in Cellular and Molecular Biology, University Paris Sud 11 | * 2011, MS in Cellular and Molecular Biology, University Paris Sud 11 | ||
* 2010, BS, University of Paris Sud 11 | * 2010, BS, University of Paris Sud 11 | ||
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==Useful links== | ==Useful links== | ||
*[[ | *[http://diybio.org/ DIYbio] | ||
*[[ | *[http://aeon.co/magazine/ Aeon] | ||
*[http://parts.igem.org/Main_Page?title=Main_Page Registry of biological parts] | |||
*[https://lifeware.inria.fr/biocham/ The Biochemical Abstract Machine BIOCHAM] | |||
*[https://www.lri.fr/~pa/Hsim/ The stochastic automaton HSIM] | |||
Revision as of 13:29, 17 August 2015
Research interests
- Cellular/molecular engineering
- Biocomputing & Biosensing
- Synthetic biological circuits
- CAD & computational design for synthetic biology
- Autonomous & programmable biosystems
- Protocells & minimal systems
- Microfluidics
- Biomolecular prosthetics, diagnostics & theranostics
- Medical sciences, translational medicine
- Multidisciplinary science
During my PhD, I applied synthetic biology to human health and biotechnology.
I developped concepts, systematic methods, computational tools and biological standards to:
- 1. Engineer next-generation diagnostics. I engineered autonomous and programmable biosensors integrating multiplexed pathological biomarker detection and complex biological signal processing as intelligent diagnostic devices.
- 2. Engineer novel biocomputing devices that solve complex problems and process/interface biological information at the microscale. I developed microfluidic and computer assisted methodologies to program these synthetic biosystems from the bottum-up (e.g. protocells).
I believe that collaboration between scientists and promotion of interdisciplinarity is the key to understand and engineer biology.
Contact Info
- Alexis Courbet
- Sys2diag laboratory, CNRS
Complex biological systems modelling and engineering for diagnosis
- Montpellier, France
- Email me through OpenWetWare
Education
- 2012-2015, PhD at The National Center for Scientific Research (CNRS)&Bio-Rad/Stanford University
- 2012, MS in Molecular and Cellular Biophysics, University of Montpellier
- 2011-2015, Residency in Clinical Toxicology, Pharmaceutical innovation and Biomedical Research
- 2011, MS in Cellular and Molecular Biology, University Paris Sud 11
- 2010, BS, University of Paris Sud 11
- 2010, BMSc, University of Paris Sud 11
Publications
Detection of pathological biomarkers in human clinical samples via amplifying genetic switches and logic gates
Science Translational Medicine, 2015 May 27;7(289):289ra83
Alexis Courbet, Drew Endy, Eric Renard, Franck Molina, and Jérôme Bonnet
Abstract PDF
Supplementary Materials
Computing with Synthetic Protocells
Acta Biotheor., 2015 May 13;
Alexis Courbet, Patrick Amar, and Franck Molina
Abstract PDF
Engineering next generation diagnostics through synthetic biology
University of Montpellier, Medical Thesis, 2015 July 2;
Alexis Courbet
PDF
