Laura Meléndez-Alafort

In vitro and in vivo assessment of 99mTc-UBI specificity for bacteria.

Technetium-99m labeled ubiquicidin peptide 29-41 ((99m)Tc-UBI) is a cationic human antimicrobial peptide fragment that has been shown to bind bacteria in vitro and accumulates at sites of infection in experimental animals. To help determine if (99m)Tc-UBI is bound to the bacterial cell envelope by a simple nonspecific electrostatic interaction, a comparative study of the in vitro binding of (99m)Tc-UBI and two different (99m)Tc labeled cationic peptides ((99m)Tc-Tat-1-Scr and (99m)Tc-Tat-2-Scr) to bacteria and to two tumor cell line (LS174T and ACHN) was performed. The in vivo specificity of (99m)Tc-UBI for infection in mice was also evaluated using dual labels in the same animal and comparing the target/non-target ratio for (67)Ga-citrate and (99m)Tc-UBI at sites of induced infection and sterile inflammation. Under conditions of this study, the in vitro binding of (99m)Tc-UBI, (99m)Tc-Tat-1-Scr and (99m)Tc-Tat-2-Scr to S. aureus was 35, 78 and 87% respectively. While the binding of (99m)Tc-Tat-1-Scr and (99m)Tc-Tat-2-Scr was 37 and 33% to colon tumor cells (LS174T) and 39 and 41% to renal tumor cells (ACHN) respectively, the binding of (99m)Tc-UBI to both cell types was much lower at less than 4%. In vivo studies revealed that there is a significant difference (p < 0.05) in the radioactive accumulation of (99m)Tc-UBI between the sites of infection and inflammation compared to (67)Ga-citrate. Thus, (99m)Tc-UBI showed an average infection/inflammation ratio of 2.08 +/- 0.49 compared to 1.14 +/- 0.45 for (67)Ga-citrate. In conclusion, the in vitro and in vivo results provide evidence that a specific mechanism is responsible of the (99m)Tc-UBI bacterial intracellular accumulation.

Lys and Arg in UBI: a specific site for a stable Tc-99m complex?

The aim of this study was to help establish if ubiquicidin peptide 29-41 fragment (UBI) contains a specific site for 99mTc labeling by a new direct method under alkaline conditions. Since this peptide does not have cysteine residues, it is possible that neighboring arginine and lysine in the peptide amino acid sequence (Thr-Gly-Arg-Ala-Lys-Arg-Arg-Met-Gln-Tyr-Asn-Arg-Arg) could be a specific coordination site to form a stable 99mTc-UBI complex. Following direct labeling, the in vitro stability of 99mTc-UBI was compared to UBI radiolabeled by one indirect method using HYNIC/tricine and HYNIC/tricine/EDDA. Radiochemical purity of 99mTc-UBI averaged 97% compared to 88% for 99mTc-HYNIC-UBI/tricine and 98% for 99mTc-HYNIC-UBI/tricine/EDDA. Both 99mTc-HYNIC-UBI (tricine or EDDA) and 99mTc-UBI showed stability in human serum and solutions of cysteine. 99mTc-UBI radiochemical purity 24 h after dilution in 0.9% NaCl was greater than 90% at pH 9 and greater than 95% at pH 6.5. Under one set of experimental conditions, in vitro binding to bacteria of 99mTc-UBI was 35% and identical to that of 99mTc-HYNIC-UBI/tricine and 99mTc-HYNIC-UBI/tricine/EDDA at 32% and 31% respectively. The biodistribution of 99mTc-UBI in mice showed a rapid renal clearance. To help identify the site(s) of 99mTc binding following direct labeling, molecular mechanics and quantum-mechanical calculations were performed which showed that the amine groups of Arg(7) and Lys are the most probable site. The calculations show that these groups can form a square pyramid with two water molecules for the Tc cation (dxysp(3)). It will be necessary to isolate and characterize the 99Tc(V)(O)-UBI.(H2O)n complex to confirm these results.

Development of Specific Radiopharmaceuticals for Infection Imaging by Targeting Infectious Micro-organisms

Infectious diseases remain a major health problem and cause of death worldwide. A variety of radiopharmaceuticals are used for the imaging of infections and inflammation in the practice of nuclear medicine. Long-term clinical use has shown that the majority of radiolabeled probes cannot distinguish between inflammation and infection. Gallium-67-citrate binds to bacteria, but also to proteins accumulating at both sterile inflammation and bacterial infection sites. Other agents are used to interact with receptors or domains on circulating and infiltrating leukocytes or to label them directly. However, these probes cannot distinguish between infection and inflammation because they are not specific to infectious micro-organisms. This review examines the recent developments and applications of radiolabeled specific agents, such as antiviral drugs, antifungal, antibiotics and antimicrobial peptides, to visualize infectious foci by targeting viruses, fungi or bacteria.

99mTc-glucarate for detection of isoproterenol-induced myocardial infarction in rats

Infarct-avid radiopharmaceuticals are necessary for rapid and timely diagnosis of acute myocardial infarction. The animal model used to produce infarction implies artery ligation but chemical induction can be easily obtained with isoproterenol. A new infarct-avid radiopharmaceutical based on glucaric acid was prepared in the hospital radiopharmacy of the INCMNSZ. 99mTc-glucarate was easy to prepare, stable for 96 h and was used to study its biodistribution in rats with isoproterenol-induced acute myocardial infarction. Histological studies demonstrated that the rats developed an infarct 18 h after isoproterenol administration. The rat biodistribution studies showed a rapid blood clearance via the kidneys. Thirty minutes after 99mTc-glucarate administration the standardised heart uptake value S(h)UV was 4.7 in infarcted rat heart which is six times more than in normal rats. ROIs drawn over the gamma camera images showed a ratio of 4.4. The high image quality suggests that high contrast images can be obtained in humans and the 96 h stability makes it an ideal agent to detect, in patients, early cardiac infarction.

Radiopharmacokinetic data for 99mTc-ABP—A new radiopharmaceutical for bone scanning: Comparison with 99mTc-MDP

Technetium-99m-labeled alendronate is a new radiopharmaceutical for bone scanning developed under strict quality control at the INNSZ. The purpose of this work was to compare the radiopharmacokinetic data and the dosimetry of 99mTc-ABP and 99mTc-MDP in 10 volunteers, after it was tested in laboratory animals. 99mTc-ABP has shorter mean residence time (MRT) and t 1/2 beta; is less protein bound; has a higher renal clearance; smaller Vdss, and similar bone uptake at 1 and 2 h. 99mTc-ABP gives less radiation exposure to the patient with a 740 MBq dose, and the quality of the bone scan is excellent. 99mTc-ABP is a better radiopharmaceutical than 99mTc-MDP for bone scanning.

Labeling peptides with rhenium-188

A direct labeling technique via EHDP for the preparation of 188Re-somatostatin analogue peptide beta-(2-naphthyl)-D-Ala-Cys-Tyr-D-Trp-Lys-Val-Cys-Thr-amide complex was developed. The influence of reaction conditions such as pH, temperature, weak ligand concentration and stannous chloride concentration were investigated. Methods of analysis were also established permitting identification of radiochemical impurities which may be present in the radiopharmaceutical solution. Results showed that under the procedure reported herein 188Re-peptide complex can be prepared with a radiochemical purity of 90% and a specific activity up to 1.8 GBq mg-1 without radiolytic degradation of the product.

Labelling of Re-ABP with 188Re for bone pain palliation

Etidronate and medronate have been labelled with technetium-99m (99mTc-HEDP, 99mTc-MDP) for bone scanning and, with rhenium-188 (188Re-HEDP) to palliate the pain resulting from bone metastases. The objective of this study was to label alendronate, ABP, a new bisphosphonate, with SnF2-reduced-188Re. The reagents for the 5 mg ABP kit were SnF2, KReO4 and gentisic acid at acid pH. The chemical, spectroscopic and microscopic characteristics, quality control, rat bone uptake of [188Re]Re-ABP and similarities with 99mTc-ABP are presented. We conclude that this is a promising new radiopharmaceutical for bone metastases pain palliation.

Labeling of biotin with [166Dy]Dy/166Ho as a stable in vivo generator system.

The aim of this work was to synthesize [166Dy]Dy/166Ho-DTPA-Biotin to evaluate its potential as a new radiopharmaceutical for targeted radiotherapy. Dysprosium-166 (166Dy) was obtained by neutron irradiation of enriched 164Dy(2)O(3) in a Triga Mark III reactor. The labeling was carried out in aqueous media at pH 8.0 by addition of [166Dy]DyCl(3) to diethylenetriaminepentaacetic-alpha,omega-bis(biocytinamide) (DTPA-Biotin). Radiochemical purity was determined by high-performance liquid chromatography (HPLC) and TLC. The biological integrity of labeled biotin was studied evaluating its avidity for avidin in an agarose column and by size-exclusion HPLC analysis of the radiolabeled DTPA-Biotin with and without the addition of avidin. Stability studies against dilution were carried out by diluting the radiocomplex solution with saline solution and with human serum at 37 degrees C for 24 h. The [166Dy]Dy/166Ho-labeled biotin was obtained with a 99.1+/-0.6% radiochemical purity. In vitro studies demonstrated that [166Dy]Dy/166Ho-DTPA-Biotin is stable after dilution in saline and in human serum and no translocation of the daughter nucleus occurs subsequent to beta(-) decay of 166Dy that could produce release of 166Ho(3+). Avidity of labeled biotin for avidin was not affected by the labeling procedure. Biodistribution studies in normal mice showed that the [166Dy]Dy/166Ho-DTPA-Biotin has a high renal clearance. In conclusion, the radiolabeled biotin prepared in this investigation has adequate properties to work as a stable in vivo generator system for targeted radiotherapy.

Phosphine reduced IgG: A new method for99mTc labeling immunoglobulins

A new technetium labeling method for immunoglobulin reduced with tris(2-carboxy-ethyl)phosphine hydrochloride is presented. The Sandoglobulina IgG source was assayed for purity and optimum reagents concentration and incubation times were determined. It was purified by column chromatography and labelled with Sn2+ reduced technetium in the presence of MDP. The kit is easy to prepare, labeling efficiency is >(97±1.9) % and stable for 6 hours. The immunoreactivity of the99mTc-IgG was verified by electrophoresis and Western blot tests. The IgG retained its structure after both the reducing and labeling processes and it was the only labeled species.

Inhibition of growth and induction of apoptosis in human lung cancer cells by Br-oxph

The study was aimed at evaluating apoptotic potential of Br-oxph (4-bromoN,N-diethyl-5,5-dimethyl-2,5-dihydro-1,2-oxaphosphol-2-amine 2-oxide) in vitro. The dose response effect of Br-oxph (dose range 1-3 mg/ml, for 48 h) on SK-MES-1 cells viability was determined by means of WST-1 cell proliferation assay. The half maximal inhibitory concentration (ІС50) value was determined - 1.8 mg/ml. The ability of the compound tested to induce apoptosis was tested by ELISA to detect cellular DNA fragmentation. We provided a quantitative assessment of the apoptotic potential of Br-oxph in human lung carcinoma cells at concentrations corresponding to ІС50 and 2хІС50 for 3 hours. Treatment with 2хІС50 significantly increased the amount of cytoplasmic DNA-fragments. Results obtained from the present study confirm that Br-oxph target the cancerous cells towards apoptosis.