Summary
Absorption, distribution, metabolism and excretion´s studies (ADME) are essential for drug discovery and development, providing invaluable preclinical data to understand how the drug behaves in living organisms, thus allowing to make a decision on whether the drug should be terminated or advanced to the next step. At present, most of these studies are performed with a radiolabelled 14C-labelled version of the drug; unfortunately, current radiolabelling syntheses rely on lengthy-step sequences or rather expensive 14C-labelled building blocks, dramatically raising the costs for the research and development, and delaying the execution of preclinical studies. Taking into consideration that carboxylic acids are privileged motifs in a myriad of agrochemicals or pharmaceuticals, LABEL-DIOX offers the opportunity of promoting a late-stage carboxylation event with labeled CO2. The protocol is user-friendly, with components that are neither air- nor moisture sensitive, utilizes earth-abundant catalysts and operates under mild conditions. LABEL-DIOX will increase the overall efficiency of the carbon isotope incorporation, reduce the costs that would have resulted from the design of a lengthy radiolabelled synthesis, minimize the costs for waste disposal and dramatically increase the revenues, thus changing the way industrial chemists conduct radiolabelling of drugs containing carboxylic acids.
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| Web resources: | https://cordis.europa.eu/project/id/755251 |
| Start date: | 01-12-2017 |
| End date: | 31-05-2019 |
| Total budget - Public funding: | 149 750,00 Euro - 149 750,00 Euro |
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Original description
Absorption, distribution, metabolism and excretion´s studies (ADME) are essential for drug discovery and development, providing invaluable preclinical data to understand how the drug behaves in living organisms, thus allowing to make a decision on whether the drug should be terminated or advanced to the next step. At present, most of these studies are performed with a radiolabelled 14C-labelled version of the drug; unfortunately, current radiolabelling syntheses rely on lengthy-step sequences or rather expensive 14C-labelled building blocks, dramatically raising the costs for the research and development, and delaying the execution of preclinical studies. Taking into consideration that carboxylic acids are privileged motifs in a myriad of agrochemicals or pharmaceuticals, LABEL-DIOX offers the opportunity of promoting a late-stage carboxylation event with labeled CO2. The protocol is user-friendly, with components that are neither air- nor moisture sensitive, utilizes earth-abundant catalysts and operates under mild conditions. LABEL-DIOX will increase the overall efficiency of the carbon isotope incorporation, reduce the costs that would have resulted from the design of a lengthy radiolabelled synthesis, minimize the costs for waste disposal and dramatically increase the revenues, thus changing the way industrial chemists conduct radiolabelling of drugs containing carboxylic acids.Status
CLOSEDCall topic
ERC-PoC-2016Update Date
27-04-2024
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