Application of deuterium in research and development of drugs

Deuterium is gaining increased attention and utilization due to its unique physical and chemical properties. Deuteration has the unique benefit of positively impacting metabolic fate of pharmacologically active compounds without altering their chemical structures, physical properties, or biological activity and selectivity. In these favorable cases, deuterium substitution can in principle improve the pharmacokinetic properties and safety of therapeutic agents. The use of deuterium to create a new chemical entity not only starts with an existing drug, but can be achieved from iterative optimization in the de novo design of new compounds. Furthermore, deuterium has become a powerful tool in pharmaceutical analysis, including deuterium-labeled compounds as internal standards for extensive analysis, metabolomics, ADME, clinical pharmacology studies. This review highlights the application of deuterium in enhancing the pharmacological effects of active molecules during drug discovery and development. Additionally, deuterium-enabled pharmaceutical analysis is also covered. This review is aimed to provide references for the discovery of new deuterium-containing chemical entities with improved pharmacological properties and for the research of fate of drugs.

Deuterium- and Tritium-Labelled Compounds: Applications in the Life Sciences

Hydrogen isotopes are unique tools for identifying and understanding biological and chemical processes. Hydrogen isotope labelling allows for the traceless and direct incorporation of an additional mass or radioactive tag into an organic molecule with almost no changes in its chemical structure, physical properties, or biological activity. Using deuterium-labelled isotopologues to study the unique mass-spectrometric patterns generated from mixtures of biologically relevant molecules drastically simplifies analysis. Such methods are now providing unprecedented levels of insight in a wide and continuously growing range of applications in the life sciences and beyond. Tritium (³ H), in particular, has seen an increase in utilization, especially in pharmaceutical drug discovery. The efforts and costs associated with the synthesis of labelled compounds are more than compensated for by the enhanced molecular sensitivity during analysis and the high reliability of the data obtained. In this Review, advances in the application of hydrogen isotopes in the life sciences are described.