[摘要] The long-term objective is to develop blood-brain barrier (BBB) permeable m2-selective (relative to m1, m3, and m4) receptor-binding radiotracers and utilize these radiotracers for quantifying receptor concentrations obtained from PET or SPECT images of human brain. In initial studies, we concluded that the lipophilicity and high affinity prevented (R,S)-I-QNB from reaching a flow-independent and receptor-dependent state in a reasonable time. Thus, it was clear that (R,S)-I-QNB should be modified. Therefore, during the last portion of this funded research, we proposed that more polar heterocycles should help accomplish that. Since reports of others concluded that radiobromination and radiofluorination of the unactivated phenyl ring is not feasible (Newkome et al,,1982), we, therefore, explored during this grant period a series of analogues of (R)-QNB in which one or both of the six-membered phenyl rings is replaced by a five-membered thienyl (Boulay et al., 1995), or furyl ring. The chemistry specific aims were to synthesize novel compounds designed to be m2-selective mAChR ligands capable of penetrating into the CNS, and develop methods for efficient radiolabeling of promising m2-selective muscarinic ligands. The pharmacology specific aims were to determine the affinity and subtype-selectivity of the novel compounds using competition binding studies with membranes from cells that express each of the five muscarinic receptor subtypes, to determine the ability of the promising non-radioactive compounds and radiolabeled novel compounds to cross the BBB, to determine the biodistribution, in-vivo pharmacokinetics, and in-vitm kinetics of promising m2-selective radioligands and to determine the distribution of receptors for the novel m2-selective radioligands using quantitative autoradiography of rat brain, and compare this distribution to the distribution of known m2-selective compounds.