RP-HPLC separation of the diastereomers of technetium-99m labelled tropanes and identity confirmation using radio-LC-MS.

99mTc-TRODAT-1 (technetium(V)-oxo-2-[[2-[[[3-(4-chlorophenyl)-8-methyl-8-azabicyclo[3.2.1]oct-2-yl]methyl](2-mercaptoethyl)amino]ethyl]]amino]-ethanethiolato(3-)) and 99mTc-TRODAT-M, the 4-methylphenyl derivative of 99mTc-TRODAT-1, are at this moment being evaluated in clinical trials as imaging agents for the central nervous dopamine transporter system. Both compounds are formed as a mixture of two major diastereomers. As the tracer concentration in preparations for clinical investigations is very low (30-150 pmol/ml), identification of these 99mTc-complexes was, up to now, carried out indirectly using X-ray diffraction analysis of the corresponding rhenium complexes which can be synthesized in gram amounts. In this study, we developed a convenient and practical reversed phase HPLC-method for purification and isolation of the respective diastereomers of 99mTc-TRODAT-1 and three of its derivatives using mixtures of solvents which are compatible with biological studies, i.e. aqueous buffers and ethanol. Furthermore, direct identity confirmation of the 99mTc-complexes using radio-LC-MS was successfully elaborated.

Synthesis and biological evaluation of the four isomers of technetium-99m labeled ethylenecysteamine cysteine ((99m)Tc-ECC), the mono-acid derivative of (99m)tc-L,L-ethylenedicysteine.

A few years ago (99m)Tc-ethylenedicysteine ((99m)Tc-L,L-EC) had been proposed as an interesting substitute for technetium-99m labeled mercaptoacetyltriglycine (MAG3) as renal function tracer agent. It possesses in its structure two carboxylate functions and is in this respect different from other renal tracers such as (99m)Tc-N, N'-bis-(mercaptoacetyl)-2,3-diaminopropionate ((99m)Tc-CO(2)DADS), (99m)Tc-MAG3, and Hippuran, which have only one carboxylic group. To study whether both carboxylic acid groups of (99m)Tc-L,L-EC contribute to the efficient renal handling of this compound we synthesized and biologically evaluated the technetium-99m labeled isomers of L- and D-ethylenecysteamine cysteine (ECC), the mono-acid derivative of (99m)Tc-L,L-EC. Labeling of L-ECC or D-ECC with (99m)Tc using a direct or exchange labeling method yields for each of them two diastereomeric (99m)Tc complexes (A and B, in the order of elution during reversed phase high performance liquid chromatography) in relative amounts depending on the pH during labeling. In mice, all four isomers of (99m)Tc-ECC (LA, LB, DA, and DB) are cleared rapidly from the blood, mainly by the renal system. The isomers LB and DB show the most efficient renal handling, but none of the mono-acid derivatives has a urinary excretion rate as high as that of (99m)Tc-L,L-EC. The renal handling of the isomers of (99m)Tc-ECC is partly due to tubular secretion because the urinary excretion of these compounds is significantly lower in mice pretreated with probenecid. In the baboon, isomers DA and DB show a plasma clearance comparable to that of (99m)Tc-L,L-EC. The plasma clearance of isomers LA and LB is lower but still comparable to or higher than that of (99m)Tc-MAG3. In a human volunteer, isomer DB shows a plasma clearance rate only slightly lower than that of (99m)Tc-L,L-EC. Thus, it appears that the presence of one carboxylate in (99m)Tc-EC-like compounds can be sufficient for efficient renal handling. However, it is also evident that the configuration at the chiral carbon atom and the orientation of the oxotechnetium core determine in a significant way the biological characteristics.

Importance of the two ester functions for the brain retention of 99mTc-labelled ethylene dicysteine diethyl ester (99mTc-ECD).

99mTc-ethylene dicysteine diethyl ester (99mTc-L,L-ECD) is a neutral lipophilic tracer agent that crosses the blood-brain barrier and is retained in the brain of primates following enzymatic hydrolysis of one of the ester functions to the ionized mono-ester, mono-acid metabolite. Up to now, it is not clear whether the second ethylcarboxylate group is essential for brain uptake and retention. Therefore, we have synthesized and studied two derivatives of 99mTc-L,L-ECD that contain only one ethylcarboxylate function, namely 99mTc-labelled L- and D-ethylene cysteamine cysteine ethyl ester (99mTc-ECCE). Direct labelling of L- or D-ECCE at neutral pH and room temperature resulted for each of them in the formation of two probably diastereomeric 99mTc-complexes in a 1:1 ratio. This means that four different isomers could be isolated. The 99mTc-labelled complexes formed after labelling ECCE (A and B, in order of elution during HPLC) are slightly less lipophilic than 99mTc-L,L-ECD. In mice, all four isomers show a low brain activity at 10 min post injection (p.i.), approximately 0.1% to 0.3% of the injected dose versus 0.9% for 99mTc-L,L-ECD. The clearance from the blood is comparable with (isomers LA and LB) or slower (isomers DA and DB) than that of 99mTc-L,L-ECD. Isomers LA and DA show high liver uptake and rapid excretion to the intestines. Both 99mTc-ECCE-LB and 99mTc-ECCE-DB, the most lipophilic isomers, are cleared from the blood mainly by the kidneys and excreted more efficiently to the urine. 99mTc-ECCE-LB is characterized by a surprisingly high heart uptake (about 1.5% of i.d.) at 10 min p.i. versus 1.0% for 99mTc-methoxyisobutylisonitrile (99mTc-MIBI) and 0.2-0.3% for the other isomers, but also lung uptake is relatively high. In the baboon, brain and heart uptake of isomers LA and LB of 99mTc-ECCE were negligible. Activity concentrated mostly in the hepatobiliary system for isomer LA and in the renal system for isomer LB. The results indicate a clear difference in biological behaviour between 99mTc-L,L-ECD and the four isomers of 99mTc-ECCE. This shows that the presence of both ester functions in 99mTc-L,L-ECD is an essential structural requirement for its brain uptake and retention in primates.

Characteristics and biological behaviour of 99mTc-labelled hydroxyacetyltriglycine, a potential alternative to 99mTc-MAG3.

Substitution of the oxidation-sensitive thiol function of mercaptoacetyltriglycine (MAG3) by a hydroxyl group yields a tetraligand (hydroxyacetyltriglycine or HAG3) which is almost insensitive to oxidation and has the advantage over MAG3 that it can be stored safely without protection of the alcohol function. We found that deprotected HAG3 could be directly labelled at alkaline pH (pH>/=11.5) and room temperature in high yield (>95%). Results of electrophoresis experiments suggested a comparable structure for 99mTc-HAG3 and 99mTc-MAG3, namely binding of an oxotechnetium(V)core via three deprotonated amides and a deprotonated hydroxyl group. Biodistribution studies in mice at 10 min and 30 min p.i. showed a slightly higher urinary excretion, a faster renal transit and a significantly lower hepatobiliary handling for 99mTc-HAG3 than for 99mTc-MAG3. In a baboon, the 1-h plasma clearance of 99mTc-HAG3 was clearly higher than that of 99mTc-MAG3. Its plasma protein binding was in the same order as that of Hippuran and much lower than that of 99mTc-MAG3. Evaluation in a human volunteer confirmed the favourable biological characteristics of 99mTc-HAG3, namely a rapid renal excretion, a high 1-h plasma clearance and a negligible hepatobiliary handling. The results indicate that 99mTc-HAG3 may be an easy-to-prepare and practical substitute for 99mTc-MAG3 with improved renal excretion characteristics.