New (68)Ga-PhenA bisphosphonates as potential bone imaging agents.

INTRODUCTION: In vivo positron emission tomography (PET) imaging of the bone using [(68)Ga]bisphosphonates may be a valuable tool for cancer diagnosis and monitoring therapeutic treatment. We have developed new [(68)Ga]bisphosphonates based on the chelating group, AAZTA (6-[bis(hydroxycarbonyl-methyl)amino]-1,4-bis(hydroxycarbonyl methyl)-6-methylperhydro-1,4-diazepine). METHOD: Phenoxy derivative of AAZTA (2,2'-(6-(bis(carboxymethyl)amino)-6-((4-(2-carboxyethyl)phenoxy)methyl)-1,4-diazepane-1,4-diyl)diacetic acid), PhenA, 2, containing a bisphosphonate group (PhenA-BPAMD, 3, and PhenA-HBP, 4) was prepared. Labeling of these chelating agents with (68)Ga was evaluated. RESULTS: The ligands reacted rapidly in a sodium acetate buffer with [(68)Ga]GaCl3 eluted from a commercially available (68)Ge/(68)Ga generator (pH4, >95% labeling at room temperature in 5min) to form [(68)Ga]PhenA-BPAMD, 3, and [(68)Ga]PhenA-HBP, 4. The improved labeling condition negates the need for further purification. The (68)Ga bisphosphonate biodistribution and autoradiography of bone sections in normal mice after an iv injection showed excellent bone uptake. CONCLUSION: New (68)Ga labeled bisphosphonates may be useful as in vivo bone imaging agents in conjunction with positron emission tomography (PET).

Synthesis and evaluation of 18F labeled alanine derivatives as potential tumor imaging agents.

INTRODUCTION: This paper reports the synthesis and labeling of (18)F alanine derivatives. We also investigate their biological characteristics as potential tumor imaging agents mediated by alanine-serine-cysteine preferring (ASC) transporter system. METHODS: Three new (18)F alanine derivatives were prepared from corresponding tosylate-precursors through a two-step labeling reaction. In vitro uptake studies to evaluate and to compare these three analogs were carried out in 9L glioma and PC-3 prostate cancer cell lines. Potential transport mechanisms, protein incorporation and stability of 3-(1-[(18)F]fluoromethyl)-L-alanine (L-[(18)F]FMA) were investigated in 9L glioma cells. Its biodistribution was determined in a rat-bearing 9L tumor model. PET imaging studies were performed on rat bearing 9L glioma tumors and transgenic mouse carrying spontaneous generated M/tomND tumor (mammary gland adenocarcinoma). RESULTS: New (18)F alanine derivatives were prepared with 7%-34% uncorrected radiochemical yields, excellent enantiomeric purity (>99%) and good radiochemical purity (>99%). In vitro uptake of the L-[(18)F]FMA in 9L glioma and PC-3 prostate cancer cells was higher than that observed for the other two alanine derivatives and [(18)F]FDG in the first 1h. Inhibition of cell uptake studies suggested that L-[(18)F]FMA uptake in 9L glioma was predominantly via transport system ASC. After entering into cells, L-[(18)F]FMA remained stable and was not incorporated into protein within 2h. In vivo biodistribution studies demonstrated that L-[(18)F]FMA had relatively high uptake in liver and kidney. Tumor uptake was fast, reaching a maximum within 30 min. The tumor-to-muscle, tumor-to-blood and tumor-to-brain ratios at 60 min post injection were 2.2, 1.9 and 3.0, respectively. In PET imaging studies, tumors were visualized with L-[(18)F]FMA in both 9L rat and transgenic mouse. CONCLUSION: L-[(18)F]FMA showed promising properties as a PET imaging agent for up-regulated ASC transporter associated with tumor proliferation.

Synthesis and comparative biological evaluation of L- and D-isomers of 18F-labeled fluoroalkyl phenylalanine derivatives as tumor imaging agents.

INTRODUCTION: L-amino acid-based tracers have established their important role as tumor metabolic imaging agents. Recently, a number of studies demonstrated that D-amino acids may have improved imaging properties than their corresponding L-isomers. We synthesized and evaluated the D-isomer of a new phenylalanine derivative, p-(2-[(18)F]fluoroethyl)-phenylalanine ([(18)F]FEP), in comparison to its L-isomer and previously reported the L- and D-isomers of O-(2-[(18)F]fluoroethyl)-tyrosine ([(18)F]FET). METHODS: L- and D-Isomers of [(18)F]FET and [(18)F]FEP were successfully synthesized via a rapid and efficient two-step nucleophilic fluorination and deprotection reaction. In vitro studies were carried out in 9L glioma cells. In in vivo studies, Fisher 344 rats bearing the 9L tumor model were used. RESULTS: L- and D-Isomers of (18)F-fluoroalkyl tyrosine and phenylalanine derivatives were efficiently labeled with high enantiomeric purity (>95%), good yield (11-45%) and high specific activity (21-75 GBq/µmol). D-[(18)F]FEP showed a similar linear time-dependent uptake as D-[(18)F]FET, while their corresponding L-isomers had much faster and higher uptake (4.3- to 16.0-fold at maximum uptake). The maximum uptake of the new compounds, L- and D-[(18)F]FEP, was 1.4- and 5.2-fold of that reported for L- and D-[(18)F]FET, respectively. Transport characterization studies indicated that both L- and D-[(18)F]FEP were selective substrates for system L. While L-[(18)F]FEP exhibited preference towards one subtype of system L, LAT1, D-[(18)F]FEP did not exhibit the same preference. Small animal PET imaging studies showed that both L- and D-[(18)F]FEP had higher uptake in 9L tumor compared to surrounding tissues, but D-isomer had lower tumor-to-muscle ratio in comparison with its L-isomer. CONCLUSION: Both L- and D-[(18)F]FEP are substrates for system L amino acid transporter with different preference toward its subtypes. Small animal imaging studies of 9L tumor showed that D-[(18)F]FEP did not show better imaging properties than their corresponding L-isomer.

Synthesis, uptake mechanism characterization and biological evaluation of (18)F labeled fluoroalkyl phenylalanine analogs as potential PET imaging agents.

INTRODUCTION: Amino acids based tracers represent a promising class of tumor metabolic imaging agents with successful clinical applications. Two new phenylalanine derivatives, p-(2-[(18)F]fluoroethyl)-L-phenylalanine (FEP, [(18)F]2) and p-(3-[(18)F]fluoropropyl)-L-phenylalanine (FPP, [(18)F]3) were synthesized and evaluated in comparison to clinically utilized O-(2-[(18)F]fluoroethyl)-L-tyrosine (FET, [(18)F]1). METHODS: FEP ([(18)F]2) and FPP ([(18)F]3) were successfully synthesized by a rapid and efficient two-step nucleophilic fluorination of tosylate precursors and deprotection reaction. In vitro cell uptake studies were carried out in 9L glioma cells. In vivo studies, 9L tumor xenografts were implanted in Fisher 344 rats. RESULTS: FEP ([(18)F]2) and FPP ([(18)F]3) could be efficiently labeled within 90 min with good enantiomeric purity (>95%), good yield (11-37%) and high specific activity (21-69 GBq/µmol). Cell uptake studies showed FEP had higher uptake than FPP as well as reference ligand FET ([(18)F]1). Uptake mechanism studies suggested that FEP is a selective substrate for system L and prefers its subtype LAT1. In vivo biodistribution studies demonstrated FEP had specific accumulation in tumor cells and tumor to background ratio reached 1.45 at 60 min. Small animal positron emission tomography (PET) imaging studies showed FEP was comparable to FET for imaging rats bearing 9L tumor model. FEP had high uptake in 9L tumor compared to surrounding tissue and was quickly excreted through urinary tract. CONCLUSION: Biological evaluations indicate that FEP ([(18)F]2) is a potential useful tracer for tumor imaging with PET.

In vivo quantitative noninvasive imaging of gene transfer by single-photon emission computerized tomography.

Systems aimed at detecting gene expression noninvasively in vivo are desirable for evaluating the outcome of gene transfer in clinical trials. Several approaches have been exploited using magnetic resonance imaging and spectroscopy ((31)P MRS), positron emission tomography (PET), single-photon emission tomography (SPECT), and detection of bioluminescent signals. An ideal system is based on transfer of a marker gene, the activity of which can be detected against a background from the target tissue without interfering with normal physiology or eliciting an immune response. The majority of approaches described to date use genes encoding a nonmammalian protein that can elicit immune responses or a transmembrane receptor as a marker gene whose ectopic expression may cause aberrant signaling in the target cell through binding to endogenous ligands. The dopamine transporter (DAT) is normally expressed at high levels, mainly in the dopaminergic neurons of the central nervous system. We previously synthesized a radioactive ligand, [(99m)Tc]TRODAT-1, that binds with high affinity to the dopamine transporter, allowing for SPECT imaging of the striatum in normal control subjects and individuals affected with Parkinson's disease. Here we describe a strategy to monitor gene transfer based on adeno-associated viral vector (AAV)-mediated transduction of DAT in murine muscle followed by [(99m)Tc]TRODAT-1 imaging by SPECT of cells expressing the transgene. We show that quantitative, noninvasive imaging of gene transfer is successfully achieved in vivo, using a single-photon computed tomography camera. This system employs a reporter gene encoding a mammalian protein that is absent in most tissues, has no enzymatic activity, and does not activate intracellular pathways. This should be useful to monitor gene transfer in the settings of gene therapy.