Highlight selection of radiochemistry and radiopharmacy developments by editorial board.

BACKGROUND: The Editorial Board of EJNMMI Radiopharmacy and Chemistry releases a biyearly highlight commentary to update the readership on trends in the field of radiopharmaceutical development. RESULTS: This commentary of highlights has resulted in 21 different topics selected by each member of the Editorial Board addressing a variety of aspects ranging from novel radiochemistry to first in man application of novel radiopharmaceuticals. Also the first contribution in relation to MRI-agents is included. CONCLUSIONS: Trends in (radio)chemistry and radiopharmacy are highlighted demonstrating the progress in the research field being the scope of EJNMMI Radiopharmacy and Chemistry.

Diversification of 99Mo/99mTc separation: non­fission reactor production of 99Mo as a strategy for enhancing 99mTc availability.

This paper discusses the benefits of obtaining (99m)Tc from non-fission reactor-produced low-specific-activity (99)Mo. This scenario is based on establishing a diversified chain of facilities for the distribution of (99m)Tc separated from reactor-produced (99)Mo by (n,γ) activation of natural or enriched Mo. Such facilities have expected lower investments than required for the proposed chain of cyclotrons for the production of (99m)Tc. Facilities can receive and process reactor-irradiated Mo targets then used for extraction of (99m)Tc over a period of 2 wk, with 3 extractions on the same day. Estimates suggest that a center receiving 1.85 TBq (50 Ci) of (99)Mo once every 4 d can provide 1.48-3.33 TBq (40-90 Ci) of (99m)Tc daily. This model can use research reactors operating in the United States to supply current (99)Mo needs by applying natural (nat)Mo targets. (99)Mo production capacity can be enhanced by using (98)Mo-enriched targets. The proposed model reduces the loss of (99)Mo by decay and avoids proliferation as well as waste management issues associated with fission-produced (99)Mo.

Thulium-170-labeled microparticles for local radiotherapy: preliminary studies.

The present article describes the preparation, characterization, and biological evaluation of Thulium-170 ((170)Tm) [T1/2 = 128.4 days; Eßmax = 968 keV; Eγ = 84 keV (3.26%)] labeled tin oxide microparticles for its possible use in radiation synovectomy (RSV) of medium-sized joints. (170)Tm was produced by irradiation of natural thulium oxide target. 170Tm-labeled microparticles were synthesized with high yield and radionuclidic purity (> 99%) along with excellent in vitro stability by following a simple process. Particle sizes and morphology of the radiolabeled particles were examined by light microscope, dynamic light scattering, and transmission electron microscope and found to be of stable spherical morphology within the range of 1.4-3.2 µm. The preparation was injected into the knee joints of healthy Beagle dogs intraarticularly for biological studies. Serial whole-body and regional images were taken by single-photon-emission computed tomography (SPECT) and SPECT-CT cameras up to 9 months postadministration, which showed very low leakage (< 8% of I.D.) of the instilled particles. The majority of leaked radiocolloid particles were found in inguinal lymph nodes during the 9 months of follow-up. All the animals tolerated the treatment well; the compound did not show any possible radiotoxicological effect. These preliminary studies showed that 170Tm-labeled microparticles could be a promising nontoxic and effective radiopharmaceutical for RSV applications or later local antitumor therapy.

Multispecies animal investigation on biodistribution, pharmacokinetics and toxicity of 177Lu-EDTMP, a potential bone pain palliation agent.

INTRODUCTION: Radionuclide therapy (RNT) is an effective method for bone pain palliation in patients suffering from bone metastasis. Due to the long half-life, easy production and relatively low beta- energy, (177)Lu [T(1/2)=6.73 days, E(beta max)=497 keV, E(gamma)=113 keV (6.4%), 208 keV (11%)]-based radiopharmaceuticals offer logistical advantage for wider use. This paper reports the results of a multispecies biodistribution and toxicity studies of (177)Lu-EDTMP to collect preclinical data for starting human clinical trials. METHODS: (177)Lu-EDTMP with radiochemical purity greater than 99% was formulated by using a lyophilized kit of EDTMP (35 mg of EDTMP, 5.72 g of CaO and 14.1 mg of NaOH). Biodistribution studies were conducted in mice and rabbits. Small animal imaging was performed using NanoSPECT/CT (Mediso, Ltd., Hungary) and digital autoradiography. Gamma camera imaging was done in rabbits and dogs. Four levels of activity (9.25 through 37 MBq/kg body weight) of (177)Lu-EDTMP were injected in four groups of three dogs each to study the toxicological effects. RESULTS: (177)Lu-EDTMP accumulated almost exclusively in the skeletal system (peak ca. 41% of the injected activity in bone with terminal elimination half-life of 2130 and 1870 h in mice and rabbits, respectively) with a peak uptake during 1-3 h. Excretion of the radiopharmaceutical was through the urinary system. Imaging studies showed that all species (mouse, rat, rabbit and dog) take up the compound in regions of remodeling bone, while kidney retention is not visible after 1 day postinjection (pi). In dogs, the highest applied activity (37 MBq/kg body weight) led to a moderate decrease in platelet concentration (mean, 160 g/L) at 1 week pi with no toxicity. CONCLUSION: The protracted effective half-life of (177)Lu-EDTMP in bone supports that modifying the EDTMP molecule by introducing (177)Lu does not alter its biological behaviour as a specific bone-seeking tracer. Species-specific pharmacokinetic behavior differences were observed. Toxicity studies in dogs did not show any biological adverse effects. The studies demonstrate that (177)Lu-EDTMP is a promising radiopharmaceutical that can be further evaluated for establishing as a radiopharmaceutical for human use.

(170)Tm-EDTMP: a potential cost-effective alternative to (89)SrCl(2) for bone pain palliation.

INTRODUCTION: Metastron ((89)SrCl(2)) is a radiopharmaceutical currently used for bone pain palliation in several countries since the long half-life of (89)Sr (50.5 days) favors wider distribution than other radioisotopes approved for this application, which have shorter half-lives. Strontium-89 is not ideal for bone pain palliation due to its high energy beta(-) particle emission [E(beta(max))=1.49 MeV] and is also difficult to produce in large quantities. A (170)Tm [T(1/2)=128.4 days, E(beta(max))=968 keV, E(gamma)=84 keV (3.26%)]-based radiopharmaceutical for bone pain palliation could offer significant advantages over that of (89)Sr. The present study constitutes the first report of the preparation of a (170)Tm-based agent, (170)Tm-ethylenediaminetetramethylene phosphonic acid (EDTMP), and its preliminary biological evaluation in animal models. METHODS: (170)Tm was produced by thermal neutron bombardment on natural Tm(2)O(3) target for a period of 60 days at a flux of 6x10(13) neutrons/cm(2).s. (170)Tm-EDTMP complex was prepared at room temperature. Biodistribution and scintigraphic imaging studies with (170)Tm-EDTMP complex were performed in normal Wistar rats. Preliminary dosimetric estimation was made using the data to adjudge the suitability of (170)Tm-EDTMP for bone pain palliation. RESULTS: (170)Tm was produced with a specific activity of 6.36 GBq/mg and radionuclidic purity of 100%. The (170)Tm-EDTMP was prepared with high radiochemical purity (>99%) and the complex exhibited satisfactory in vitro stability. Biodistribution and imaging studies showed good skeletal accumulation (50-55% of the injected activity) with insignificant uptake in any other vital organ/tissue. Activity was observed to be retained in skeleton until 60 days post-injection demonstrating that (170)Tm-EDTMP exhibits good bone-seeking properties with long retention. It is predicted that a dose of approximately 0.5 microGy/MBq is accrued to red bone marrow and 4.3 Gy/MBq is delivered to the skeleton. CONCLUSION: (170)Tm-EDTMP shows promising biodistribution features, encouraging dosimetric values and warrants further investigation in order to develop it as a bone pain palliative radiopharmaceutical. Despite the relatively long half-life (128.4 days) of (170)Tm, (170)Tm-EDTMP could be explored as a cost-effective alternative to (89)SrCl(2).

177Lu-EDTMP: a viable bone pain palliative in skeletal metastasis.

Designing ideal radiopharmaceuticals for use as bone pain palliatives require the use of a moderate energy beta() emitter as a radionuclide and a suitable polyaminophosphonic acid as a carrier molecule. Owing to its suitable decay characteristics [T(1/2) = 6.73 d, E((max)) = 497 keV, E() = 113 keV (6.4%), 208 keV (11%)] as well as the feasibility of large-scale production in adequate specific activity and radionuclidic purity using a moderate flux reactor, 177Lu could be considered as a promising radionuclide for palliative care in painful bone metastasis. The present study was therefore, oriented toward the preparation and biologic evaluation of 177Lu complex of ethylenediaminetetramethylene phosphonic acid (EDTMP) in various animal models, with an aim to prepare a viable radiopharmaceutical for bone pain palliation. 177Lu was produced with a specific activity of approximately 12 GBq/mg (approximately 324 mCi/mg) and radionuclidic purity of 99.98% by irradiation of natural Lu2O3 targeted at a thermal neutron flux of approximately 6 x 10(13) n/cm(2).s for 21 days. 177Lu-EDTMP complex was prepared in high-yield and excellent radiochemical purity (>99%), using EDTMP synthesized and characterized in-house. The complex exhibited excellent in vitro stability at room temperature. Biodistribution studies in Wistar rats showed a rapid skeletal accumulation of injected activity [(1.74 +/- 0.30)% per gram in femur at 3 hours postinjection] with a fast clearance from blood and minimal uptake in any of the major organs. Scintigraphic imaging studies carried out in normal Wistar rats, New Zealand white rabbits, as well as in Beagle dogs also demonstrated significant accumulation of the agent in the skeleton and almost no retention of activity in any other vital organs.

A novel 99mTc-labeled testosterone derivative as a potential agent for targeting androgen receptors.

With an insight that ligands possessing a N2S2 tetradentate array of donor atoms serve as ideal bifunctional chelating agents (BFCA) in the radiolabeling of target-specific agents, 5-hydroxy-3,7-diazanonan-1,9-dithiol (DAHPES) with a derivatizable substituent in the form of a hydroxyl group in the backbone was synthesized. The preparation of a steroid conjugate via coupling of this BFCA with testosterone-3-(O-carboxymethyl) oxime and the subsequent radiolabeling of the conjugate under optimized conditions with 99mTc, the ideal diagnostic radionuclide in nuclear medicine procedures, are reported. The immunoreactivity of the radiolabeled conjugate was demonstrated in a study using anti-testosterone antibodies, wherein the radiolabeled conjugate exhibited significant binding with antiserum to testosterone. Cell-uptake studies in DU145 prostate carcinoma cell line bearing androgen receptors (ARs) and comparison with AR non-bearing breast carcinoma cell line revealed the specific binding of the steroidal moiety with the testosterone receptor.

99mTc carbonyl t-butyl isonitrile: a potential new agent for myocardial perfusion imaging.

OBJECTIVE: The recent development of mixed ligand complexes using a 99mTc tricarbonyl synthon has prompted us to revisit the first generation product, 99mTc-t-butyl isonitrile (TBI), for possible myocardial imaging after modification of the 99mTc core to a mixed ligand core of carbonyl and t-butyl isonitrile. The easy availability of TBI from commercial sources and the recent promising development of a 'kit' procedure to prepare the 99mTc tricarbonyl aqua synthon/precursor [99mTc(H2O)3(CO)3]+ were other factors that triggered this work. METHODS: The carbonyl precursor (37-370 MBq/0.5 ml) was synthesized and reacted with TBI (3 mg.ml-1) at room temperature and at pH 8 for 1 h. [99mTc(CO)3(TBI)3]+ was characterized by C18 reverse phase HPLC in gradient mode with water and acetonitrile as solvent. Biodistribution studies were carried out in normal mice and planar images were acquired in rabbit at 5 min, 30 min, 1 h, 2 h and 4 h post-injection to assess heart uptake and soft tissue retention. [99mTc(CO)3(TBI)3]+was formed as a single species in >95% yield and was found to be stable. Biodistribution studies in mice revealed 2.3 (+/-0.2)% uptake in heart at 5 min p.i. with heart/liver, heart/lung and heart/blood ratios of 1.5, 2.0 and 30, respectively. Imaging studies in rabbits showed high uptake in myocardium, with negligible activity in blood and lungs, at 5 min p.i. that washed out of the heart after 4 h. CONCLUSION: [99mTc(CO)3(TBI)3]+ could be prepared in >95% yields. The complex showed high myocardial uptake with desirable rate of washout from heart in rabbits. [99mTc(CO)3(TBI)3]+ has potential to extend to larger animal studies and later for clinical evaluation as a myocardial imaging agent.

Preparation and biological evaluation of 153Sm-DOTMP as a potential agent for bone pain palliation.

BACKGROUND: Designing ideal radiopharmaceuticals for use as bone pain palliative agents requires the use of a moderate energy beta emitter as the radionuclide and a polyaminophosphonic acid as the carrier molecule. Cyclic polyaminophosphonic acid ligands are known for endowing higher thermodynamic stability and kinetic inertness of the radiolabelled agent when complexed with radiolanthanides. AIM: To use Sm (T1/2=46.27 h, Ebeta,max=0.81 MeV, Egamma=103 keV) as the radioisotope, obtainable at an adequate specific activity and high radionuclidic purity by irradiation of a natural Sm2O3 target, and 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetramethylene phosphonic acid (DOTMP) as the carrier ligand. RESULTS: The radiolabelling yields under optimized conditions were near quantitative with the additional merit of using a relatively low ligand:metal ratio of 2:1 unlike the 250-fold excess of ligands used in the case of the established agent, Sm-EDTMP. Radiochemical purity was retained with insignificant dissociation on storage up to 10 d at room temperature. Biodistribution studies in Wistar rats demonstrated selective skeletal uptake (4.52%+/-0.49% of injected activity per gram in tibia at 30 min post-injection) with rapid blood clearance and minimal uptake in any of the major organs. No leaching of skeletal activity was observed up to 48 h post-injection. Scintigraphic studies carried out in rabbits also showed significant skeletal accumulation and almost no retention of activity in other vital organs/tissues.