用于正电子发射断层扫描(PET)神经成像的18F标记磷酸二酯酶7(PDE7)抑制剂的合成及临床前评估
Synthesis and preclinical evaluation of an 18F labeled PDE7 inhibitor for PET neuroimaging.
作者信息
Thomae David, Servaes Stijn, Vazquez Naiara, Wyffels Leonie, Dedeurwaerdere Stefanie, Van der Veken Pieter, Joossens Jurgen, Augustyns Koen, Stroobants Sigrid, Staelens Steven
机构信息
Molecular Imaging Center Antwerp, University of Antwerp, Antwerp, Belgium; Laboratory of Medicinal Chemistry, University of Antwerp, Antwerp, Belgium.
Molecular Imaging Center Antwerp, University of Antwerp, Antwerp, Belgium.
出版信息
Nucl Med Biol. 2015 Dec;42(12):975-81. doi: 10.1016/j.nucmedbio.2015.07.007. Epub 2015 Jul 29.
INTRODUCTION
Phosphodiesterase 7 (PDE7) hydrolyzes selectively cyclic adenosine monophosphate (cAMP) which is an intracellular second messenger. PDE7 is expressed by 2 genes which are both present in the brain. To date there is no radiotracer for PDE7 imaging described and detection of PDE7 has only been performed by ex vivo techniques. In this report we describe the radiosynthesis of a novel fluorine-18 labeled radiotracer for PDE7 as well as the in vivo evaluation in mice to verify whether it has potential for imaging of PDE7 in the brain.
METHODS
We have synthesized a potent fluorinated PDE7 inhibitor, [(18)F]MICA-003 (PDE7 IC(50)=17 nM) and the corresponding tosylate precursor for radiolabeling. [(18)F]MICA-003 was injected in C57BL/6J mice (n=5) and in vivo images were acquired by μPET imaging. Radiometabolite analysis in plasma and brain was performed to determine the stability of the radioligand.
RESULTS
[(18)F]MICA-003 was synthesized by direct fluorination of the tosylate and produced in high decay corrected radiochemical yield (40%), high radiochemical purity (>98%) and high specific activity (86-497 GBq/μmol). μPET imaging revealed that [(18)F]MICA-003 crosses the blood brain barrier and has a homogenous distribution over the brain which washes out after the initial peak uptake. [(18)F]MICA-003 was quickly metabolized in plasma with 8.9%±0.59% of intact [(18)F]MICA-003 remaining at 5m in post injection. We observed the formation of three distinct radiometabolites of which the main radiometabolite was also detected in the brain in a proportion of 25.7±2.57% at this same time point.
CONCLUSION
We have described the synthesis and in vivo evaluation of a novel radioligand for PDE7 imaging. Despite high uptake in the brain and favorable kinetics in vivo, the presence of a brain penetrant radiometabolite makes [(18)F]MICA-003 unfavorable for the accurate quantification of PDE7 and more stable spiroquinazolinones analogs are in development.
引言
磷酸二酯酶7(PDE7)选择性水解细胞内第二信使环磷酸腺苷(cAMP)。PDE7由大脑中都存在的两个基因表达。迄今为止,尚无用于PDE7成像的放射性示踪剂描述,PDE7的检测仅通过离体技术进行。在本报告中,我们描述了一种新型的用于PDE7的氟-18标记放射性示踪剂的放射性合成,以及在小鼠体内的评估,以验证其是否具有对大脑中PDE7进行成像的潜力。
方法
我们合成了一种强效氟化PDE7抑制剂[(18)F]MICA-003(PDE7的半数抑制浓度(IC(50))=17 nM)以及用于放射性标记的相应甲苯磺酸盐前体。将[(18)F]MICA-003注射到C57BL/6J小鼠(n=5)体内,并通过微型正电子发射断层扫描(μPET)成像获取体内图像。对血浆和大脑进行放射性代谢物分析,以确定放射性配体的稳定性。
结果
[(18)F]MICA-003通过对甲苯磺酸盐的直接氟化合成,以高衰变校正放射性化学产率(40%)、高放射性化学纯度(>98%)和高比活度(86至497 GBq/μmol)产生。μPET成像显示[(18)F]MICA-003穿过血脑屏障,在大脑中分布均匀,在初始峰值摄取后逐渐清除。[(18)F]MICA-003在血浆中迅速代谢,注射后5分钟时完整的[(18)F]MICA-003仅剩余8.9%±0.59%。我们观察到形成了三种不同的放射性代谢物,在同一时间点,其中主要放射性代谢物在大脑中的比例为25.7±2.57%。
结论
我们描述了一种用于PDE7成像的新型放射性配体的合成及体内评估。尽管在大脑中摄取高且体内动力学良好,但存在可穿透大脑的放射性代谢物使得[(18)F]MICA-003不利于准确量化PDE7,更稳定的螺喹唑啉酮类似物正在研发中。
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