Alice Laznickova

Comparison of biological characteristics of EDTMP complexes with 99mTc, 111In and 153Sm in rats

The pharmacokinetics and elimination of EDTMP chelates with different radionuclides (99mTc, 111In and 153Sm) has been investigated in rats. The biodistribution of the complexes under study was similar and two main processes, namely bone uptake and the elimination of glomerular filtration, take part in their rapid blood clearance. A substantially slower blood clearance of 111In-EDTMP in comparison with the other complexes suggests partial indium exchange between the chelate and transferrin. All the complexes exhibited high affinity for bone and the radionuclide uptake into the skeleton was in the order 153Sm > 111In > 99mTc. No specific extra-skeletal uptake was found.

The effect of lipophilicity on the protein binding and blood cell uptake of some acidic drugs.

Quantitative relationships between lipophilicity (characterized by the octanol-water partition coefficient) and binding to both human plasma proteins and blood cells have been studied in a group of model anionic drugs (benzoic and phenylacetic acid derivatives). Protein binding in plasma and accumulation in blood cells in suspension increases with increasing lipophilicity. For quantitative evaluation, the equation log R = a + b log D has been employed, where R is the bound-to-free drug ratio, D is lipophilicity, and a and b are constants. Whereas the protein bound-to-free drug ratio is proportional to drug lipophilicity, the cell bound-to-free drug ratio correlates with lipophilicity to the power 0.685. Distribution in whole blood is affected by protein binding and also by cell accumulation. In blood, the free drug fraction and the fraction in blood cells decrease with increasing lipophilicity, whereas the protein-bound fraction correspondingly increases.

2,3-Dihydro-1H-cyclopenta[b]quinoline Derivatives as Acetylcholinesterase Inhibitors—Synthesis, Radiolabeling and Biodistribution

In the present study we describe the synthesis and biological assessment of new tacrine analogs in the course of inhibition of acetylcholinesterase. The obtained molecules were synthesized in a condensation reaction between activated 6-BOC-hydrazinopyridine-3-carboxylic acid and 8-aminoalkyl derivatives of 2,3-dihydro-1H-cyclopenta[b]quinoline. Activities of the newly synthesized compounds were estimated by means of Ellman’s method. Compound 6h (IC50 = 3.65 nM) was found to be most active. All obtained novel compounds present comparable activity to that of tacrine towards acetylcholinesterase (AChE) and, simultaneously, lower activity towards butyrylcholinesterase (BChE). Apart from 6a, all synthesized compounds are characterized by a higher affinity for AChE and a lower affinity for BChE in comparison with tacrine. Among all obtained molecules, compound 6h presented the highest selectivity towards inhibition of acetylcholinesterase. Molecular modeling showed that all compounds demonstrated a similar binding mode with AChE and interacted with catalytic and peripheral sites of AChE. Also, a biodistribution study of compound 6a radiolabeled with 99mTc was performed.

Radiolabeling of PAMAM dendrimers conjugated to a pyridine-N-oxide DOTA analog with 111In: Optimization of reaction conditions and biodistribution

Polyamidoamine dendrimers (PAMAMs) of generations 1 (G1) and 4 (G4) were conjugated with a bifunctional pyridine-N-oxide DOTA analog, 10-[(4-carboxy-1-oxidopyridin-2-yl)methyl]-1,4,7,10-tetraazacyclododecane-1,4,7-triacetic acid (H(4)do3a-py(NO-C)), through the pyridine-4-carboxylic acid group, and the conjugates were radiolabeled with indium-111. Reaction conditions for the radiolabelling were optimized. Both radiolabeled conjugates, G1-[(111)In(do3a-py(NO-C))] and G4-[(111)In(do3a-py(NO-C))], were kinetically stable for at least 48h after preparation; in the presence of competitive ligands, the radiochemical purity of the conjugates slightly decreased (4-7%) over the same time period. The preclinical pharmacokinetics of both agents were evaluated. Biodistribution and elimination in rats were more favorable for the G1-[(111)In(do3a-py(NO-C))] conjugate than G4-[(111)In(do3a-py(NO-C))] conjugate. However, the G1-[(111)In(do3a-py(NO-C))] conjugate was rapidly eliminated from the body, mainly through urine, while, significant and long-term radioactivity uptake in the liver and kidney was observed for the G4-[(111)In(do3a-py(NO-C))] conjugate.

Octreotide and Octreotate Derivatives Radiolabeled with Yttrium: Pharmacokinetics in Rats

Distribution profiles and elimination pathways in rats of two new octreotate derivatives radiolabeled with yttrium, namely Y-DOTAGA-tate and Y-DOTA-t-GA-tate, were compared with those of Y-DOTA-octreotide and Y-DOTA-Tyr(3)-octreotide. All synthetic somatostatin analogues under study were rapidly cleared from the blood and most organs of rats. The main elimination pathway for all peptides under study was urine excretion. High and long-term uptakes of radioactivity in the kidneys and also in organs with high density of somatostatin receptors (the adrenals and pancreas) were found. Radioactivity concentrations in these somatostatin receptor-rich organs were substantially higher for octreotate derivatives in comparison with octreotide analogues; the highest values for Y-DOTAGA-tate were determined. The octreotate derivatives under study appear to be specific ligands for treatment of somatostatin receptor-positive tumors if some mechanism to decrease their kidney retention is provided.

Preclinical Evaluation of 177Lu-Nimotuzumab: A Potential Tool for Radioimmunotherapy of Epidermal Growth Factor Receptor–Overexpressing Tumors

BACKGROUND The humanized monoclonal antibody Nimotuzumab (h-R3) has demonstrated an exceptional and better clinical profile than other monoclonal antibodies for immunotherapy of epidermal growth factor receptor-overexpressing tumors. This work deals with the preparation and radiolabeling optimization of (177)Lu-Nimotuzumab and their preclinical evaluation. METHODS Nimotuzumab was conjugated with S-2-(4-isothiocyanatobenzyl)-1,4,7,10-tetraazacyclododecane tetraacetic acid (p-SCN-Bn-DOTA), testing different molar ratios. The immunoconjugates were characterized. The radiolabeling with (177)Lu was optimized. Radioimmunoconjugates stability was tested in 2-[bis[2-[bis(carboxymethyl)amino]ethyl]amino]acetic acid (DTPA) excess and human serum. In vitro studies were performed in tumor model cell lines. Receptor-specific binding was tested by competitive inhibition. (177)Lu-Nimotuzumab in vivo studies were conducted in healthy and xenograft animals. RESULTS Nimotuzumab conjugates were obtained with high purity. Radiolabeling yield and specific activities ranged from 63.6% to 94.5% and from 748 to 1142 MBq/mg, respectively. The stability in DTPA excess and human serum was 95.9% and 93.2% after 10 days, respectively. The radioimmunoconjugate showed specific receptor binding in tumor cell lines. Biodistribution in healthy animals showed the typical behavior of the immunoconjugates based on monoclonal antibodies. The study in xenografts mice demonstrated uptake of (177)Lu-Nimotuzumab in the tumor and reticuloendothelial organs. CONCLUSIONS (177)Lu-Nimotuzumab was obtained with high purity and specific activities under optimal conditions without significant loss in immunoreactivity and might be a potential radioimmunoconjugate for radioimmunotherapy of tumors with epidermal growth factor receptor overexpression.

The effect of molecular weight on the biodistribution of hyaluronic acid radiolabeled with111In after intravenous administration to rats

SummaryHyaluronic acid (HA), is a high molecular weight (HMW) glucosaminoglycan with significant acitivity, and which influences a number of physiological and pathological processes such as tumorogenesis, arthritis, etc. The aim of this study was to determine the difference in the biodistributional pathways of111in-labeled diethylenetriaminepentaacetic acid-hyaluronic acid (111In-DTPA-HA) molecule of three different MWs (10, 100 and 450 kDA) in a rat model, and to determine possible relationships between the biodistribution and the MW of the investigated agent for future medical applications.111In-DTPA-HA was prepared by mixing activated DTPA and activated HA, then adding111InCl3 to the previously prepared mixture at pH 5,5 in an acetic buffer. Biodistributional studies were performed using 36 male Wistar rats aged 2 months and weighing 280–350 g. The radioactivity in the samples was measured via a radiometer and the radioactivity in the different organs, blood, plasma and urine was determined. It was found that 50–54% for 10 and 100 kDa and 80% for 450 kDa of the administered dose of radiolabel was present in the liver after 5min. Other organs show no significant increase during the experimental period. The elimination of the radiolabel was mostly renal and in low molecular weight (LMW) form. Radioactivity remained in liver throughout the 72h experimental period. A difference in the biodistribution of 450 kDa and LMW radiolabeled molecules was found. Higher amounts of radiolabel were taken up by the liver when the 450 kDa molecule was used. LMW fractions were found in the urine, and could have been a product of non-enzymatic cleavage. The extended retention of radiolabel in the liver could be related to changes in the polarity of DTPA-HA molecules.

Mono(pyridine-N-oxide) DOTA analog and its G1/G4-PAMAM dendrimer conjugates labeled with 177Lu: Radiolabeling and biodistribution studies

(177)Lu radiolabeling of the first (G1-) or fourth (G4-) generation polyaminoamide (PAMAM) dendrimer conjugates with DOTA-like bifunctional chelator with one methylenepyridine-N-oxide pendant arm (DO3A-py(NO-C)) stability of the radiolabeled species and their pharmacokinetic characteristics were evaluated in preclinical experiments. The results showed that the G1- and G4-dendrimer conjugates, modified in average with 7.5 or 57 DO3A-py(NO-C) chelating units, respectively, can also be labeled with (177)Lu with a high specific activity and radiochemical purity even at 37 °C. The radiolabeled species were stable for at least 24h. Distribution profile of G1-dendrimer conjugate in organs and tissues of rats was more favorable than that of G4 one. On the other hand, the later dendrimer conjugate bears a substantially higher number of metal chelators per molecule enabling binding of a considerably larger number of radiometals. Our results indicate that an employment of dendrimer-chelate conjugates with bound radiometals might represent a prospective way for radiolabeling of biologically active target-specific macromolecules to obtain markedly high specific activity.

Kidney and liver contributions to salicylate metabolism in rats

SummaryThe pharmacokinetics and metabolism of radiolabelled salicylate were studied in rats and compared with that of the isolated perfused rat liver and the perfused rat kidney. Both parent compound and salicylate metabolites (mainly conjugates with glycine and glucuronic acid) were eliminated mostly into urine. The comparison of a relative proportion of metabolites eliminated in whole rats with that of the isolated perfused rat liver and the perfused rat kidney showed that both kidney and liver contributed to the salicylate metabolism. The glycine conjugate of salicylate was formed predominantly in the kidney whereas both kidney and liver participated in the formation of glucuronic acid derivatives.

99Tcm-DTPMP as a skeletal scintigraphy agent: distribution in rats in comparison with 99Tcm-MDP.

The distribution and elimination of 99Tcm-complexes with methylene-diphosphonate (MDP) and with the calcium salt of diethylene-triamine-penta(methylene phosphonate) (DTPMP) were compared in rats. Both compounds exhibited high bone uptake and long-term retention of radioactivity in the skeleton. No significant accumulation of the complexes in non-osseous tissues was found. The pharmacokinetics of both chelates were similar, small differences in their distribution and elimination probably being due to different binding to plasma proteins. Two processes, namely bone uptake and kidney elimination, contributed to the disappearance of the complexes from the blood. The higher protein binding of 99Tcm-MDP probably caused its slower rate of urine elimination and insignificantly higher bone uptake compared with 99Tcm-DTPMP. On the other hand, the more rapid reduction in blood and muscle radioactivity with 99Tcm-DTPMP resulted in accelerated non-osseous tissue clearance compared with 99Tcm-MDP. This suggests that the time between administration and imaging may be shorter for 99Tcm-DTPMP than for 99Tcm-MDP. Furthermore, the much greater stability of 99Tcm-DTPMP may also reduce degradation of the complex and 99Tcm liberation in the body. For a general evaluation of both compounds, it will be necessary to determine lesion-to-bone ratios.