Amino Acids Labeled with [99mTc(CO)3]+and Recognized by thel-type Amino Acid Transporter LAT1

An Organometallic Isostere of an Amino Acid

An organometallic complex that mimics an amino acid, also known as an amino acid isostere, can be synthesized from a functionalized bipyridine ligand and a fac-[Re(CO)₃]⁺ center. The reaction of an achiral ligand and metal results in a racemic mixture of chiral-at-metal complexes. These metal species have amine and carboxy termini, a side chain type unit that can be varied, as well as the chiral metal that is analogous to the α carbon of an amino acid. The racemic mixtures can be separated into enantiomers by chiral chromatography, and the metal complexes can be incorporated into peptides by using solid-phase peptide synthesis.

The "Carbonyl Story" and Beyond; Experiences, Lessons and Implications

The complex [^99m Tc(OH₂ )₃ (CO)₃ ]⁺ has become a versatile building block in radiopharmaceutical chemistry, applied by many groups worldwide. However, despite widespread efforts, only one compound has made it right the way through clinical trials. Along the way from its discovery to its development into an eventual product, the author experienced issues that he would handle differently in retrospect. In this article, these experiences are turned into "lessons" that might be helpful for young researchers finding themselves in similar situations. Beside issues with patenting and company strategies, the carbonyl story has provided scientific implications beyond its own story, and insights from which any future ^99m Tc-based chemistry for radiopharmacy or molecular imaging might benefit.

Multifunctional Cyclopentadienes as a Scaffold for Combinatorial Bioorganometallics in [(η5 -C5 H2 R1 R2 R3 )M(CO)3 ] (M=Re, 99m Tc) Piano-Stool Complexes

Multifunctional cyclopentadiene (Cp) ligands and their rhenium and ^99m Tc complexes were prepared by a versatile synthetic route. The properties of these Cp ligands can be tuned on demand, either during their synthesis (variation of R₁ ) or through post-synthetic functionalization with two equal or different vectors (V₁ and V₂ ). Variation of these groups enables a combinatorial approach in the synthesis of bioorganometallic complexes. This is demonstrated by the preparation of Cp ligands containing both electron-donating and electron-withdrawing groups at the R₁ position and their subsequent homo- or heterofunctionalization with biovector models (benzylamine and phenylalanine) under standard amide bond-formation conditions. All ligands can be coordinated to the fac-[Re(CO)₃ ]⁺ and fac-[^99m Tc(CO)₃ ]⁺ cores to give tetrafunctional complexes in straightforward and functional-group-tolerant procedures. The ^99m Tc complexes were prepared in one step, in 30 min, and under aqueous conditions from generator-eluted [^99m TcO₄ ]^- .

Technetium-99m complexes of l-arginine derivatives for targeting amino acid transporters

Although relevant from the clinical point of view, radiotracers targeting cationic amino acid transporters are relatively unexplored and, in particular, no metal-based radiotracers are known. The rare examples of complexes recognized by amino acid transporters, namely by the Na⁺-independent neutral l-type amino acid transporter 1 (LAT1), are ^99mTc(i)/Re(i) compounds. Herein, we describe conjugates comprising a pyrazolyl-diamine chelating unit and the cationic amino acid l-arginine (l-Arg) linked by a propyl (L1) or hexyl linker (L2), which allowed the preparation of stable complexes of the type fac-[^99mTc(CO)₃(k³-L)]⁺ (Tc1, L = L1; Tc2, L = L2) and of the respective surrogates Re1 and Re2. Interestingly, complex Tc2 exhibited moderate levels of time-dependent internalization in three human tumoural cell lines, with approximately 3% of total applied activity internalized, corresponding to 21% of the cell-associated activity. A putative mechanism of retention in the cytoplasm of cells could be the interaction of the complex with inducible nitric oxide synthase (iNOS), which is the enzyme responsible for the catalytic oxidation of l-Arg to citrulline and nitric oxide. However, the surrogate complex Re2 does not recognize iNOS, as demonstrated by the in vitro assays with purified iNOS and in studies with lipopolysaccharide(LPS)-activated macrophages. Preliminary mechanistic studies suggest that the internalization of Tc2 is linked to the cationic amino acid transporters, namely system y⁺. This finding might open the way towards the development of novel families of metal-based radiotracers for probing metabolically active cancer cells.

Structure and reactivities of rhenium and technetium bis-arene sandwich complexes [M(η6-arene)2]+

Rhenium and ⁹⁹Tc bis-arene complexes for a molecule-based theranostic approach are presented. Conjugation of biovectors to benzene or substitution of naphthalene allows integration of {Re(η⁶-C₆H₆)}⁺ in pharmaceutical lead structures.

Crystal structure of fac-aquatricarbonyl[(S)-valin-ato-κ(2) N,O]-rhenium(I)

In the mol-ecule of the title compound, [Re(C5H10NO2)(CO)3(H2O)], the Re(I) atom adopts a distorted octa-hedral coordination sphere defined by one aqua and three carbonyl ligands as well as one amino N and one carboxyl-ate O atom of the chelating valinate anion. The carbonyl ligands are arranged in a fac-configuration around the Re(I) ion. In the crystal, an intricate hydrogen-bonding system under participation of two O-H, two N-H and one C-H donor groups and the carboxyl-ate and carbonyl O atoms as acceptor groups contribute to the formation of a three-dimensional supra-molecular network.

Re(I) and Tc(I) complexes for targeting nitric oxide synthase: influence of the chelator in the affinity for the enzyme

Aiming to design (99m) Tc complexes for probing nitric oxide synthase (NOS) by SPECT, we synthesized conjugates (L4-L6) comprising a NOS-recognizing moiety connected to a diamino-propionic acid (dap) chelating unit. The conjugates led to complexes of the type fac-[M(CO)3 (ĸ(3) -L)] (M = Re/(99m) Tc; Re4/Tc4: L = L4; Re5/Tc5: L = L5; Re6/Tc6: L = L6). Enzymatic studies showed that L4 and L5, but not L6, gave complexes (Re4 and Re5) that are less potent than the conjugates. To rationalize these results, we performed docking and molecular dynamics simulations. The high affinity of L4 and L5 is due to the strong interactions between the dap chelator and polar residues of the binding cavity. These interactions are hampered by metallation resulting in complexes with lower affinity. The higher potency of Re5 compared to Re4 was assigned to the increased bulkiness of Re5 and the presence of additional anchoring groups that better fit the active site and provide more extensive contacts. In turn, Re6 is too bulky and its organometallic tail is oriented toward the peripheral pocket of iNOS, leading to loss of contacts and a lower affinity. These results were compared with our previous results obtained with analogue complexes stabilized by a pyrazolyl-diamine chelating unit.

Antimicrobial efficacy of phenanthrenequinone based Schiff base complexes incorporating methionine amino acid: structural elucidation and in vitro bio assay

This work focuses the synthesis and characterization of few novel mixed ligand Schiff base metal complexes and their biological activities. For deriving the structural aspects, spectral techniques such as FT-IR, UV-Vis., (1)H NMR, Raman, EPR and the physicochemical characterizations including elemental analysis, molar conductance and magnetic susceptibility method have been involved. All the complexes adopt square planar geometry. DNA binding ability of these complexes has been explored using diverse techniques viz. UV-Vis. absorption, fluorescence spectroscopy, viscometry and cyclic voltammetry. These studies prove that CT-DNA binding of the complexes follows the intercalation mode. Comparative DNA oxidative cleavage ability of the complexes has been done under ultraviolet photo radiation on pUC19 DNA. In addition, the biocidal action of the complexes has been investigated against few pathogenic bacteria and fungi by disc diffusion method. Importantly, the amylase inhibition activity of Cu(II) complex has been explored. The amylase inhibition property has been found to be increased upon increasing the complex concentration.

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.

Orthogonally protected artificial amino acid as tripod ligand for automated peptide synthesis and labeling with [(99m)Tc(OH(2))(3)(CO)(3)](+)

1,2-Diamino-propionic acid (Dap) is a very strong chelator for the [(99m)Tc(CO)(3)](+) core, yielding small and hydrophilic complexes. We prepared the lysine based Dap derivative l-Lys(Dap) in which the ε-NH(2) group was replaced by the tripod through conjugation to its α-carbon. The synthetic strategy produced an orthogonally protected bifunctional chelator (BFC). The -NH(2) group of the α-amino acid portion is Fmoc- and the -NH(2) of Dap are Boc-protected. Fmoc-l-Lys(Dap(Boc)) was either conjugated to the N- and C-terminus of bombesin BBN(7-14) or integrated into the sequence using solid-phase peptide synthesis (SPPS). We also replaced the native lysine in a cyclic RGD peptide with l-Lys(Dap). For all peptides, quantitative labeling with the [(99m)Tc(CO)(3)](+) core at a 10 μM concentration in PBS buffer (pH = 7.4) was achieved. For comparison, the rhenium homologues were prepared from [Re(OH(2))(3)(CO)(3)](+) and Lys(Dap)-BBN(7-14) or cyclo-(RGDyK(Dap)), respectively. Determination of integrin receptor binding showed low to medium nanomolar affinities for various receptor subtypes. The IC(50) of cyclo-(RGDyK(Dap[Re(CO)(3)])) for α(v)β(3) is 7.1 nM as compared to 3.1 nM for nonligated RGD derivative. Biodistribution studies in M21 melanoma bearing nude mice showed reasonable α(v)β(3)-integrin specific tumor uptake. Altogether, orthogonally protected l-Lys(Dap) represents a highly versatile building block for integration in any peptide sequence. Lys(Dap)-precursors allow high-yield (99m)Tc-labeling with [(99m)Tc(OH(2))(3)(CO)(3)](+), forming small and hydrophilic complexes, which in turn leads to peptide radiopharmaceuticals with excellent in vivo characteristics.

APPLICATION OF TECHNETIUM AND RHENIUM IN NUCLEAR MEDICINE

Technetium and Rhenium are the two lower elements in the manganese triad. Whereas rhenium is known as an important part of high resistance alloys, technetium is mostly known as a cumbersome product of nuclear fission. It is less known that its metastable isotope 99mTc is of utmost importance in nuclear medicine diagnosis. The technical application of elemental rhenium is currently complemented by investigations of its isotope 188Re , which could play a central role in the future for internal, targeted radiotherapy. This article will briefly describe the basic principles behind diagnostic methods with radionuclides for molecular imaging, review the 99mTc -based radiopharmaceuticals currently in clinical routine and focus on the chemical challenges and current developments towards improved, radiolabeled compounds for diagnosis and therapy in nuclear medicine.

Preclinical evaluation of 99mTc(CO)3-aspartic-N-monoacetic acid, a renal radiotracer with pharmacokinetic properties comparable to 131I-o-iodohippurate

In an ongoing effort to develop a renal tracer with pharmacokinetic properties comparable to p-aminohippurate and superior to those of both (99m)Tc-mercaptoacetyltriglycine and (131)I-o-iodohippurate ((131)I-OIH), we evaluated a new renal tricarbonyl radiotracer based on the aspartic-N-monoacetic acid (ASMA) ligand, (99m)Tc(CO)(3)(ASMA). The ASMA ligand features 2 carboxyl groups and an amine function for the coordination of the {(99m)Tc(CO)(3)}(+) core as well as a dangling carboxylate to facilitate rapid renal clearance.

METHODS

rac-ASMA and l-ASMA were labeled with a (99m)Tc-tricarbonyl precursor, and radiochemical purity of the labeled products was determined by high-performance liquid chromatography. Using (131)I-OIH as an internal control, we evaluated biodistribution in normal rats with (99m)Tc(CO)(3)(ASMA) isomers and in rats with renal pedicle ligation with (99m)Tc(CO)(3)(rac-ASMA). Clearance studies were conducted in 4 additional rats. In vitro radiotracer stability was determined in phosphate-buffered saline, pH 7.4, and in challenge studies with cysteine and histidine. (99m)Tc(CO)(3)(ASMA) metabolites in urine were analyzed by high-performance liquid chromatography.

RESULTS

Both (99m)Tc(CO)(3)(ASMA) preparations had greater than 99% radiochemical purity and were stable in phosphate-buffered saline, pH 7.4, for 24 h. Challenge studies on both revealed no significant displacement of the ligand. In normal rats, the percentage injected dose in urine at 10 and 60 min for both preparations averaged, respectively, 103% and 106% that of (131)I-OIH. The renal clearances of (99m)Tc(CO)(3)(rac-ASMA) and (131)I-OIH were comparable (P = 0.48). The tracer was excreted unchanged in the urine, proving its in vivo stability. In pedicle-ligated rats, (99m)Tc(CO)(3)(rac-ASMA) had less excretion into the bowel (P < 0.05) than did (131)I-OIH and was better retained in the blood (P < 0.05).

CONCLUSION

Both (99m)Tc(CO)(3)(ASMA) complexes have pharmacokinetic properties in rats comparable to or superior to those of (131)I-OIH, and human studies are warranted for their further evaluation.

Charge dependent substrate activity of C3' and N3 functionalized, organometallic technetium and rhenium-labeled thymidine derivatives toward human thymidine kinase 1

Human cytosolic thymidine kinase (hTK1) has proven to be a suitable target for the noninvasive imaging of cancer cell proliferation using radiolabeled thymidine analogues such as [(18)F]3'-fluoro-3'-deoxythymidine ([(18)F]FLT). A thymidine analogue for single photon emission computed tomography (SPECT), which incorporates the readily available and inexpensive nuclide technetium-99m, would be of considerable practical interest. hTK1 is known to accommodate modification of the structure of the natural substrate thymidine at the positions N3 and C3' and, to a lesser extent, C5. In this work, we used the copper-catalyzed azide-alkyne cycloaddition to synthesize two series of derivatives in which thymidine is functionalized at either the C3' or N3 position with chelating systems suitable for the M(CO)(3) core (M = (99m)Tc, Re). The click chemistry approach enabled complexes with different structures and overall charges to be synthesized from a common precursor. Using this strategy, the first organometallic hTK1 substrates in which thymidine is modified at the C3' position were identified. Phosphorylation of the organometallic derivatives was measured relative to thymidine. We have shown that the influence of the overall charge of the derivatives is dependent on the position of functionalization. In the case of the C3'-functionalized derivatives, neutral and anionic substrates were most readily phosphorylated (20-28% of the value for the parent ligand thymidine), whereas for the N3-functionalized derivatives, cationic and neutral complexes were apparently better substrates for the enzyme (14-18%) than anionic derivatives (9%).

Syntheses of bifunctional 2,3-diamino propionic acid-based chelators as small and strong tripod ligands for the labelling of biomolecules with (99m)Tc

The labelling of targeting biomolecules requires small and hydrophilic complexes in order to not affect the binding properties of the vectors. 2,3-Diamino propionic acid (dap) is a small and strong, albeit scarcely used, tripod ligand for the fac-[(99m)Tc(CO)(3)](+) moiety. We have introduced at the alpha-carbon atom in the basic dap structure various second functionalities such as carboxylato, amino and alpha-amino acid groups via various spacers in order to yield bifunctional chelators. These dap derivatives can be coupled to targeting molecules for application in molecular imaging. Full characterizations of the bifunctional chelators, X-ray structures of intermediates and of one rhenium complex, as well as labelling studies with (99m)Tc, are presented.

Coordination modes of multidentate ligands in fac-[Re(CO)(3)(polyaminocarboxylate)] analogues of (99m)Tc radiopharmaceuticals. dependence on aqueous solution reaction conditions

We study Re analogues of (99m)Tc renal agents to interpret previous results at the (99m)Tc tracer level. The relative propensities of amine donors versus carboxylate oxygen donors of four L = polyaminocarboxylate ligands to coordinate in fac-[Re(I)(CO)(3)L](n) complexes were assessed by examining the reaction of fac-[Re(I)(CO)(3)(H(2)O)(3)](+) under conditions differing in acidity and temperature. All four L [N,N-bis-(2-aminoethyl)glycine (DTGH), N,N-ethylenediaminediacetic acid, diethylenetriamine-N-malonic acid, and diethylenetriamine-N-acetic acid] can coordinate as tridentate ligands while creating a dangling chain terminated in a carboxyl group. Dangling carboxyl groups facilitate renal clearance in fac-[(99m)Tc(I)(CO)(3)L](n) agents. Under neutral conditions, the four ligands each gave two fac-[Re(I)(CO)(3)L](n) products with HPLC traces correlating well with known traces of the fac-[(99m)Tc(I)(CO)(3)L](n) mixtures. Such mixtures are common in renal agents because the needed dangling carboxyl group can compete for a coordination site. However, the HPLC separations needed to assess the biodistribution of a single tracer are impractical in a clinical setting. One goal in investigating this Re chemistry is to identify conditions for avoiding this problem of mixtures in preparations of fac-[(99m)Tc(I)(CO)(3)L](n) renal tracers. After separation and isolation of the fac-[Re(I)(CO)(3)L](n) products, NMR analysis of all products and single crystal X-ray crystallographic analysis of both DTGH products, as well as one product each from the other L, allowed us to establish coordination mode unambiguously. The product favored in acidic conditions has a dangling amine chain and more bound oxygen. The product favored in basic conditions has a dangling carboxyl chain and more bound nitrogen. At the elevated temperatures used for simulating tracer preparation, equilibration was facile (ca. 1 h or less), allowing selective formation of one product by utilizing acidic or basic conditions. The results of this fundamental study offer protocols and guidance useful for the design and preparation of fac-[(99m)Tc(I)(CO)(3)L](n) agents consisting of a single tracer.

Synthesis, structural characterisation and anti-proliferative activity of NHC gold amino acid and peptide conjugates

We report the synthesis of new NHC gold(I) and NHC gold(III) halide, amino acid and dipeptide complexes. Transmetallation of the N-phenylalanine-substituted NHC silver complex 3 with Me2SAuCl yields the phenylalanine-NHC gold(I) conjugate 4a. Halide exchange with LiBr and oxidation of 4a with Br2 in CH2Cl2 yields the phenylalanine-NHC Au(I) and Au(III) bromides 4b and 4c, respectively. Reaction of N-Boc protected cysteine methyl ester (Boc-Cys-OMe) or the dipeptide N-Boc-Leu-Cys-OMe with the NHC gold chloride 6a yields the (NHC)Au-S complexed amino acid and dipeptide derivatives 8 and 9. The NHC gold(III) complexes 4c and 6c were characterised by single crystal X-ray analysis. All of the tested gold carbene complexes showed significant anti-tumor activity on the HeLa, HepG2 and HT-29 cancer cell lines. The best compounds show activity comparable to the well-known anti-cancer drug cisplatin. There seems to be no clear cut structure-activity relationship in the compounds tested, nor did we observe a dependence on the metal oxidation state or the different halide substituents. Given the ease of preparation, stability and high activity of the compounds described herein, it may be possible to design tumor-specific anti-cancer agents based on NHC gold amino acid conjugates in the future.

99m-Technetium carbohydrate conjugates as potential agents in molecular imaging

This feature article covers recent reports of work towards the development of (99m)Tc-carbohydrate based agents for use in SPECT imaging, particularly of cancerous tissue. An outline of some of the key biological functions and coordination chemistry of carbohydrates is given, along with an introduction to bioconjugation and molecular imaging. Technetium coordination chemistry and the subset of this involving bioconjugates are discussed before moving into the focus of the article: glycoconjugates of (99m)Tc(v) and the more recently developed [(99m)Tc(I)(CO)(3)](+). Significant work in the last decade has featured the very attractive [(99m)Tc(CO)(3)](+) core, and the ligand sets designed for this core are discussed in detail.

Kinetic and high-pressure mechanistic investigation of the aqua substitution in the trans-aquaoxotetracyano complexes of re(v) and tc(v): some implications for nuclear medicine

A kinetic study of the aqua substitution in the [TcO(OH(2))(CN)(4)](-) complex by different thiourea ligands (TU = thiourea, NMTU = N-methyl thiourea, NNDMTU = N, N'-dimethylthiourea) yielded second-order formation rate constants (25 degrees C) as follows [NNDMTU, NMTU, TU, respectively]: k(f) = 11.5 +/- 0.1, 11.38 +/- 0.04, and 7.4 +/- 0.1 M(-1)s(-1), with activation parameters: Delta H(#) (k(f) ) : 55 +/- 2, 42 +/- 3, 35 +/- 5 kJ mol(-1); DeltaS(#) (k(f) ) : - 40 +/- 8, - 84 +/- 11, - 110 +/- 17 J K(-1)mol(-1). A subsequent high-pressure investigation of the aqua substitution in the [ReO(OH(2))(CN)(4)](-) and [TcO(OH(2))(CN)(4)](-) complexes by selected entering ligands yielded DeltaV(#) (k(f) ) values as follows: Re(V): -1.7 +/- 0.3(NCS(-)), -22.1 +/- 0.9 (TU) and for Tc(V): -3.5 +/- 0.3(NCS(-)), -14 +/- 1 (NNDMTU), and -6.0 +/- 0.5 (TU) cm(3)mol (-1), respectively. These results point to an interchange associative mechanism for the negative NCS(-) as entering group but even a pure associative mechanism for the neutral thiourea ligands.