Synthesis and Evaluation of 18F-Labeled Chalcone Analogue for Detection of α-Synuclein Aggregates in the Brain Using the Mouse Model.

In the brains of patients with synucleinopathies such as Parkinson's disease, dementia with Lewy bodies, and multiple system atrophy, α-synuclein (α-syn) aggregates deposit abnormally to induce neurodegeneration, although the mechanism is unclear. Thus, in vivo imaging studies targeting α-syn aggregates have attracted much attention to guide medical intervention against synucleinopathy. In our previous study, a chalcone analogue, [125I]PHNP-3, functioned as a feasible probe in terms of α-syn binding in vitro; however, it did not migrate to the mouse brain, and further improvement of brain uptake was required. In the present study, we designed and synthesized two novel 18F-labeled chalcone analogues, [18F]FHCL-1 and [18F]FHCL-2, using a central nervous system multiparameter optimization (CNS MPO) algorithm with the aim of improving blood-brain barrier permeation in the mouse brain. Then, we evaluated their utility for in vivo imaging of α-syn aggregates using a mouse model. In the competitive inhibition assay, both chalcone analogues exhibited high binding affinity for α-syn aggregates (Ki = 2.6 and 3.4 nM, respectively), while no marked amyloid ß (Aß)-binding was observed. The 18F-labeling reaction was successfully performed. In a biodistribution experiment, brain uptake of both chalcone analogues in normal mice (2.09 and 2.40% injected dose/gram (% ID/g) at 2 min postinjection, respectively) was higher than that of [125I]PHNP-3, suggesting that the introduction of 18F into the chalcone analogue led to an improvement in brain uptake in mice while maintaining favorable binding ability for α-syn aggregates. Furthermore, in an ex vivo autoradiography experiment, [18F]FHCL-2 showed the feasibility of the detection of α-syn aggregates in the mouse brain in vivo. These preclinical studies demonstrated the validity of the design of α-syn-targeting probes based on the CNS MPO score and the possibility of in vivo imaging of α-syn aggregates in a mouse model using 18F-labeled chalcone analogues.

Structure-Activity Relationships of Styrylquinoline and Styrylquinoxaline Derivatives as α-Synuclein Imaging Probes.

Synucleinopathies are characterized by the deposition of α-synuclein (α-syn) aggregates before the onset of clinical symptoms. Therefore, in vivo imaging of α-syn may contribute to early diagnosis of these diseases and has attracted much attention in recent years. However, no clinically useful probes have been reported. In the present study, 16 quinoline/quinoxaline derivatives with different styryl and fluorine groups were evaluated in order to develop α-syn imaging probes. Among them, SQ3, which is a quinoline analogue with a p-(dimethylamino)styryl group and fluoroethoxy group at the 2- and 7- positions of the skeleton, displayed moderate selectivity for α-syn aggregates over ß-amyloid (Aß) aggregates (K i = 230 nM), while maintaining high binding affinity for α-syn aggregates (K i = 39.3 nM). In a biodistribution study, [18F]SQ3 exhibited high uptake (2.08% ID/g at 2 min after intravenous injection) into a normal mouse brain. Taken together, we demonstrate that [18F]SQ3 has basic properties as a lead compound for the development of a useful α-syn imaging probe.

Synthesis and evaluation of novel radioiodinated phenylbenzofuranone derivatives as α-synuclein imaging probes.

α-Synuclein (α-syn) aggregates are major components of pathological hallmarks observed in the human brain affected by neurodegenerative diseases such as Parkinson's disease, dementia with Lewy bodies, and multiple system atrophy. It is known that α-syn aggregates are involved in the pathogenesis of these neurodegenerative diseases. However, detailed mechanisms have not been fully elucidated. Therefore, the development of radiolabeled imaging probes to detect α-syn aggregates in vivo may contribute to early diagnosis and pathophysiological elucidation of neurodegenerative diseases affected by α-syn aggregates. In the present study, we designed and synthesized four radioiodinated phenylbenzofuranone (PBF) derivatives: [123/125I]IDPBF-2, [123/125I]INPBF-2, [123/125I]IDPBF-3, and [123/125I]INPBF-3, as candidates for α-syn imaging probes. All four compounds exhibited high binding affinity for recombinant α-syn aggregates in an inhibition assay. However, brain uptake of all four compounds was insufficient to achieve α-syn imaging in vivo. Considering the results of this study, while further structural modifications are required to improve brain uptake, it is suggested that PBF derivatives show fundamental characteristics as α-syn imaging probes.

Chalcone Analogue as New Candidate for Selective Detection of α-Synuclein Pathology.

Deposition of α-synuclein (α-syn) aggregates is one of the neuropathological hallmarks of synucleinopathies including Parkinson's disease, dementia with Lewy bodies, and multiple-system atrophy. In vivo detection of α-syn aggregates with SPECT or PET may be an effective tool for medical intervention against synucleinopathy. In the present study, we designed and synthesized a series of chalcone analogues with different aryl groups to evaluate their potential as α-syn imaging probes. In competitive inhibition assays, aryl groups markedly affected binding affinity and selectivity for recombinant α-syn aggregates. Chalcone analogues with a 4-(dimethylamino)phenyl group bound to both α-syn and amyloid ß (Aß) aggregates while ones with a 4-nitrophenyl group displayed α-syn-selective binding. In fluorescent staining, only chalcone analogues with a 4-nitrophenyl group succeeded in selective detection of human α-syn against Aß aggregates in patients' brain samples. Among them, PHNP-3 exhibited the most promising binding characteristics for α-syn aggregates (Ki = 0.52 nM), encouraging us to further evaluate its utility. Then, a 125I-labeling reaction was performed to obtain [125I]PHNP-3. In a binding saturation assay, [125I]PHNP-3 bound to α-syn aggregates with high affinity (Kd = 6.9 nM) and selectivity. In a biodistribution study, [125I]PHNP-3 exhibited modest uptake (0.78% ID/g at 2 min after intravenous injection) into a normal mouse brain. Although there is room for improvement of its pharmacokinetics in the brain, encouraging in vitro results in the present study indicate that further structural optimization based on PHNP-3 might lead to the development of a clinically useful probe targeting α-syn aggregates in the future.

Characterization and Optimization of Benzimidazopyrimidine and Pyridoimidazopyridine Derivatives as Tau-SPECT Probes.

The accumulation of hyperphosphorylated tau protein in the brain is regarded as one of the hallmarks of Alzheimer's disease (AD). In vivo imaging of tau aggregates is helpful for diagnosis and monitoring of the progression of AD. In this study, we designed and synthesized novel radioiodinated benzimidazopyrimidine (BIPM) and pyridoimidazopyridine (PIP) derivatives with a monomethylamino, monoethylamino, monopropylamino, or diethylamino group as tau imaging probes for single-photon-emission computed tomography (SPECT). On in vitro autoradiography with AD brain sections, [125I]PIP-NHMe showed the highest selective binding affinity for tau aggregates among the radioiodinated BIPM and PIP derivatives. In a biodistribution study using normal mice, [125I]PIP-NHMe and [125I]PIP-NHEt displayed high initial uptake (6.62 and 6.86% ID/g, respectively, at 2 min postinjection) into and rapid clearance from the brain, with brain2 min/brain30 min ratios of 38.9 and 28.6, respectively. These results suggest that [123I]PIP-NHMe may be a novel SPECT probe that is useful for detecting tau aggregates in the AD brain.

Structure-Activity and Brain Kinetics Relationships of 18F-Labeled Benzimidazopyridine Derivatives as Tau PET Tracers.

Noninvasive imaging of tau aggregates with a positron emission tomography (PET) tracer is useful for the diagnosis and staging of Alzheimer's disease (AD). Recently, we found that benzimidazopyridine (BIP) is an attractive scaffold for developing PET and single photon computed emission tomography tracers targeting tau aggregates. In this study, we designed and synthesized five novel 18F-labeled compounds with various substituted groups or atoms at the 7-position of the BIP scaffold. In in vitro autoradiographic studies, all 18F-labeled BIP derivatives selectively bound to tau aggregates deposited in AD brain sections. On the other hand, the initial brain uptake of these compounds was affected by the type of substituted group or halogen atom introduced into the 7-position of the BIP scaffold. Among these compounds, [18F]Me-BIPF showed the highest brain uptake (6.79% ID/g at 2 min postinjection) and 2 min/60 min ratio (3.59). These results suggest that appropriate introduction of the substituted group or atom into the 7-position of the BIP scaffold may be effective for developing useful tau PET tracers.

Identification and Evaluation of Bisquinoline Scaffold as a New Candidate for α-Synuclein-PET Imaging.

α-Synuclein (α-syn) aggregates are pathologically associated with the hallmarks found in brains affected by synucleinopathies such as Parkinson's disease (PD) and multiple system atrophy (MSA). Therefore, the in vivo detection of α-syn aggregates using radiolabeled probes is useful for the comprehension of and medical intervention for synucleinopathies. In the present study, we identified a bisquinoline scaffold as a new promising structure for targeting α-syn aggregates by a screening assay. Then, based on the scaffold, novel bisquinoline derivatives, BQ1 and BQ2, were designed and synthesized, and we evaluated their utilities as α-syn imaging probes. Both compounds showed high affinity for recombinant α-syn aggregates in binding assays in vitro and clearly detected α-syn aggregates in human brain sections. BQ2 showed higher affinity for α-syn aggregates than BQ1, leading to performing 18F-labeling to obtain [18F]BQ2. In a biodistribution study using normal mice, [18F]BQ2 displayed moderate uptake (1.59% ID/g at 2 min postinjection) into but subsequent retention (1.35% ID/g at 60 min postinjection) in the brain. The results of this study suggest that a bisquinoline derivative may be a new candidate as an α-syn-PET imaging probe after appropriate structure modification for further improvement in the pharmacokinetics.

Structure-Activity Relationships of Radioiodinated 6,5,6-Tricyclic Compounds for the Development of Tau Imaging Probes.

Tau aggregate, which is the main component of the neurofibrillary tangle, is an attractive imaging target for diagnosing and monitoring the progression of Alzheimer's disease (AD). In this study, we designed and synthesized six radioiodinated 6,5,6-tricyclic compounds to explore novel scaffolds for tau imaging probes. On in vitro autoradiography of AD brain sections, pyridoimidazopyridine and benzimidazopyrimidine derivatives ([125I]21 and [125I]22, respectively) showed selective binding affinity for tau aggregates, whereas carbazole, pyrrolodipyridine, and pyridoimidazopyrimidine derivatives ([125I]10, [125I]12, and [125I]23, respectively) bound ß-amyloid aggregates. In a biodistribution study using normal mice, [125I]21 and [125I]22 showed high initial uptakes (5.73 and 5.66% ID/g, respectively, at 2 min postinjection) into and rapid washout (0.14 and 0.10% ID/g, respectively, at 60 min postinjection) from the brain. Taken together, two novel scaffolds including pyridoimidazopyridine and benzimidazopyrimidine may be applied to develop useful tau imaging probes.

18F-labeled benzimidazopyridine derivatives for PET imaging of tau pathology in Alzheimer's disease.

Hyperphosphorylated tau proteins are one of the neuropathological hallmarks in the Alzheimer's disease (AD) brain. The in vivo imaging of tau aggregates with nuclear medical imaging probes is helpful for the further comprehension of and medical intervention in the AD pathology. For tau-selective PET imaging, we newly designed and synthesized 18F-labeled benzimidazopyridine (BIP) derivatives with fluoroalkylamino groups, [18F]IBIPF1 and [18F]IBIPF2, and evaluated their utilities as tau imaging probes. They both bound selectively to tau against amyloid ß (Aß) aggregates in AD brain sections in vitro, and showed good pharmacokinetics in mouse brains in vivo. Notably, [18F]IBIPF1 exhibited high tau-selectivity (Tau/Aß ratio = 34.8), high brain uptake (6.22% ID/g at 2 min postinjection), and subsequent washout (2.77% ID/g at 30 min postinjection). In vivo analysis of radiometabolites indicated that [18F]IBIPF1 was stable against metabolism in the mouse brain. These encouraging preclinical results suggest that further structural optimization based on the BIP scaffold may lead to the development of more useful tau imaging probes.

Characterization of Novel 18F-Labeled Phenoxymethylpyridine Derivatives as Amylin Imaging Probes.

Deposition of islet amyloid consisting of amylin constitutes one of pathological hallmarks of type 2 diabetes mellitus (T2DM), and it may be involved in the development and progression of T2DM. However, the details about the relationship between the deposition of islet amyloid and the pathology of T2DM remain unclear, since no useful imaging tracer enabling the visualization of pancreatic amylin is available. In the present study, we synthesized and evaluated six novel 18F-labeled phenoxymethylpyridine (PMP) derivatives as amylin imaging probes. All 18F-labeled PMP derivatives showed not only affinity for islet amyloid in the post-mortem T2DM pancreatic sections but also excellent pharmacokinetics in normal mice. Furthermore, ex vivo autoradiographic studies demonstrated that [18F]FPMP-5 showed intense labeling of islet amyloids in the diabetes model mouse pancreas in vivo. The preclinical studies suggested that [18F]FPMP-5 may have potential as an imaging probe that targets amylin aggregates in the T2DM pancreas.

Conversion of iodine to fluorine-18 based on iodinated chalcone and evaluation for ß-amyloid PET imaging.

In the amyloid cascade hypothesis, ß-amyloid (Aß) plaques is one of the major pathological biomarkers in the Alzheimer's disease (AD) brain. We report the synthesis and evaluation of novel radiofluorinated chalcones, [18F]4-dimethylamino-4'-fluoro-chalcone ([18F]DMFC) and [18F]4'-fluoro-4-methylamino-chalcone ([18F]FMC), as Aß imaging probes. The conversion of iodine directly introduced to the chalcone backbone into fluorine was successfully carried out by 18F-labeling via the corresponding boronate precursors, achieving the direct introduction of fluorine-18 into the chalcone backbone to prepare [18F]DMFC and [18F]FMC. In a biodistribution study using normal mice, [18F]DMFC and [18F]FMC showed a higher initial uptake (4.43 and 5.47% ID/g at 2 min postinjection, respectively) into and more rapid clearance (0.52 and 0.66% ID/g at 30 min postinjection, respectively) from the brain than a Food and Drug Administration (FDA)-approved Aß imaging agent ([18F]Florbetapir), meaning the improvement of the probability of detecting Aß plaques and the reduction of non-specific binding in the brain. In the in vitro binding studies using aggregates of recombinant Aß peptides, [18F]DMFC and [18F]FMC showed high binding affinity to recombinant Aß aggregates at the Kd values of 4.47 and 6.50 nM, respectively. In the in vitro autoradiography (ARG) experiment with AD brain sections, [18F]DMFC and [18F]FMC markedly accumulated only in a region with abundant Aß plaques, indicating that they clearly recognized human Aß plaques in vitro. These encouraging results suggest that [18F]DMFC and [18F]FMC may be promising PET probes for the detection of an amyloid pathology and the early diagnosis of AD with marked accuracy.

Structure-Activity Relationships of Radioiodinated Benzoimidazopyridine Derivatives for Detection of Tau Pathology.

It is generally accepted that neurofibrillary tangles consisting of tau proteins are involved in the pathogenesis of Alzheimer's disease (AD). For selective detection of tau pathology, we synthesized and evaluated radioiodinated benzoimidazopyridine (BIP) derivatives with an alkylamino group as tau imaging probes. In vitro selectivity to tau aggregates and in vivo pharmacokinetics of BIP derivatives varied markedly, being strongly dependent on the alkylamino group. In in vitro autoradiography with AD brain sections, the BIP derivative with a dimethylamino group (BIP-NMe2) showed the highest selectivity to tau aggregates. Regarding the biodistribution using normal mice, the BIP derivative with an ethylamino group (BIP-NHEt) showed the highest uptake (6.04% ID/g at 2 min postinjection) into and rapid washout (0.12% ID/g at 60 min postinjection) from the brain. These results suggest that the introduction of an optimal alkylamino group into the BIP scaffold may lead to the development of more potential tau imaging probes.