Synthesis of a new bifunctional NODA for bioconjugation with PSMA ligand and one-step Al18F labeling

The Al¹⁸F labeling method is a relatively new approach that allows radiofluorination of biomolecules such as peptides and proteins in a one-step procedure and in an aqueous solution. However, instability of the complex of [AlF]²⁺ with hexadentate chelator NOTA may attribute to the disassociation of free ¹⁸F^- and [Al¹⁸F]²⁺ and accumulation in bone. In this study, we designed and synthesized a new bifunctional pentadentate AlF-chelator p-SCN-PhPr-NODA as well as its nitro form p-NO₂-PhPr-NODA. Chelator p-NO₂-PhPr-NODA exhibited increased Al (III) complexation kinetics determined by AA III complexation kinetic studies and stronger coordination ability towards [AlF]²⁺ according to DFT calculation studies in comparison with hexadentate chelator NOTA. As a proof of concept, bifunctional chelator p-SCN-PhPr-NODA was furthermore conjugated to a PSMA targeting moiety Glu-urea-Lys to form NODA-PrPh-GuL. The conjugated peptide showed acceptable radiochemical yield (12.5-16.4%) and efficiency with an excellent radiochemical purity (∼100% after SPE purification) in Al¹⁸F labeling. The labeled peptide exhibited good in vitro stability and significant specificity for PSMA. Biodistribution study and MicroPET scan in healthy Kun Ming mice with the labeled peptide were performed and demonstrated excellent in vivo stability of Al¹⁸F-labeled construct. In general, the successful application of the new bifunctional chelator in labeling dipeptide Glu-urea-Lys with Al¹⁸F could facilitate its possibility in conjugating with other peptides for PET imaging with enhanced in vivo stability, thus providing better in vivo performances.

Hexavalent lactoside labeled with [18F]AlF for PET imaging of asialoglycoprotein receptor

Several methods have been developed to label compounds with ¹⁸F. However, in general these are laborious and require a multistep synthesis. A method based on the chelation of ¹⁸F-aluminum fluoride ([¹⁸F]AlF) by 1,4,7-triazacyclononane-1,4,7-triacetic acid (NOTA) was developed recently. The present work was aimed to radiolabel hexavalent lactoside (NOTA-HL) by [¹⁸F]AlF method for PET imaging of asialoglycoprotein receptor (ASGPR).

METHODS

hexavalent lactoside was conjugated with the NOTA chelate and labeled with ¹⁸F in a one-pot method. The labeling procedure was investigated with different amounts of NOTA-HL and aluminum concentration. Radiochemical yield and radiochemical purity were determined by radio-TLC and radio-HPLC respectively. In vitro stability study of [¹⁸F]AlF-HL were carried out. PET/CT imaging of normal mice injected with [¹⁸F]AlF-NOTA-HL was performed.

RESULTS

The Radiochemical yield of [¹⁸F]AlF-NOTA-HL was higher with more precursor and optimal Al⁺ concentration. The radiochemical purity of labeled product was >95% after purified by Sep-Pak cartridge to remove unbound [¹⁸F]AlF. The radiolabeling, including purification, was performed in 30 min [¹⁸F]AlF-NOTA-HL exhibited good in vitro stability. PET studies in normal mice revealed high specific accumulation of activity in the liver.

CONCLUSION

NOTA-HL could be labeled rapidly and efficiently with aqueous ¹⁸F using AlF method. [¹⁸F]AlF-NOTA-HL would provide another efficient approach for PET imaging of ASGPR.

Role of Spirulina in mitigating hemato-toxicity in Swiss albino mice exposed to aluminum and aluminum fluoride

Aluminum is ingested through foods, water, air, and even drugs. Its intake is potentiated further through foods and tea prepared in aluminum utensils and Al salt added in the drinking water for removal of suspended impurities and also fluoride in the affected areas. The ameliorating role of a blue green alga Spirulina is well documented to various pollutants in the animal models. We, therefore, examined its protective role (230 mg/kg body weight) on the hematology of male Swiss albino mice treated with aluminum (sub-acute = 78.4 mg/kg body weight for 7 days, sub-chronic = 7.8 mg/kg body weight for 90 days) and aluminum fluoride (sub-acute = 103 mg/kg body weight, sub-chronic = 21 mg/kg body weight), along with their recovery after 90 days of sub-chronic exposure. This study revealed significant reduction in the values of RBC (5-18 %), Hb (15-17 %), PCV (8-14 %), and platelets (26-36 %), and increase in WBC (54-124 %) in the treated mice, particularly after sub-acute exposure. Aluminum fluoride was comparatively more toxic than aluminum. Further, Spirulina supplement not only alleviated toxicity of test chemicals in Swiss albino mice but also led to their better recovery after withdrawal.

Al18F-NODA-butyric acid: biological evaluation of a new PET renal radiotracer

INTRODUCTION

Renal scintigraphy is an important imaging modality for the diagnosis and management of a variety of renal diseases including obstruction and renovascular hypertension as well as the evaluation of absolute and relative kidney function. The goal of this work was to evaluate Al(18)F-NODA-butyric acid (Al(18)F-1) as a potential PET tracer to image the kidneys and monitor renal function by comparing its pharmacokinetic properties with those of (131)I-o-iodohippurate ((131)I-OIH), the radioactive standard for the measurement of effective renal plasma flow.

METHODS

Al(18)F-1 was prepared in aqueous conditions using a one-pot Al(18)F-radiofluorination method and its radiochemical purity was determined by HPLC. Biodistribution studies, using (131)I-OIH as an internal control, were performed in normal rats and in rats with renal pedicle ligation. In vitro stability and metabolism of Al(18)F-1 were analyzed by HPLC. Dynamic microPET/CT studies were conducted in normal rats.

RESULTS

Al(18)F-1 showed excellent stability in vitro and in vivo. Biodistribution studies in normal rats and in rats with simulated renal failure confirmed that Al(18)F-1 was exclusively cleared through the renal-urinary pathway and that the hepatic/gastrointestinal activity was less for Al(18)F-1 than for (131)I-OIH both at 10 and 60 min. Dynamic PET showed a rapid transit of Al(18)F-1 through the kidneys into the bladder.

CONCLUSION

These results suggest that the easily labeled Al(18)F-based compounds provide a highly promising approach for the development of a PET renal radiotracer that combines superior imaging qualities with a reliable measure of effective renal plasma flow.

An Experimental Search for Gaseous Reactivity Between AlF3 and HF Near 1200 K

Using an accurate transpiration method, AlF₃ was sublimed near 1200 K into argon containing 0, 0.02, and 0.76 atm of HF, but no reaction between AlF₃ and the HF was detected within the precision (about 1%). Two alternative structures of HAlF₄ are postulated. An upper bound for extent of reaction corresponds to Δ H 298 ∘ > - 33 kcal (- 138 kJ) for AlF₃ (g) + HF (g) = HAlF₄ (g); this indicates a far lower stability of HAlF₄ (g) than that of LiAlF₄ (g) or NaAlF₄ (g) when formed similarly.

The Heats of Combustion of Polytetrafluoroethylene (Teflon) and Graphite in Elemental Fluorine

Bomb calorimetric measurements are reported for the combustion in fluorine of polytetrafluoroethylene (Teflon) and graphite-polytetrafluoroethylene mixtures. Mass spectrometric examination of the product gases showed CF4 to be the only major product with C2F6(g) present in only very small amounts. The completeness of combustion of the graphite was determined by chemical analysis of combustion residues and found to range from 97 to better than 99 percent. From the combustion data, the heats of formation Δ H f 298 ° [ CF 4 ( g ) ] and Δ H f 298 ° [ C 2 F 4 ( solid polymer ) ] were determined to be -222.87 ±0.38 kcal mol-1 and -197.82 ±0.39 kcal (gfw C2F4)-1, respectively. The uncertainties are estimates of the overall experimental errors. A previously reported value for the heat of formation of AlF3(c) is adjusted to be consistent with the present work. An evaluation of other data on CF4 is presented. The heat of formation of CF4(g) is combined with other work to derive the heats of formation of HF solutions at three specific concentrations.