6 research outputs found
Studies on the separation of 99mTc from large excess of molybdenum
BACKGROUND: Due to aging and unexpected prolonged shutdown of nuclear reactors producing 99Mo for 99Mo/ 99mTc generators it was necessary to explore the alternative methods of technetium-99m production. The first choice were the accelerators. Three years ago IAEA (International Atomic Energy Agency) initiated the Coordinated Research Project “Accelerator-based Alternatives to Non-HEU production of Mo-99 /Tc-99m” aimed at direct production of 99mTc in proton accelerators using the 100Mo(p,2n)99mTc reaction. POLATOM is participating in this enterprise together with the Heavy Ion Laboratory of Warsaw University and the Institute of Nuclear Chemistry and Technology.
MATERIAL AND METHODS: 99Mo/99mTc solutions and pure 99mTc used for generators production or milked from ready to use generators were used in experiments. Commercial chromatographic and laboratory-prepared columns were used for separation. The peristaltic pumps were used for solutions delivery onto the columns. Radioactivity of eluted 99Mo and 99mTc was measured using high resolution gamma spectrometry or ionisation chamber in case of high radioactivity. For separation, three different chromatographic methods were used, one based on ion exchange and two on extraction.
RESULTS: Synthetic mixtures simulating the real solutions were used. 99mTc is quantitatively bound in the Dowex-1 × 8 column whereas molybdenum is only slightly retained and totally rinsed with 2M NaOH. 99mTc is eluted with TBAB. The elution yield has been reproducible and amounted to 78%. The AnaLig Tc-02 resin column was used for 99mTc retention. Residual Mo was removed by rinsing with 2M NaOH and 99mTc eluted using small volume of water. The recovery was equal to about 85%. Using C-18 column coated with PEG over 80% of 99mTc was recovered in about 50 mL of water. The reduction of volume was necessary.
CONCLUSIONS: The recovery of 99mTc was the highest using AnaLig Tc-02 resin. Time of 99mTc separation is the shortest for AnaLig Tc-02 resin and it is not higher than 100 minutes and it can further be shortened
Improved procedures of Sc(OH)3 precipitation and UTEVA extraction for 44Sc separation
BACKGROUND: 44Sc is becoming attractive as a PET radionuclide due to its decay characteristics. It can be produced from 44Ca present in natural calcium with 2.08% abundance.
MATERIALS AND METHODS: The targets were mostly prepared from natural CaCO3 or metallic calcium in the form of pellets. After irradiation they were dissolved in 3 M hydrochloric acid and 44Sc was separated from excess of calcium by precipitation of scandium hydroxide using ammonia. Alternatively, targets were dissolved in 11 M hydrochloric acid and 44Sc was separated by extraction chromatography on UTEVA resin. As the next step, in both processes 44Sc was further purified on a cation exchange resin. Initially, the separation procedures were developed with 46Sc as a tracer. Gamma spectrometry with a high purity germanium detector was used to determine the separation efficiency. Finally, the CaCO3 pellet with 99.2% enrichment in 44Ca was activated with protons via 44Ca(p,n)44Sc nuclear reaction.
RESULTS: Altogether twenty two irradiations and separations were performed. The working procedures were developed and the quality of separated 44Sc solution was confirmed by radiolabeling of DOTATATE. The chemical purity of the product was sufficient for preclinical experiments. At the end of around 1 hour proton beam irradiation of CaCO3 pellet with 99.2% enrichment in 44Ca the obtained radioactivity of 44Sc was more than 4.8 GBq.
CONCLUSION: 44Sc can be produced inexpensively with adequate yields and radionuclidic purity via 44Ca(p,n)44Sc nuclear reaction in small cyclotrons. The recovery yield in both investigated separation methods was comparable and amounted above 90%. The obtained 44Sc was pure in terms of radionuclide and chemical purity, as shown by the results of peptide radiolabeling
Characterization of bacterial strains able to grow on high molecular hydrocarbons
Szczepy bakterii zdolne do degradacji węglowodorów znane sąjako naturalna mikroflora bytująca
w skażonym tymi związkami środowisku. W wyniku wieloetapowego skriningu wyizolowano i
scharakteryzowano cztery monokultury zdolne do wykorzystania węglowodorów cięższych (C20-
C40) jako źródła węgla i energii. Substrat do badań stanowiła frakcja będąca mieszaniną
wysokocząsteczkowych węglowodorów. Analizowano hydrofobowość komórek w oparciu o
zjawisko adhezji bakterii do cząsteczek węglowodorów w obecności frakcji P-30 i surfaktantów
(PEG i Triton).The capability of hydrocarbon degradation is displayed by many bacteria. Using enrichment
procedures we isolated and characterized four bacterial strains that can use hydrocarbon as a
source of carbon and energy. The substrate was a complex mixture of high molecular mass
compounds, including saturated,aromatic and branched hydrocarbons. Analysis of the metabolic
profiles of the isolated strains showed that they could metabolize diffrent groups of hydrocarbons
but their consortium was the most efficient. We also measured the hydrophobicity, which affects
the adhesion to a hydrocarbon, of all bacterial strains in the presence of hydrocarbons from P-30
fraction and surfactants such as: PEG and Triton
Biodegradation of fuel oil hydrocarbons in presence of high concentration of iron and lead ions
Skażeniom substancjami ropopochodnymi często towarzyszą zanieczyszczenia metalami ciężkimi.
Ich obecność może mieć wpływ na wzrost i proces biodegradacji węglowodorów. Wyniki
uzyskane dla szczepów G. alkanivorans S7 i P. fluorescens SL3 wskazują, że obecność jonów
żelaza i ołowiu w stężeniach 50 i 100 mg/I powoduje ograniczenie degradacji węglowodorów
oleju napędowego. Jony żelaza w zastosowanych dawkach ograniczają aktywność emulgacyjną
szczepów. Efektu takiego nie obserwuje się w hodowlach z jonami ołowiu. Łączna obecność
jonów żelaza i ołowiu w hodowlach szczepu P. fluorescens SL3 powoduje silne ograniczenie
biodegradacji węglowodorów cięższych i gromadzenie się pośredników metabolizmu.Heavy metals contamination often accompanies pollution with petroleum oil derivatives. Metal
ions may considerably affect the microbial growth and process of hydrocarbons biodegradation.
The results obtained for bacterial strains Gordonia alkanivorans S7 i Pseudomonas fluorescens
SL3 indicated the limitation of degradation of fuel oil hydrocarbons in presence ferric and lead
ions in concentrations 50 and 100 mg/I. The ferric ions in these doses limit the emulsifying activity
of both strains. This effect wasn 't observed for lead ions. The combined presence of ferric and
lead ions in P. fluorescens SL3 cultures caused reduction of long chain hydrocarbons and
accumulation of metabolism derivatives