Kongzhen Hu

Synthesis and biological evaluation of N-(2-[18F]Fluoropropionyl)-L-methionine for tumor imaging☆

INTRODUCTION N-position radiolabeled amino acids, such as N-(2-[(18)F]fluoropropionyl)-L-methionine ([(18)F]FPMET) as a derivative of L-methionine (MET), can potentially serve as a PET tracer for tumor imaging. In the current study, radiosynthesis and biological evaluation of [(18)F]FPMET as a new PET tumor agent are performed. METHODS [(18)F]FPMET was synthesized by reacting 4-nitrophenyl 2-[(18)F]fluoropropionate ([(18)F]NFP) with MET. In vitro competitive inhibition and protein incorporation experiments were performed with Hepa1-6 hepatoma cell lines. The biodistribution of [(18)F]FPMET was determined in S180 fibrosarcoma-bearing mice. PET/CT studies of [(18)F]FPMET were conducted in S180 fibrosarcoma-bearing mice, A549 lung adenocarcinoma-bearing nude mice, and PC-3 prostate cancer-bearing nude mice. RESULTS [(18)F]FPMET was synthesized in 72%± 4% uncorrected radiochemical yield (n=10) from [(18)F]NFP. In vitro experiments showed that [(18)F]FPMET was primarily transported through Na(+)-dependent system A, system ASC, and system B(0,+), and was not incorporated into protein. Biodistribution and PET/CT imaging studies indicated that [(18)F]FPMET could delineate S180 fibrosarcoma, A549 lung adenocarcinoma, and PC-3 prostate cancer. CONCLUSION An efficient synthesis of N-position [(18)F]labeled amino acids with a classic [(18)F]NFP prosthetic group is developed. The results support that [(18)F]FPMET seems to be a potential tracer for tumor imaging with PET.

In Vivo Cancer Dual-Targeting and Dual-Modality Imaging with Functionalized Quantum Dots

Semiconductor quantum dots (QDs), after surface modification to provide water solubility and biocompatibility, have a promising future in biomedical applications. In this study, a dual receptor–targeting dual-modality PET/near-infrared fluorescence (NIRF) probe was developed for accurate assessment of the pharmacokinetics and tumor-targeting efficacy of QDs. Methods: QDs were modified by β-Glu-RGD-BBN (RGD is arginine-glycine-aspartate acid, and BBN is bombesin) peptides and then labeled with 18F via the 4-nitrophenyl-2-18F-fluoropropionate prosthetic group. Cytotoxicity and cell-binding assay of QD-RGD-BBN were performed with PC-3 cells. In vivo dual-modality PET/NIRF imaging of prostate tumor–bearing mice was investigated using QD-RGD-BBN and 2-18F-fluoropropionyl-QD-RGD-BBN (18F-FP-QD-RGD-BBN). An in vivo biodistribution study of 18F-FP-QD-RGD-BBN was performed on normal mice. Results: QD-RGD-BBN exhibited strong red luminescence (600–800 nm) with the same maximum fluorescence wavelength (705 nm) as QD705 and slightly lower toxicity than that of QD705 in PC-3 cells at concentrations of greater than 30 μg/mL. Uptake of QD-RGD-BBN in PC-3 cells showed no significant decrease in the presence of an excess amount of dimer arginine-glycine-aspartate acid (RGD2) or bombesin(7–14) (BBN) peptide but was blocked significantly in the presence of an excess amount of NH2-RGD-BBN. Dual-function PET/NIRF imaging is able to accurately assess the biodistribution and tumor-targeting efficacy of the 18F-labeled functionalized QDs. Conclusion: The functionalized QD probe has great potential as a universal dual-targeting probe for detecting tumors in living subjects, opening up a new strategy for the development of multitargeting multimodality 18F-labeled QD probes with improved tumor-targeting efficacy.

Radiosynthesis and Biological Evaluation of N-[18F]Labeled Glutamic Acid as a Tumor Metabolic Imaging Tracer

We have previously reported that N-(2-[18F]fluoropropionyl)-L-methionine ([18F]FPMET) selectively accumulates in tumors. However, due to the poor pharmacokinetics of [18F]FPMET in vivo, the potential clinical translation of this observation is hampered. In this study, we rationally designed and synthesized [18F] or [11C]labeled N-position L-glutamic acid analogues for tumor imaging. N-(2-[18F]fluoropropionyl)-L-glutamic acid ([18F]FPGLU) was synthesized with a 30±10% (n = 10, decay-corrected) overall radiochemical yield and a specific activity of 40±25 GBq/μmol (n = 10) after 130 min of radiosynthesis. In vitro cell experiments showed that [18F]FPGLU was primarily transported through the XAG – system and was not incorporated into protein. [18F]FPGLU was stable in urine, tumor tissues, and blood. We were able to use [18F]FPGLU in PET imaging and obtained high tumor to background ratios when visualizing tumors tissues in animal models.

Radiosynthesis and biological evaluation of 5-(3-[18F]Fluoropropyloxy)-L-tryptophan for tumor PET imaging

INTRODUCTION [(18)F]FDG PET has difficulty distinguishing tumor from inflammation in the clinic because of the same high uptake in nonmalignant and inflammatory tissue. In contrast, amino acid tracers do not accumulate in inflamed tissues and thus provide an excellent opportunity for their use in clinical cancer imaging. In this study, we developed a new amino acid tracer 5-(3-[(18)F]Fluoropropyloxy)-L-tryptophan ([(18)F]-L-FPTP) by two-step reactions and performed its biologic evaluation. METHODS [(18)F]-L-FPTP was prepared by [(18)F]fluoropropylation of 5-hydroxy-L-tryptophan disodium salt and purification on C18 cartridges. The biodistribution of [(18)F]-L-FPTP was determined in normal mice and the incorporation of [(18)F]-L-FPTP into tissue proteins was investigated. In vitro competitive inhibition experiments were performed with Hepa1-6 hepatoma cell lines. [(18)F]-L-FPTP PET imaging was performed on tumor-bearing and inflammation mice and compared with [(18)F]-L-FEHTP PET. RESULTS The overall uncorrected radiochemical yield of [(18)F]-L-FPTP was 21.1 ± 4.4% with a synthesis time of 60 min, the radiochemical purity was more than 99%. Biodistribution studies demonstrate high uptake of [(18)F]-L-FPTP in liver, kidney, pancreas, and blood at the early phase, and fast clearance in most tissues over the whole observed time. The uptake studies in Hepa1-6 cells suggest that [(18)F]-L-FPTP is transported by the amino acid transport system B(0,+), LAT2 and ASC. [(18)F]-L-FPTP displays good stability and is not incorporated into proteins in vitro. PET imaging shows that [(18)F]-L-FPTP can be a better potential PET tracer for differentiating tumor from inflammation than [(18)F]FDG and 5-(3-[(18)F]fluoroethyloxy)-L-tryptophan ([(18)F]-L-FEHTP), with high [(18)F]-L-FPTP uptake ratio (2.53) of tumor to inflammation at 60 min postinjection. CONCLUSIONS Using [(18)F]fluoropropyl derivatives as intermediates, the new tracer [(18)F]-L-FPTP was achieved with good yield and radiochemical purity, and the biological evaluation results of [(18)F]-L-FPTP showed that it was a hopeful tracer for PET tumor imaging.

Positron emission tomography imaging of cardiomyocyte apoptosis with a novel molecule probe [ 18 F]FP-DPAZn2

Cardiomyocyte apoptosis plays a causal role in the development and progression of heart failure. Currently, there is no effective imaging agent that can be used to detect cardiomyocyte apoptosis in vivo. To target phosphatidylserine (PS) on the surface of the dying cell, we synthesized a novel 18F-labeled Zn2+-dipicolylamine (DPA) analog, [18F]FP-DPAZn2, and evaluated it for noninvasive imaging of cardiomyocyte apoptosis. In vitro, the fluorescence imaging of dansyl-DPAZn2 was suitable for detecting cardiomyocyte apoptosis, which was confirmed by confocal immunofluorescence imaging, terminal dUTP nick-end labeling (TUNEL) assay, and western blot assay. The in vivo biodistribution showed that the uptake ratios of [18F]FP-DPAZn2 in the heart were 4.41±0.29% ID/g at 5 min, 2.40 ± 0.43% ID/g at 30 min, 1.63 ± 0.26% ID/g at 60 min, and 1.43% ± 0.07 ID/g at 120 min post-injection. In vivo, the [18F]FP-DPAZn2 PET images showed more cardiac accumulation of radioactivity 60 min post-injection in acute myocardial infarction (AMI) rats than in normal rats, which was consistent with the findings of a histological analysis of the rat cardiac tissues in vitro. [18F]FP-DPAZn2 PET imaging has the capability for myocardial apoptosis detection, but the method will require improved myocardial uptake for the noninvasive evaluation of cardiomyocyte apoptosis in clinical settings.

Comparative uptake of 18F-FEN-DPAZn2, 18F-FECH, 18F-fluoride, and 18F-FDG in fibrosarcoma and aseptic inflammation

The aim of this study is to evaluate uptake of 2-(18)F-fluoroethyl-bis(zinc(II)-dipicolylamine) ((18)F-FEN-DPAZn2) as a promising cell death imaging agent, a choline analog (18)F-fluoroethylcholine ((18)F-FECH), (18)F-fluoride as a bone imaging agent, and a glucose analog 2-(18)F-fluoro-2-deoxy-d-glucose ((18)F-FDG) in the combined S180 fibrosarcoma and turpentine-induced inflammation mice models. The results showed that (18)F-FDG had the highest tumor-to-blood uptake ratio and tumor-to-muscle ratio, and high inflammation-to-blood ratio and inflammation-to-muscle ratio. (18)F -FECH showed moderate tumor-to-blood ratio and tumor-to-muscle ratio, and low inflammation-to-blood ratio and inflammation-to-muscle ratio. However, accumulation of (18)F FEN-DPAZn2 in tumor was similar to that in normal muscle. Also, (18)F-FEN-DPAZn2 and (18)F-fluoride exhibited the best selectivity to inflammation. (18)F-FECH positron emission tomography (PET) imaging demonstrates some advantages over (18)F-FDG PET for the differentiation of tumor from inflammation. (18)F FEN-DPAZn2 and (18)F-fluoride can be used for PET imaging of aseptic inflammation.

18F-FP-PEG2-β-Glu-RGD2: A Symmetric Integrin αvβ3-Targeting Radiotracer for Tumor PET Imaging

Radiolabeled cyclic arginine-glycine-aspartic (RGD) peptides can be used for noninvasive determination of integrin αvβ3 expression in tumors. In this study, we performed radiosynthesis and biological evaluation of a new 18F-labeled RGD homodimeric peptide with one 8-amino-3,6-dioxaoctanoic acid (PEG2) linker on the glutamate β-amino group (18F-FP-PEG2-β-Glu-RGD2) as a symmetric PET tracer for tumor imaging. Biodistribution studies showed that radioactivity of 18F-FP-PEG2-β-Glu-RGD2 was rapidly cleared from blood by predominately renal excretion. MicroPET-CT imaging with 18F-FP-PEG2-β-Glu-RGD2 revealed high tumor contrast and low background in A549 human lung adenocarcinoma-bearing mouse models, PC-3 prostate cancer-bearing mouse models, and orthotopic transplanted C6 brain glioma models. 18F-FP-PEG2-β-Glu-RGD2 exhibited good stability in vitro and in vivo. The results suggest that this tracer is a potential PET tracer for tumor imaging.

Molecular PET Imaging of Cyclophosphamide Induced Apoptosis with 18F-ML-8

In this paper, a novel small-molecular apoptotic PET imaging probe, 18F-ML-8 with a malonate motif structure, is presented and discussed. After study, the small tracer that belongs to a member of ApoSense family is proved to be capable of imaging merely apoptotic regions in the CTX treated tumor-bearing mice. The experimental result is further confirmed by in vitro cell binding assays and TUNEL staining assay. As a result, 18F-ML-8 could be used for noninvasive visualization of apoptosis induced by antitumor chemotherapy.

Human Biodistribution and Radiation Dosimetry of S-11C-Methyl-L-Cysteine Using Whole-Body PET.

Purpose S-11C-Methyl-L-cysteine (11C-MCYS) is a recently developed amino acid PET tracer for tumor imaging. The present study estimated human radiation absorbed dose of 11C-MCYS in healthy volunteers based on whole-body PET imaging. Methods Five sequential whole-body PET scans were performed on 6 healthy volunteers after injection of 11C-MCYS. Each scan contained of approximately 7 to 10 bed positions, and total scan time of each volunteer was approximately 70 to 85 minutes. Regions of interest were drawn on PET images of source organs. Residence times of 13 source organs for men and 14 source organs for women were calculated from the organ-specific time-activity curves. Absorbed dose estimates were performed from organ residence time by using the medical internal radiation dosimetry method. Results All volunteers showed initial high uptake in liver, heart, kidneys, pancreas, spleen, and uterus (only women), and followed by rapid clearance. There was very little activity residual in most of the organs except for the liver at the last emission scan time (approximately 75 minutes). The liver was the dose-limiting critical organ with the highest radiation-absorbed dose (1.01E-02 ± 2.64E-03 mGy/MBq), followed by the heart (9.09E-03 ± 1.40E-03 mGy/MBq), and the kidneys (7.12E-03 ± 9.44E-04 mGy/MBq). The effective dose to the whole body was 4.03E-03 ± 1.65E-04 mSv/MBq. A routine injection of 555 MBq (15 mCi) of 11C-MCYS would lead to an estimated effective dose of 2.24 ± 0.092 mSv. Conclusions The potential radiation risks associated with 11C-MCYS PET imaging are within accepted limits. 11C-MCYS is a safe amino acid PET tracer for tumor imaging and can be used in further clinical studies.

Radiation dosimetry estimation of N-(2-[18F]fluoropropionyl)- l-glutamate based on the mice distribution data

N-(2-[(18)F]fluoropropionyl)-l-glutamate([(18)F]FPGLU) was a recently developed potential amino acid tracer for tumor imaging with positron emission tomography-computer tomography (PET-CT). The absorbed and effective radiation doses resulting from the intravenous administration of [(18)F]FPGLU were estimated using biodistribution data from normal mice. The methodology recommended by Medical Internal Radiation Dose Committee (MIRD) was used to estimate the doses. The highest uptake of [(18)F]FPGLU was found in the kidneys, followed by the liver and lung. The kidneys were the organ received the highest absorbed dose, 58.4μGy/MBq, the brain received the lowest dose, 5.5μGy/MBq, and other organs received doses in the range of 8.3-11.9μGy/MBq. The effective dose was 17.0μSv/MBq. The data show that a 370MBq (10mCi) injection of [(18)F]FPGLU would lead to an estimated effective dose of 6.3mSv, which is within the accepted range of routine nuclear medicine investigations.