DEVICE AND CASSETTE FOR PERFORMING A PLURALITY OF SYNTHESIS PROCESSES OF PREPARING A RADIOPHARMACEUTICAL IN SERIES

Abstract

A method of performing a plurality of synthesis processes of preparing a radiopharmaceutical in series, which method includes carrying out a first synthesis run comprising the steps of: a) providing water containing 18F; b) trapping the 18F from the water provided in step a) on an anion exchange material; c) eluting the trapped 18F from the anion exchange material to a reaction vessel of first radiopharmaceutical synthesis cassette; d) preparing a radiopharmaceutical incorporating the eluted 18F using the first radiopharmaceutical synthesis cassette; where steps a)-d) are repeated in at least one subsequent run using another radiopharmaceutical synthesis cassette; and where the method includes a reconditioning step of treating the anion exchange material with water between two consecutive runs. Other aspects of the invention relate to a device for performing this method, and a cassette for use in the device.

Claims

1.-10. (canceled)

11. A method of performing a plurality of synthesis processes of preparing a radiopharmaceutical in series, which method comprises carrying out a first synthesis run comprising the steps of: a) providing water containing 18F; b) trapping the 18F from the water provided in step a) on an anion exchange material; c) eluting the trapped 18F from the anion exchange material to a reaction vessel of a first radiopharmaceutical synthesis cassette; d) preparing a radiopharmaceutical incorporating the eluted 18F using the first radiopharmaceutical synthesis cassette; wherein steps a)-d) are repeated in at least one subsequent run using another radiopharmaceutical synthesis cassette; and wherein the method comprises a reconditioning step of said anion exchange material between two consecutive runs, said reconditioning step comprises treating the anion exchange material with water.

12. The method according to claim 11, wherein said anion exchange material is a quaternary ammonium anion exchange material.

13. The method according to claim 11, wherein in step c) the eluent comprises a phase transfer agent.

14. The method according to claim 11, wherein the radiopharmaceutical is selected from the group of FDG, FMISO, NaF, FLT, FET, FES, FCHOL, FACETATE, FDGal, FDOPA, SFB.

15. The method according to claim 11, wherein at least one process of said plurality of synthesis processes comprises preparing 18FDG

16. A reconditioning cassette for reconditioning an anion exchange material used in performing a plurality of synthesis processes of preparing a radiopharmaceutical in series in a synthesizer, comprising: at least one manifold provided with a plurality of valves connectable to and operable by the synthesizer for performing a plurality of synthesis processes of preparing a radiopharmaceutical in series; an anion-exchanger comprising an anionic exchange material connectable through the manifold to said synthesizer; an eluent container comprising an eluent connectable through the manifold to said anion-exchanger; and a recondition container comprising water connectable through the manifold to said anion-exchanger.

17. The cassette according to claim 16, wherein the anion exchanger comprises a quaternary ammonium anion exchange material.

18. The cassette according to claim 16, wherein the eluent container comprises a phase transfer agent.

19. A device for performing a plurality of synthesis processes of preparing a radiopharmaceutical in series, comprising: a frame; an inlet for introducing water containing 18F; at least one manifold provided with a plurality of valves connectable to and operable by the device; an anion-exchanger comprising an anionic exchange material configured for trapping 18F connected to said inlet; an eluent container comprising an eluent configured for eluting trapped 18F connectable through the manifold to said anion-exchanger; a recondition container comprising water configured for reconditioning used anionic exchange material that trapped 18F connectable through the manifold to said anion-exchanger, distribution means for selectively supplying eluted 18F to a radiopharmaceutical synthesis cassette; and at least two radiopharmaceutical synthesis cassettes, each cassette being connected to said distribution means.

20. The device according to claim 19, wherein the anion exchanger comprises a quaternary ammonium anion exchange material.

21. The device according to claim 19, wherein the eluent container comprises a phase transfer agent.

22. The device according to claim 19, wherein the anion-exchanger comprising an anionic exchange material connected to said inlet; the eluent container comprising an eluent connectable through the manifold to said anion-exchanger; and the recondition container comprising water connectable through the manifold to said anion-exchanger are assembled into a cassette having a manifold provided with a plurality of valves connectable to and operable by the synthesizer.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0064] The invention will be illustrated by reference to the attached drawings, wherein:

[0065] FIG. 1 shows a diagrammatic view of a part of a synthesizer, in particular a cassette suitable for trapping 18F, eluting and reconditioning;

[0066] FIG. 2 shows an example of a process scheme for performing a number of synthesis processes according to the invention; and

[0067] FIG. 3 shows a diagrammatic view of a synthesizer for performing a number of synthesis processes according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0068] In FIG. 1 a part of a synthesizer being an embodiment of a disposable reconditioning cassette according to the invention, for trapping 18F on an anionic exchange material, subsequent elution and reconditioning of the anion exchange material, is shown diagrammatically. In the embodiment shown the cassette indicated in its entirety by reference numeral 10, comprises a first manifold 12 and a second manifold 14. Each manifold 12, 14 comprises five 3 way valves 16, individually indicated 16a through 16e, and 16f-16j respectively. These reference numerals are also used to indicate the respective positions. The valves 16 are preferably operated by compressed air as disclosed in WO 2013/127439 A1, which is incorporated by reference. Typically connections with tubing occurs by luerlock connectors 17, while (reagent) vials and other bottles are usually closed by suitable septums 19 that are spiked.

[0069] Water containing 18F is derived from a cyclotron (not shown) and introduced at 16j and trapped on anion-exchanger 18, such as a Sep-Pak Accell Plus QMA Carbonate Plus Light cartridge available from Waters Corporation, which is connected to the right hand ends 20, 22 of manifolds 12 and 14 via tubing 24. The water is removed at 16e and collected into a bottle or other container (not shown). Once the 18F is trapped by anion-exchanger 18 an eluent, typically a mixture of (potassium) carbonate, a transfer agent like Kryptofix, water and acetonitrile, from vial 26 is metered in syringe 28 via valves 16d, 16a and then passed over the anion-exchanger 18 thereby extracting the 18F and sending it to a reaction vessel of one of the synthesis cassettes (see FIG. 3) at valves 16f-h. The left end 30 of manifold 12 is connected to a source of an inert gas such as nitrogen or helium.

[0070] For reconditioning the anion-exchanger 18 reconditioning agent, typically an aqueous carbonate solution, is used. In the embodiment shown in FIG. 1, this solution is prepared in situ in syringe 28 from a high molar K.sub.2CO.sub.3 solution in vial 32 at position 16c and water from bottle 34 at position 16b. It will be recognized that the vials 26, 32, 34 can be placed in any order. Then the diluted K.sub.2CO.sub.3 solution thus prepared is ejected from syringe 28 over anion-exchanger 18 to a waste bottle (not shown) connected to the left hand end 36 at position 16f of manifold 14. Subsequently one or more rinsing steps are carried out with water from bottle 34 using syringe 28. The spent water is collected in the same waste bottle at 36. The anion-exchanger 18 is dried using the inert gas introduced at 30. The water at 16i is used for each synthesis step requiring water, that is to say water is sampled from 16i for subsequent synthesis runs. Cross-contamination is not possible because the water arrives from 16 f g h in the different runs.

[0071] FIG. 2 shows an example of a process scheme for performing multiple reactions in series.

[0072] The series of reactions start with supply of 18F in water from a target and trapping thereof on the anion-exchanger. Then the trapped 18F is eluted to radiopharmaceutical synthesis process 1. The anion-exchanger is reconditioned. Thereafter the sequence of steps A) through D) is repeated using the same anion-exchanger, but the eluted 18F is now guided to a second synthesis process 2. Upon finishing this synthesis process, the anion-exchanger is reconditioned once more, and the sequence of steps A) through D) is repeated for the last time.

[0073] FIG. 3 shows an embodiment of a synthesizer 48 having a frame or housing 49 allowing insertion of cassettes, wherein 3 consecutive batches of 18F-FDG are prepared usingin this embodimentidentical radiopharmaceutical synthesis cassettes 50 (diagrammatically shown in broken lines). Each cassette comprises two manifold 52 and 54, and each manifold has five 3 way valves 56 (or positions), numbered 56a-e and 56f-j respectively. In the top left part of the synthesizer the eluent mixture containing 18F is prepared as explained above with reference to FIG. 1. This eluent mixture is used in the first synthesis process of 18F-FDG. The eluent mixture is introduced in a cassette 50 at position 56c and collected in reactor vessel 58, which can be heated by heating means (not shown). Therein the eluent mixture comprising 18F is dried using acetonitrile from bottle 60. Waste is collected at left hand end 62 of manifold 54. Precursor is added from vial 64 at position 56d. After reaction the thus produced intermediate product, after dilution with water sampled in 16i is separated on a suitable solid phase extraction cartridge 66 at position 56j and eluted back into the reaction vessel 58 using a suitable eluent such as EtOH from vial 68 at position 56i. If the chemistry allows so, the water container or bag may be incorporated in the radiopharmaceutical synthesis cassette 50, 50 or 50. The protective groups of the intermediate product are removed by means of basic hydrolysis using NaOH contained in syringe 70 at position 56g. The final product after buffering with buffer from vial 72 at position 56f is removed via valve 56h for subsequent formulation and quality control. After approval it can be used for diagnosis purposes. The syringe on position 56a is used for the pressurization of vials 60, 64, 72, 68, and for sampling of chemicals solutions, for dilution of reactive bulk mixture, and loading of the separation cartridges.

[0074] After this first production run the reconditioning of the anion-exchanger 18 is performed as outlined above with respect to FIG. 1. Fresh 18F containing water is again trapped on the thus reconditioned anion exchanger 18 and subsequently eluted to the second synthesis process cassette 50, where 18F-FDG is produced in the same way as described with respect to cassette 50. Also after this second production run reconditioning of the anion-exchanger takes place. Then a third batch of eluent mixture containing 18F is prepared and used in synthesis process 3 in cassette 50.

[0075] The synthesizer 48 is operated by a single control system 80 comprising PLC, router and server (PC).

[0076] In an embodiment of the synthesizer 48 the cassette 10 and cassettes 50, 50 and 50 are releasably mounted on a fixed upright front plate of the frame or housing 49, while common pumps, drivers and other electronics and the like are mounted on a detachable upright rear plate (not visible in FIG. 3). For example the rear plate is connected to the frame or housing 49 using removable hinges, that are horizontally arranged at the bottom. For access to the components on the rear plate it is rotated backwards over a certain angle allowing inspection, servicing and maintenance of the components, while hooks or other connecting elements maintain the rear plate in this inclined position. Upon detachment of these hooks, the rear plate can rotate further down to an essentially horizontal position. In this position the rear plate can be removed as a module from the synthesizer.