Summary
The emergence of highly diverse resistance mechanisms among pathogens requires their detailed analysis to guarantee an efficient medical treatment. The gold standard in clinical diagnostics is based on the cultivation of bacteria and their phenotypical characterisation. However, these methods are labour-intensive and time-consuming lasting in some cases up to a few weeks. Thus, faster diagnostic techniques are necessary to ensure an immediate and targeted treatment of the patient. DNA-based diagnostics can provide the relevant results within a few hours.
The requirements for a clinical DNA-based characterisation method are high; more than 1000 clinically relevant antibiotic resistance genes, a few hundred phylogenetic marker genes and virulence factors have to be targeted (including SNP detection). The limit of detection has to be low because a few 100 bacterial cells in the blood system can lead to the death of the patient. It should be possible to analyse a wide range of clinical sample origins such as stool, blood, urine and saliva using the same test. In addition, the results have to be obtained within a single working day.
In our project, we will develop two diagnostic systems that can be with direct sample material from patients. Thus, the time-consuming cultivation of pathogens will be avoided. Additionally, the test will be more sensitive, specific and faster than any other test on the market using an innovative DNA probe concept.
The requirements for a clinical DNA-based characterisation method are high; more than 1000 clinically relevant antibiotic resistance genes, a few hundred phylogenetic marker genes and virulence factors have to be targeted (including SNP detection). The limit of detection has to be low because a few 100 bacterial cells in the blood system can lead to the death of the patient. It should be possible to analyse a wide range of clinical sample origins such as stool, blood, urine and saliva using the same test. In addition, the results have to be obtained within a single working day.
In our project, we will develop two diagnostic systems that can be with direct sample material from patients. Thus, the time-consuming cultivation of pathogens will be avoided. Additionally, the test will be more sensitive, specific and faster than any other test on the market using an innovative DNA probe concept.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/634137 |
| Start date: | 01-05-2015 |
| End date: | 31-10-2020 |
| Total budget - Public funding: | 5 999 997,00 Euro - 5 999 997,00 Euro |
Cordis data
Original description
The emergence of highly diverse resistance mechanisms among pathogens requires their detailed analysis to guarantee an efficient medical treatment. The gold standard in clinical diagnostics is based on the cultivation of bacteria and their phenotypical characterisation. However, these methods are labour-intensive and time-consuming lasting in some cases up to a few weeks. Thus, faster diagnostic techniques are necessary to ensure an immediate and targeted treatment of the patient. DNA-based diagnostics can provide the relevant results within a few hours.The requirements for a clinical DNA-based characterisation method are high; more than 1000 clinically relevant antibiotic resistance genes, a few hundred phylogenetic marker genes and virulence factors have to be targeted (including SNP detection). The limit of detection has to be low because a few 100 bacterial cells in the blood system can lead to the death of the patient. It should be possible to analyse a wide range of clinical sample origins such as stool, blood, urine and saliva using the same test. In addition, the results have to be obtained within a single working day.
In our project, we will develop two diagnostic systems that can be with direct sample material from patients. Thus, the time-consuming cultivation of pathogens will be avoided. Additionally, the test will be more sensitive, specific and faster than any other test on the market using an innovative DNA probe concept.
Status
CLOSEDCall topic
PHC-10-2014Update Date
26-10-2022
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Organisations
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| UNIVERSITE LYON 1 CLAUDE BERNARD (UCB) (Coördinator)
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| AIT AUSTRIAN INSTITUTE OF TECHNOLOGY GMBH (AIT Austrian Institute of Technology GmbH)
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| AXO SCIENCE SAS
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| BEE ROBOTICS LTD
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| CENTRE NATIONAL DE LA RECHERCHE SCIENTIFIQUE (CNRS)
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| LYON INGENIERIE PROJETS
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| MOLZYM GMBH & CO KG
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| STICHTING KATHOLIEKE UNIVERSITEIT (SKU/RU)
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| SVEUCILISTE U ZAGREBU MEDICINSKI FAKULTET
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| THE UNIVERSITY OF WARWICK
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| UNIVERSITEIT HASSELT