Therapy for radioisotope contamination of a large population by a dirty bomb or other event will require a cocktail of decorporation agents because of the wide variety of possible radionuclides and their chemical/biological properties. Decorporation is the only way to reduce exposure of certain incorporated radioisotopes. Fission product lanthanides and the actinides are among the most intractable of these elements to decorporate. While diethylenetriaminepentaacetic acid (DTPA) has been the standard therapy for actinide/lanthanide decorporation since its development and use by the U.S. Atomic Energy Commission in the 1950's, it is limited in efficacy. A new family of sequestering agents has been developed using a biomimetic design based on the similar biochemical transport properties of plutonium(IV) and iron(IIl) and siderophores, the natural iron chelators of bacteria. These chelators are more selective and have higher affinity for plutonium(IV) and a number of other actinide metal ions. Extensive toxicity and efficacy studies using a mouse model have been published and limited tests have been done in dogs and baboons. The results established that several of the new agents are much more effective than DTPA and, unlike DTPA, can be orally active. This project proposes to take two lead compounds 3,4,3-LI-i ,2-HOPO (an octadentate ligand) and 5-LIO-Me-3,2-HQPO (a tetradentate ligand) toward clinical use by scaling up the synthesis, establishing preparation methods suitable for good manufacturing practice (GMP), carrying out limited efficacy and toxicity studies for combinations of the two chelators in a mouse model, completing toxicity studies in human cell lines, and establishing preclinical safety of the candidate ligands under good laboratory practice (GLP) guidelines. The objective of this research is to bring forth two new decorporation agents in tandem and successfully accelerate their development to a pre-IND stage where only primate studies remain prior to a full IND application. This will be accomplished by an effective partnering of Lawrence Berkeley National Laboratory (LBNL) that has expertise in Iigand design, synthesis, and laboratory testing, with SRI International which possesses expertise in GLP testing and bringing pharmaceutical products to market. ? ? ? ?
Sturzbecher-Hoehne, Manuel; Leung, Clara Ng Pak; D'Aleo, Anthony et al. (2011) 3,4,3-LI(1,2-HOPO): in vitro formation of highly stable lanthanide complexes translates into efficacious in vivo europium decorporation. Dalton Trans 40:8340-6 |
Abergel, Rebecca J; Durbin, Patricia W; Kullgren, Birgitta et al. (2010) Biomimetic actinide chelators: an update on the preclinical development of the orally active hydroxypyridonate decorporation agents 3,4,3-LI(1,2-HOPO) and 5-LIO(Me-3,2-HOPO). Health Phys 99:401-7 |
Abergel, Rebecca J; D'Aleo, Anthony; Leung, Clara Ng Pak et al. (2009) Using the antenna effect as a spectroscopic tool: photophysics and solution thermodynamics of the model luminescent hydroxypyridonate complex [Eu(III)(3,4,3-LI(1,2-HOPO))]-. Inorg Chem 48:10868-70 |
Durbin, Patricia W (2008) Lauriston S. Taylor Lecture: the quest for therapeutic actinide chelators. Health Phys 95:465-92 |