Modified "4 + 1" mixed ligand technetium-labeled fatty acids for myocardial imaging: evaluation of myocardial uptake and biodistribution.

Our group previously synthesized 99m Tc-labeled fatty acids suitable for myocardial metabolism and flow imaging. In this set of experiments, 29 new analogues were synthesized according to the "4 + 1" mixed ligand approach with some specific differences. Conventional "4 + 1" 99m Tc-fatty acids are built in the sequence: Tc-chelate, alkyl chain, and carboxylic group.

Myocardial uptake and biodistribution of newly designed technetium-labelled fatty acid analogues.

Purpose: In an effort to develop 99mTc-labelled fatty acids (FAs) for myocardial metabolism and flow imaging, several Tc analogues according to the '3+1' and the '4+1' mixed-ligand approach were synthesized and myocardial extraction was evaluated in non-working isolated guinea pig hearts. An example of biodistribution patterns in guinea pigs was determined by using one FA analogue.

Methods: The coordination moieties contain a +5, respectively +3, oxidation state metal core attached to the end position of a FA chain.

Cluster core controlled reactions of substitution of terminal bromide ligands by triphenylphosphine in octahedral rhenium chalcobromide complexes.

Reactions of rhenium chalcobromides Cs4[{Re6(mu3-S)8}Br6].2H2O, Cs3[{Re6(mu3-Se)8}Br6].2H2O, Cs3[{Re6(mu3-Q)7(mu3-Br)}Br6].

Synthesis and biological evaluation of a new type of 99mtechnetium-labeled Fatty Acid for myocardial metabolism imaging.

Technetium-labeled fatty acids intended for myocardial metabolism imaging and the respective rhenium model complexes were synthesized according to the "4 + 1" mixed-ligand approach and investigated in vitro and in vivo. The non-radioactive rhenium model complexes were characterized by NMR, IR, and EA, and the geometrical impact of the chelate unit on the integrity of the fatty acid head structure was determined by single-crystal X-ray analyses. To estimate the diagnostic value of the 99mTc-labeled fatty acids, the compounds were investigated in experiments in vitro and in biodistribution studies using male Wistar rats.

Synthesis and biological evaluation of tricarbonyl Re(I) and Tc(I) complexes anchored by poly(azolyl)borates: application on the design of radiopharmaceuticals for the targeting of 5-HT1A receptors.

The building blocks fac-[(99m)Tc{kappa(3)-HB(tim(Me))(3)}(CO)(3)] and fac-[(99m)Tc{kappa(3)-R(mu-H)B(tim(Me))(2)}(CO)(3)] [R is H (4a), Ph (5a); tim(Me) is 2-mercapto-1-methylimidazolyl] were obtained almost quantitatively by reacting fac-[(99m)Tc(CO)(3)(H(2)O)(3)](+) with the corresponding scorpionate. These compounds cross the intact blood-brain barrier in mice, with significant retention in the case of 4a and 5a. Using 4a as the lead structure, we have synthesized the functionalized complexes fac-[M{kappa(3)-H(mu-H)B(tim(Bu-pip))(2)}(CO)(3)] [M is Re (8), (99m)Tc (8a); tim(Bu-pip) is methyl[4-((2-methoxyphenyl)-1-piperazinyl)butyl](2-mercapto-1-methylimidazol-5-yl)methanamide] and fac-[M{kappa (3)-H(mu-H)B(tim(Me))(tim(Bu-pip))}(CO)(3)] [M is Re (9), (99m)Tc (9a)] and evaluated their potential as radioactive probes for the targeting of brain 5-HT(1A) serotonergic receptors.

Novel rhenium chelate system derived from dimercaptosuccinic acid for the selective labeling of biomolecules.

This work is part of an effort to develop chelating agents for stable binding and easy conjugation of Re-188 to biologically interesting structures. Starting from the well-known in vivo stability of [(188)ReO(DMSA)(2)](-), we want to exploit this coordination system for the design of (188)ReO(V) chelates, which are stable toward reoxidation to perrhenate and toward ligand exchange under all conditions of radiopharmaceutical development. Therefore, a new type of tetradentate ligand has been synthesized by bridging two molecules of N,N'-diisobutyl-2,3-dimercaptosuccinamide with N-(3-aminopropyl)propane-1,3-diamine.

Mixed-ligand rhenium-188 complexes with tetradentate/monodentate NS3/P ('4 + 1') coordination: relation of structure with antioxidation stability.

Development of new radiopharmaceuticals based on rhenium-188 depends on finding appropriate ligands able to give complexes with high in vivo stability. Rhenium(III) mixed-ligand complexes with tetradentate/monodentate ('4 + 1') coordination of the general formula [Re(NS(3))(PRR'R' ')] (NS(3) = tris(2-mercaptoethyl)amine and derivatives thereof, PRR'R' ' = phosphorus(III) ligands) appear to be among the promising tools to achieve this goal. According to this approach, we synthesized and characterized a series of rhenium model complexes.

Synthesis, characterization, and biological evaluation of neutral nitrido technetium(V) mixed ligand complexes containing dithiolates and aminodiphosphines. A novel system for linking technetium to biomolecules.

A new biomolecule labeling method that utilizes the [(99m)Tc(N)(PNP)](2+) metal fragment is presented. Thus, a series of nitrido mixed-ligand M(V) complexes (M = (99m)Tc, (99g)Tc, Re), [M(N)(Ln)(PNP)], where Ln is the dianionic form of a dithiolate or substituted-dithiolate ligand and PNP is an aminodiphosphine, is described. (99m)Tc complexes can be prepared using either a two-step or a three-step procedure starting from generator-eluted pertechnetate through a prereduced mixture of [(99m)Tc(N)]-containing species, followed by sequential or contemporary addition of the relevant dithiolate and aminodiphosphine.

Synthesis, characterization, and biological evaluation of technetium(III) complexes with tridentate/bidentate S,E,S/P,S coordination (E = O, N(CH(3)), S): a novel approach to robust technetium chelates suitable for linking the metal to biomolecules.

A novel type of mixed-ligand Tc(III) complexes, [Tc(SCH(2)CH(2)-E-CH(2)CH(2)S)(PR(2)S)] (E = S, N(CH(3)); PR(2)S = phosphinothiolate with R = aryl, alkyl) is described. These "3+2"-coordinated complexes can be prepared in a two-step reduction/substitution procedure via the appropriate chloro-containing oxotechnetium(V) complex [TcO(SES)Cl] [E=S, N(CH(3)]. Tc(III) compounds have been fully characterized both in solid and solution states and found to adopt the trigonal-bipyramidal coordination geometry.