Targeting histone deacetylase in lung cancer for early diagnosis: (18)F-FAHA PET/CT imaging of NNK-treated A/J mice model.

Elevated levels of histone deacetylases (HDACs) have been indicated in the development of some cancers. HDAC has been imaged using (18)F-FAHA and may serve as a marker to study epigenetics. We report evaluation of (18)F-FAHA as a probe in the early diagnosis of lung cancer using (18)F-FAHA PET/CT studies of A/J mice treated with NNK. (18)F-FAHA radiosynthesis was carried out in specific activity of ~2 Ci/µmol. A/J mice were divided into 2 groups: 1. Controls; 2. NNK treatment group with NNK (100 mg/kg, ip, weekly for 4 wks). Mice were injected 100-200 µCi i.v. (18)F-FAHA and then scanned in Inveon PET/CT under anesthesia using 2.0% isoflurane. Midbrain, cerebellum and brainstem uptake of (18)F-FAHA was displaced by the known HDAC inhibitor, suberanilohydroxamic acid (SAHA) with less than 10% activity remaining. CT revealed presence of lung nodules in 8 to 10-month old NNK mice while control mice were free of tumors. Little uptake of (18)F-FAHA was observed in the control mice lungs while significant (18)F-FAHA uptake occurred in the lungs of NNK-treated mice with tumor/nontumor >2.0. Ex vivo scans of the excised NNK and control mice lungs confirmed presence of extensive amounts of lung nodules seen by CT and confirmed by (18)F-FAHA in the NNK mice with tumor/nontumor >6.0. Our preliminary imaging studies with A/J mice lung cancer model suggest (18)F-FAHA PET may allow the study of epigenetic mechanisms involved in NNK-induced tumorigenesis in the lungs.

Synthesis and evaluation of 2-(18)F-fluoro-5-iodo-3-[2-(S)-3,4-dehydropyrrolinylmethoxy]pyridine ((18)F-Niofene) as a potential imaging agent for nicotinic α4ß2 receptors.

Nicotinic α4ß2 acetylcholine receptors (nAChRs) have been implicated in various pathophysiologies including neurodegenerative diseases. Currently, 2-(18)F-A85380 (2-FA) and 5-(123)I-A85380 (5-IA) are used separately in human PET and SPECT studies respectively and require >4-6 hours of scanning. We have developed 2-fluoro-5-iodo-3-[2-(S)-3-dehydropyrrolinylmethoxy]pyridine (niofene) as a potential PET/SPECT imaging agent for nAChRs with an aim to have rapid binding kinetics similar to that of (18)F-nifene used in PET studies. Niofene exhibited a 10-fold better in vitro binding affinity in rat brain than that of nicotine. The relative binding of niofene was similar to that of niodene and twice as better as that of nifene. In vitro autoradiography in rat brain slices alongside niodene indicated selective binding of niofene to regions consistent with α4ß2 receptor distribution. Niofene, 10 nM, displaced >70% of (3)H-cytisine bound to α4ß2 receptors in rat brain slices. Radiolabeling of (18)F-niofene was achieved in 10-15% radiochemical yield in high specific activities >2 Ci/µmol and showed rapid in vivo kinetics similar to that of (18)F-nifene and (18)F-nifrolene. In vivo PET in rats showed rapid uptake in the brain and selective localization in receptor regions such as the thalamus (TH). Pseudoequilibrium with (18)F-niofene was achieved in 30-40 minutes, which is similar to that of (18)F-nifene. Further evaluation of (18)F-niofene as a potential PET imaging agent is underway. Future studies will be conducted to radiolabel niofene with iodine-123 for use in SPECT imaging.

Nicotinic α4ß2 receptor imaging agents. Part IV. Synthesis and biological evaluation of 3-(2-(S)-3,4-dehydropyrrolinyl methoxy)-5-(3'-¹8F-fluoropropyl)pyridine (¹8F-Nifrolene) using PET.

Imaging agents for nicotinic α4ß2 receptors in the brain have been under way for studying various CNS disorders. Previous studies from our laboratories have reported the successful development of agonist, ¹8F-nifene. In attempts to develop potential antagonists, ¹8F-nifrolidine and ¹8F-nifzetidine were previously reported. Further optimization of these fluoropropyl derivatives has now been carried out resulting in 3-(2-(S)-3,4-dehydropyrrolinylmethoxy)-5-(3'-Fluoropropyl)pyridine (nifrolene) as a new high affinity agent for nicotinic α4ß2 receptors. Nifrolene in rat brain homogenate assays--labeled with ³H-cytisine--exhibited a binding affinity of 0.36 nM. The fluorine-18 analog, ¹8F-nifrolene, was synthesized in approximately 10%-20% yield and specific activity was estimated to be >2000 Ci/mmol. Rat brain slices indicated selective binding to anterior thalamic nuclei, thalamus, subiculum, striata, cortex and other regions consistent with α4ß2 receptor distribution. This selective binding was displaced >90% by 300 µM nicotine. Thalamus to cerebellum ratio (>10) was the highest for ¹8F-nifrolene with several other regions showing selective binding. In vivo rat PET studies exhibited rapid uptake of ¹8F-nifrolene in the brain with specific retention in the thalamus and other brain regions while clearing out from the cerebellum. Thalamus to cerebellum ratio value in the rat was >4. Administration of nicotine caused a rapid decline in the thalamic ¹8F-nifrolene suggesting reversible binding to nicotinic receptors. PET imaging studies of ¹8F-nifrolene in anesthetized rhesus monkey revealed highest binding in the thalamus followed by regions of the lateral cingulated and temporal cortex. Cerebellum showed the least binding. Thalamus to cerebellum ratio in the monkey brain was >3 at 120 min. These ratios of ¹8F-nifrolene are higher than measured for ¹8F-nifrolidine and ¹8F-nifzetidine. ¹8F-Nifrolene thus shows promise as a new PET imaging agent for α4ß2 nAChR.

Synthesis and evaluation of 3-¹²³I-iodo-5-[2-(S)-3-pyrrolinylmethoxy]-pyridine (niodene) as a potential nicotinic α4ß2 receptor imaging agent.

Nicotinic acetylcholine receptors (nAChRs) are downregulated in disease conditions such as Alzheimer's and substance abuse. Presently, (123)I-5-IA-85380 is used in human studies and requires over 6h of scanning time, thus increases patient discomfort. We have designed and synthesized 3-iodo-5-[2-(S)-3-pyrrolinylmethoxy]pyridine (niodene) with the aim to have faster binding kinetics compared to (123)I-5-IA-85380, which may reduce scanning time and help in imaging studies. Binding affinity K(i) of niodene for rat brain α4ß2 receptors in brain homogenate assays using (3)H-cytisine was 0.27 nM. Niodene, 10nM displaced >95% of (18)F-nifene bound to α4ß2 receptors in rat brain slices. By using the iododestannylation method, (123)I-niodene was obtained in high radiochemical purity (>95%) but with low radiochemical yield (<5%) and low specific activity (∼100 Ci/mmol). Autoradiograms show (123)I-niodene localized in the thalamus and cortex, which was displaced by nicotine (thalamus to cerebellum ratio=4; cortex to cerebellum ratio=1.6). Methods of radioiodination need to be further evaluated in order to obtain (123)I-niodene in higher radiochemical yields and higher specific activity of this potentially useful new SPECT imaging agent.