The potential of radioiodinated (-)-m-iodovesamicol for diagnosing cholinergic deficit dementia

Evaluation of radioiodinated (-)-o-iodovesamicol as a radiotracer for mapping the vesicular acetylcholine transporter

We evaluated the potencies of radioiodinated (-)-o-iodovesamicol [(-)-oIV] as a selective vesicular acetylcholine transporter (VAChT) mapping agent. (-)-[125I]oIV exhibited significant accumulation (about 2.8% of the injected dose) in rat brain. The regional brain distribution of radioactivity was similar for both (-)-[125I]olV and (-)-[3H]vesamicol. The accumulation of (-)-[125I]oIV in the brain was significant reduced by post-administration of unlabeled vesamicol (0.5 /micromol/kg(-1)) and (-)-oIV (0.5 micromol/kg(-1)). On the other hand, the post-administration of sigma ligands hardly affected the accumulation of (-)-[125I]oIV in the brain. These studies showed that (-)-[125I]oIV, as well as [3H] vesamicol, bound to VAChT with high affinity in the rat brain. Furthermore, (-)-[125I]oIV binding in the ipsilateral cortex to the lesion was significantly reduced by 17.0%, compared with that in the contralateral cortex in a unilateral NBM-lesioned rat. These results suggested that radioiodinated (-)-oIV may potentially be useful for the diagnosis of cholinergic neurodegenerative disorders.

Imaging end points for monitoring neuroprotection in Parkinson's disease

In this review, the potential role of positron emission tomography and single-photon emission computed tomography as biological markers for following the progression of Parkinson's disease (PD) is discussed, and their value for assessing the efficacy of putative neuroprotective agents in PD is considered. It is concluded that functional imaging provides a valuable adjunct to clinical assessment when judging the efficacy of neuroprotective approaches to PD.

Characterization of radioiodinated (-)-ortho-iodovesamicol binding in rat brain preparations

We investigated the binding characteristics of optical isomers of three iodovesamicol analogs to vesicular acetylcholine transporters (VAChT) and to sigma receptors (sigma-1, sigma-2) in rat brains. In competitive inhibition studies, (-)-enantiomers [(-)-ortho-iodovesamicol ((-)-oIV), (-)-meta-iodovesamicol ((-)-mIV), (-)-vesamicol] displayed a higher affinity for VAChT than (+)-enantiomer [(+)-oIV, (+)-mIV, (+)-vesamicol]. (-)-oIV and (-)-mIV showed the same high affinity for VAChT as (-)-vesamicol. For sigma receptors(sigma-1, sigma-2), (-)-oIV (Ki = 62.2 nM (to sigma-1) and 554 nM(to sigma-2)) showed a lower affinity than (-)-mIV (Ki = 4.5 nM (to sigma-1) and 42.9 nM (to sigma-2)). Furthermore, in a saturation binding study, (-)-[125I]-oIV exhibited a Kd of 17.4 +/- 5.1 nM with a maximum number of binding sites, Bmax, of 559 +/- 51 fmol/ mg of protein. These results showed that (-)-oIV binds to vesicular acetylcholine transporters (VAChT) more selectively than (-)-mIV, previously reported as a VAChT mapping agent, and may be suitable for VAChT imaging studies.