Introduction
Radioisotope (RI) generator contains an ion chromatography system in which mother nuclides are attached onto adsorbents, such as Al2O3, and the daughter nuclides are eluted from the generator. The most widely used generator throughout the world is the 99Mo/99mTc generator. The clinical use of 99mTc has been mainly for the diagnosis of cancers in bone, brain, heart and other organs. Because of the proper half-life (6 h) and diagnostic imaging capacity of 99mTc which comprises 70% of all medical isotopes, 99mTc is the daughter nuclide of 99Mo that can be obtained either by thermal neutron-irradiation of pure 98Mo or from fission product of Uranium-235 in a nuclear reactor. In general, most 99mTc generators are prepared by using fission-99Mo since it doesn’t require large amount of adsorbent to attach 99Mo with high specificity.
The longer the generator is used, the smaller amount of the desired radioisotope is attained due to the half-life of mother nuclide. Even though the permissible period of a 99Mo/99mTc generator application is two weeks, but the actual lifetime of the generator is less than a week. At the second week, the activity of 99mTcO4- is approximately a quarter of that at the first week. Therefore, increasing the concentration of 99mTcO4- would be useful to extend the lifetime of the 99Mo/99mTc generators.
Recently, many researchers have been focused on 188Re in that it has similar chemical and physical characteristics to 99mTc. 188Re is one of the prominent therapeutic radioisotopes for various medical applications such as bone pain palliation and synovectomy. Additionally, 188Re is also an attractive agent for simultaneous diagnosis and therapy of cancer, as it emits both beta (βmax = 2.12 MeV) and gamma (γ = 155 KeV) rays with proper half-life (16.9 h). 188Re is obtained by the 188W/188Re generator that contains an alumina adsorbent embedded 188W (T1/2 = 69.4 days). 188Re, a daughter nuclide of 188W, is produced by a double n-γ reaction from 186W. Since 188W has low specific activity, relatively large column and therefore large eluate volumes are required to get a highly purified 188Re. Therefore, it is required to be more enriched in order to extend the permissible period of 188W/ 188Re generator. Recently, some 188W/188Re generators are commercially available for research and medical purposes. To label reasonable amount of 188Re with cold-kit, large volume of eluate was needed and its labeling yield was not satisfactory. To solve this problem, high performance 188W/188Re generator with a small column was established by using newly developed adsorbent (7).
Numerous studies have focused on the concentration of 99mTcO4- and 188ReO4- to improve the labeling yield. For example, it has been reported simple concentration system of 99mTcO4- and 188ReO4- with post-elution tandem cation/ anion exchange column (11, 1, 5, 6). Chattopadhyayet al. (2, 3) showed a new concept for concentrating 99mTc from (n, γ)99Mo by using strong ion exchange resin (Dowex 1X8) and AgCl column. Mushtaq et al. (10) reported that acetone was a good eluent for 99mTc and 188Re generators and it can be easily vaporized to form concentrated RI. Mansur et al. (9) reported the concentration of 99mTc and 188Re using silver cation exchange and alumina column after primary elution. Luo et al. (8) reported the automatic concentration apparatus for extending the permissible period of 188Re generator. Despite substantial concentration systems have been developed to extend lifetime of radioisotopes, it still remains to be investigated portable devices for convenient concentration.
We describe herein the development of the RI concentration system with ion exchange column to get high activity of 188Re and 99mTc per unit volume. We also investigated the concentration process with this device and animal studies demonstrating efficacy of the concentrated radioisotopes.
Materials and methods
1.1. Materials
All chemicals and reagents used were analytical grade (AR) purchased from Sigma-Aldrich Co. and most are of GR/AR grade. The parts, fittings and check valves, of device were obtained from Upchurch Scientific®. Cation exchange resins (AG 50W-X8, AG50W-X12) were obtained from BioRad. An anion exchange column (SepPak Light QMA) and IC-Ag column were purchased from Waters. Sodium pertechnetate ([99mTc] NaTcO4) was obtained from a 99Mo/99mTc generator produced by Sam Young Unitech,Co. Sodium perrhenate ([188Re] NaReO4) was used from the 188W/188Re generators developed at KAERI. The endotoxin test vial was purchased from ENDOSAFE®. Radioactivities were measured using an ionizing chamber (Atomlab 200, Biodex), radionuclide purity was checked by a HPGe γ-ray detector, and radiolabeling yield was determined by an ITLC scanner. The inveon SPECT/CT system (Siemens Medical Solutions, Knoxville, TN, USA) was used for the anatomical and molecular imaging of mice.
1.2. Preparation of Ag-cation exchange column
10 g of cation exchange resins (AG 50W-X8, AG50W-X12) were washed with 100 ml of deionized water and 0.1 M HNO3 in sequence. An empty SPE tube was filled with 1-1.5 g of resin and then 0.5 N AgNO3 in 0.1 M HNO3 solution was passed through the SPE tube at a flow rate of 2 ml/min. After filling Ag ions into the SPE tube, the total adsorbed amounts were 6 ml and 4 ml of 0.5 M AgNO3 when using AG50W-X12 and AG 50W-X8 resin, respectively. These adsorption capacities were calculated using the relation given below.
Adsorption amount of Ag = 3.0 mmol/1g of wet AG50W-X12 resin
Adsorption amount of Ag = 2.25mmol/1g of wet AG50W-X8 resin
1.3. Shield design and analysis
For calculating the radioactivity shield, simulation geometries were constituted as shown in Fig.1. For the beta source (188Re), the shield was made in the order of Teflon and lead. The diameter of the shield is 5.03 cm and the inner constitutions were 1.3 × 0.4 cm RI source in the middle of a 1.91 cm length of air, X cm of Teflon, and Y cm of lead (X + Y = 1.56) shields. For 99mTc, all the geometries were the same, only difference of lead and Teflon sequence. Calculation was done using MCNPx 2.6 and dose conversion factor was used in ICRP211971.
Figure 1. Geometry for calculating the radiation shield Total length is 5.03 cm and shielding region is 1.56 cm. RI source core is 0.4 x 1.3 cm cylinder form. (Shielding of 99mTc : X= lead, Y= Teflon, Shielding of 188Re : X = Teflon, Y =lead )
1.4. Preparation of portable concentration device
A rough outline of the concentration system of the radioisotopes is as follows (Fig. 2). Two-different check valves were connected to a T-connector to protect the backward flow. One was opened with a cracking pressure of 1 psi and the other with 15 psi. When a vacuum vial was connected to the retrieval region in the same constitution, only the check valve (B) was opened, and RI (188Re or 99mTc) was adsorbed into the anion exchange resin. Another empty vial was changed with a vacuum vial and 1ml of saline was allowed to flow through the check valve (A). Concentrated RI was collected in an empty vial. There were two different concentration systems. I-type and L-type. These were used same concept as shown in Fig. 3. Each type was also divided by two categories, one for 188Re and the other for 99mTc.
Figure 2. The arrangement of components for RI concentration system
Figure 3. RI concentration systems for 99mTc and 188Re (L-type : (1-1) 99mTc concentration system shielding with lead, (1-2) 188Re concentration system shielding with Teflon and lead in order, (1-3) The profile of I type concentration system connected with a generator, I-type: (2-1) 99mTc concentration system shielding with lead, (2-2) 188Re concentration system shielding with Teflon and lead in order, (2-3) The profile of I type concentration system connected with a generator)
1.5. Quality Analysis
With the concentrated 99mTc and 188Re, quality control was done on the basis of a ‘standard and test method’ regulated by the KFDA (Korea Food & Drug Administration) and KAERI regulations. To determine the radiochemical purity of 188ReO4- and 99mTcO4-, the samples were chromatographed on ITLC-SG using 75% MeOH and HPLC. The metal ions content of the RI solution was checked using a spot test and ICPAES. In addition, clarity, pH, and endotoxin tests were performed.
1.6. The preparation of labeled compound
After concentration was performed, 1 ml of 99mTcO4containing 740 MBq (20 mCi) was added to the MDP kit vial, gently mixed for 2 min, and allowed to stand for 10 min at room temperature. One drop of labeled compound was placed over a 15 cm SG/ITLC strip at a position 2 cm from the lower end. The strip was developed in 75% methanol, dried in air and scanned with TLC scanner.
1.7. Animal study
37 MBq of 99mTc-MDP was intravenously administrated to ICR mouse. The micro SPECT image was acquired at 3 hrs after injection. The mice were scanned with an Inveon SPECT/CT system, equipped with a 1-pinhole mouse high-sensitivity collimator.
Results and Discussion
The principle of the concentration device to obtain a high specific activity of MO4- (M = 188Re or 99mTc) and to extend the lifetime of the generator was based onthe previous report by Singh et al. (11), Guhlke et al. (5) and Knapp et al. (6). The technological principle of concentrating 99mTc and 188Re are as follows (Fig. 4). First, by passing 5 ml of saline solution containing radioisotopes through a cation exchange resin embedding Ag ion and the salt within the solution was removed. In this mechanism, Na+ from a saline was exchanged with Ag+ and adsorbed cation exchange resin, and then Cl- ions reacted with Ag+ to form AgCl precipitation. At this point, the radioisotope (188ReO4- or 99mTcO4-) was in the state of dissolving in pure water. While an RI solution was passed through an anion exchange resin, where only RI was attached to the anion exchange resin (Sep-Pak Light QMA) since there were no other interfering ions. Then, 188ReO4-or 99mTcO4- attached to the anion exchange resin can be easily extracted by passing 0.5-1 ml of the saline solution because Na+ and Cl- in the saline interfere with the ionic bond between isotope and resin. Using the above method, total volume of RI solution can be reduced from 5-10 ml to 0.5-1 ml.
Figure 4. Basic principle for RI concentration
This principle was used to develop a compact-sized enhancing system.
To determine the desalination capacity in 0.9% NaCl solution, Lab made Ag-cation exchange resin was comparatively studied with commercially available ICAg Sep-Pak. The titration point was checked when the AgCl precipitation formed within the 0.1 M AgNO3 solution. IC-Ag Seppak, AG50W-X12 (1 g) containing maximum Ag+ (3 mmol), and AG 50W-X8 (1 g) with Ag+ (2.25 mmol) can eliminate 14, 15 and 11 ml of saline, respectively. Although AG 50W-C12 and IC-Ag have good characteristics in terms of desalting effect, they have a drawback in that internal pressure within a column and T-connector increases when saline was allowed to flow. Thus, it is difficult to get a concentrated RI, and even takes a long time when a vacuum vial was used to extract the RI solution. For this reason, AG 50W-X8 is preferable as the desalting column material. The shelf stability lasts for one month in a dark bottle and lasts for 2 month in a refrigerator. Sep-Pak Light QMA was used to adsorb 188ReO4- and 99mTcO4-, and can be recycled at least five times just washing with 1 ml of pure water.
188Re simultaneously emits gamma and beta rays, and primarily emits beta rays with maximum beta energy of 2.12 MeV. Lead reduces Bremsstrahlung X-ray from beta ray as well as gamma ray and Teflon reduce the generation of X-ray. For the calculation of the shielding thickness, the beta energy spectrum of 188Re was referred to RSICC DATA LIBRARY DLC-172 (4). These data have been designed to address the need for medical, environmental, and occupational radiation protection. To calculate the dose rate of the outer side of a 188Re concentrator, ‘F5 tally’ and ‘Fluence to Dose conversion factor from ICRP21-1971’ were used for computing the dose rate with the variable length of the inner (Teflon) and outer shields (Lead). The computing results of MCNPx revealed the units of (Sv/h)/(particles/cm2-sec) and converted into the dose rate per hour. With assumption of a maximum amount used (50 mCi for 188Re or 99mTc), the computed results of the surface dose rates are shown in Table 1 and 2. All these data satisfy the regulations of RI-package and transportation (activity at a 10 cm distance from the surface: below 2 mSv/h ).
Table 1. The surface dose rates of 50 mCi 99mTc for different X and Y value
Table 2. The surface dose rates of 50 mCi 188Re for different X and Y value
In this portable concentration device, a key characteristic is that two separate check valves with different opening pressures were used instead of a 3-way valve. The cracking pressure of check valve (B) is lower than the other one (A), as Fig. 2. It is the reason why two resins in the middle of passing through the retrieval region from generator to concentrator induce the high internal pressure. Generally, when the 3-way valve system is used, the valve opening and closing operations must be done manually or automatic with electronic device. But, this present concentration device do not required any such manual or automatic operations, making it more convenient to use. Moreover, we constructed two different types of system (I-type and L-type) considering the user convenience. The I-type is recommended for usage in spacious places equipped with a large shield, and the L-type for the confined places. The lengths of I and L types are 16.5 cm and 9.5 cm, respectively. The concentration steps of 99mTc and 188Re were performed using the aforementioned technical principle with the equipped concentration device. First, the concentration device was placed on the generator and saline vial and vacuum vial were orderly placed at the specified location. 5 ml of saline in the vial was passed through a vacuum vial. After the vacuum vial was exchanged for another empty vial, 1 ml of saline was injected into the side inlet part. During this process, almost all of the eluted RI was conveniently recovered. The average recovery yield of 99mTc was 87.6%. In the same manner above, 188Re was also concentrated, and the average yield was 92.5%. Table 3 summarizes the results of concentration of 99mTc and Table 4 represents the results for 188Re. In this study, the anion exchange column (QMA Light) has been repeatedly used for the concentration process up to 5 times by simply washing with 1ml of pure water. The cation column is disposable and was easily detached by simply twisting the lower position of the concentrator.
Table 3. Concentration of 99mTc form expired generator using a concentration device
Table 4. Concentration of 188Re from a generator after 1 year using a concentration device
The resultant concentrated 99mTc and 188Re showed a clear solution with pH 6-7 and were checked for radiochemical and nuclide purity using ITLC/HPLC and MCA, respectively. The radiochemical purity was consistently over 99%. Metal impurities were also checked using a colorimetric spot test and ICP AES. No metals were identified, except trace of silver ions (lower than 0.1 ppm) were appeared. As a result of an endotoxin test, all of the concentrated RI was revealed as negative. All processes were compared with pre-concentrated RI, and we found that the results were consistent with as the KFDA regulations, even concentrated RI showed a better quality.
The animal studies were performed using approved protocols under KAERI Institutional Animal Care and Use Committee. During the concentration process, 99mTc generator produced by Sam Young Unictech Co. and an RI concentrator were comparatively studied. Single photon emission computed tomography (SPECT) imaging study of 99mTc-MDP using 99mTc obtained from above concentration process was carried out in normal ICR mice. The mice were anesthetized with 2% isoflurane in 100% oxygen (prone positioned in the cradle). SPECT images were acquired with Inveon Multimodality (SIEMENS, Germany), at 3 hrs after intravenous administration of radiotracer. The images were obtained with a multipinhole collimator using a 10% window centered over the 140 KeV photopeak. The CT scans were used for anatomical reference. For the CT scans, the X-ray sources were used at 300 μA and 60 kV. The number of acquired projections was 180 (one shot per projection) for 15 min and CT resolution was 200 μm. The SPECT and CT images were reconstructed and resultant images are shown in Fig 5. A large amount of 99mTc-MDP was accumulated in the backbone, especially in the cartilage and cavity, and a small amount was revealed in liver area. These images pattern are not distinguishably different from the 99mTcMDP with 99mTcO4- from the commercial 99mTc generator (Sam Young Unitech Co, Korea).
Figure 5. Animal SPECT-CT image profiles of 99mTc-MDP using with 99mTcO4- from the concentrator in ICR mice at 3 hrs after i.v. administration.
Conclusion
Since 2007, there have often been cases in which the world’s major research reactors for producing 99Mo, the mother nuclide of 99mTc, have stopped functioning due to deterioration. In this situation, there have been major setbacks in supply and demand within and outside the country, and cases have emerged in which hospital emergency patients cannot receive nuclear imaging examinations.
To alleviate this state which may occur in the near future, we studied and developed a RI concentration device for extending the lifetime of generators. According to the description of the results disclosed above, a portable RI concentration device will offer a new paradigm for the re-usage of expired generators and partially resolve the international problem of radioisotope supply and demand. In addition, it can aid in providing hospital care during emergency times when the isotope supply is low.
Acknowledgment
This study was supported by Nuclear R&D program of MSIP (Ministry of Science, ICT and Future Planning) in KOREA and KAERI (Korea Atomic Energy Research Institute) R&D program.
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