Patent Number: 061570362
Section: claims

1. A gas-over-eluent, fluid delivery mechanism for eluting one or more processing elements having inlets and outlets, comprising: a reservoir having an output feed at the bottom thereof for connecting to the inlet of one of the one or more processing elements;  a predetermined volume of eluent contained in the reservoir;  a predetermined volume of gas contained in the reservoir, separated from and positioned over the predetermined volume of eluent; and  a force-limited, pressure-supplying mechanism that forces the volume of eluent and then the volume of gas through the reservoir output feed and into and through the one or more processing elements, thereby eluting the one or more processing elements with the predetermined volume of eluent and purging the one or more processing elements with the predetermined volume of gas.  the reservoir is a syringe; and  the pressure-supplying mechanism includes:  at least one processing element each having an inlet and outlet;  a reservoir having an output feed at the bottom thereof for connecting to the inlet of one of the at least one processing element;  a predetermined volume of eluent contained in the reservoir;  a predetermined volume of gas contained in the reservoir, separated from and positioned over the predetermined volume of eluent; and  a force-limited, pressure-supplying mechanism that forces the volume of eluent and then the volume of gas through the reservoir output feed and into and through the at least one processing element, thereby eluting the at least one processing element with the predetermined volume of eluent and purging the one or more processing elements with the predetermined volume of gas.  preloading the delivery mechanism with a predetermined volume of eluent and a predetermined volume of gas positioned over the volume of eluent; and  applying a pressure directly upon the volume of gas to force the volume of eluent followed by the volume of gas through the at least one processing element at a predetermined rate.  (a) at least one generator for producing an eluate containing a desired radioisotope to be concentrated;  (b) a radioisotope concentration subsystem having at least one processing element in fluid communication with the generator that processes the radioisotope therein;  (c) a radioisotope collection vessel in fluid communication with the concentration subsystem for collecting therein a desired volume of prepared radioisotope solution;  (d) a first gas-over-eluent delivery mechanism in fluid communication with the generator, that stores a first measured volume of fluid which includes a first measured volume of eluent solution and a first measured volume of a gas positioned over the first volume of solution, the mechanism including a first pressure-supplying source that applies a first pressure upon the first volume of gas to force the first volume of eluent and then gas through the generator and the radioisotope concentration subsystem; and  (e) a second gas-over-eluent delivery mechanism in fluid communication with the concentration subsystem, that stores a second measured volume of fluid which includes a second measured volume of eluent solution and a second measured volume of a gas positioned over the second volume of solution, the second mechanism including a second pressure-supplying source that applies a second pressure upon the second volume of gas to force the second volume of eluent and then gas through the concentration subsystem and into the radioisotope collection vessel, thereby re-eluting the radioisotope at a desired concentration.  the first delivery mechanism further includes a first, downwardly-positioned syringe having a barrel defining a hollow cavity for containing therein the first volume of fluid and including an outlet, and a plunger placed within the hollow cavity, the first syringe being substantially vertically positioned so that the outlet is at the bottom and the plunger is at the top, and wherein the first pressure-supplying source is connected to the plunger, and  the second delivery mechanism further includes a second, downwardly-positioned syringe having a barrel defining a hollow cavity for containing therein the second volume of fluid and including an outlet, and a plunger placed within the hollow cavity, the second syringe being substantially vertically positioned so that the outlet is at the bottom and the plunger is at the top and wherein the second pressure supplying source is connected to the plunger.  at least one impurity trap in fluid communication with the generator for removing impurities from the eluate,  a radioisotope trap in fluid communication with the at least one impurity trap for concentrating therein the desired radioisotope in the eluate and for permitting the passage of the eluate therethrough for disposal, and  wherein the second gas-over eluent delivery mechanism forces the second measured volume of eluent and then the second measured volume of a gas into and through the radioisotope trap and into the radioisotope collection vessel.  applying a first pressure on the first volume of gas to force the first volume of eluent and then the first volume of gas through the generator and concentration subsystem and into a fluid waste receptacle, thereby eluting the daughter radioisotope from the generator, concentrating the resultant eluate, and purging the generator, the at least one impurity trap and the radioisotope of eluate; and  applying a second pressure on the second volume of gas to force the second volume of eluent, and then the second volume of gas through the concentration subsystem and into the sterile, vented collection vessel, thereby re-eluting the concentrated daughter radioisotope into the collection vessel and purging the concentration subsystem of fluid.  at least one eluate processing element; and  a sealed, radioactively-shielded, container that houses the at least one eluate processing element, the container having at least one opening and further including,  at least one impurity trap;  a radioisotope trap serially connected to the at least one impurity trap; and  a sealed, radioactively shielded, container that houses the at least one impurity trap and radioisotope trap, the container having at least one opening and further including,  a first input septum that seals the first container opening and permits the flow of eluate from the generator into the at least one impurity trap when penetrated by the first fluid delivery system,  a second input septum that seals the second container opening and permits the flow of fresh eluent through the radioisotope trap when penetrated by the second fluid delivery system, and  an output septum that seals the third opening and permits the flow of the prepared radioisotope solution from the radioisotope trap to the sterile, collection vial when penetrated by the third fluid delivery system. 2. The mechanism of claim 1, wherein: 3. A system for producing a radioisotope solution, comprising: 4. The system of claim 3, wherein the at least one processing element is a radioisotope generator having an input connected to the output feed of the reservoir. 5. The system of claim 3, wherein the at least one processing element includes at least two radioisotope generators connected in series. 6. The system of claim 3, wherein the at least one processing element includes at least one radioisotope generator and at least one of a radioisotope concentration component and radioisotope purification component. 7. A method for eluting a desired volume of a daughter radioisotope solution through at least one radioisotope processing element using a gas-over-eluent delivery mechanism in fluid communication with the at least one processing element, the method comprising: 8. A system for producing a concentrated radioisotope through a series of elution steps, comprising: 9. The system of claim 8, wherein 10. The system of claim 9, wherein the first and second pressure-supplying sources are constant pressure sources. 11. The system of claim 10 wherein the first constant pressure source is a first mass having a predetermined weight and the second constant pressure source is a second mass having a predetermined weight. 12. The system of claim 9, wherein the first and second pressure-supplying sources are variable-rate, pressure-supplying sources. 13. The system of 12 wherein the first pressure supply source is a first spring having a predetermined spring constant and the second pressure supply source is a second spring having a predetermined spring constant. 14. The system of claim 8, wherein the at least one processing element comprises 15. The system of claim 9, further including a waste receptacle for receiving the eluate produced by the generator and passed by the radioisotope trap. 16. The system of claim 15, wherein the waste receptacle is integral with the radioisotope concentration subsystem. 17. The system of claim 8, wherein the first gas-over-eluent delivery mechanism is connected to the second delivery mechanism so that the second pressure-supplying source is applied to the second measured volume of fluid only after the first delivery mechanism is depleted of its first volume of fluid. 18. A method for automatically eluting a desired volume of a daughter radioisotope from a parent radioisotope contained in at least one generator using a first, gas-over-eluent delivery mechanism containing a first measured volume of gas positioned over a first measured volume of eluent, the mechanism in fluid communication with the at least one generator, for automatically concentrating the resultant eluate in a concentration subsystem having at least one impurity trap in series with a radioisotope trap having an inlet and outlet, and for re-eluting a daughter radioisotope solution into a sterile, vented, collection vessel with a second, gas-over-eluent, storage and delivery mechanism containing a second, measured volume of gas positioned over a second, measured volume of eluent, the method comprising: 19. The method of claim 18, further including sensing that the applying of the first pressure on the first volume of gas is completed, and wherein the applying of the second pressure on the second volume of gas commences only upon such sensing. 20. The method of claim 19, wherein the applying if the second pressure is automatic. 21. A single-use, self-sealed, radioisotope concentration cartridge for processing therein a radioisotope contained in an eluate solution generated by a radioisotope generator and carried by a fluid delivery system, thereby preparing the radioisotope to be delivered into a sterile, collection vial, the cartridge comprising: 22. The cartridge of claim 21, wherein the container further includes a visual indicator that identifies whether the container has been used in a prior elution procedure. 23. The cartridge of claim 21, wherein the container further includes a quality control indicator that identifies a condition, such as pH, chemical purity or biological purity, of the eluate contained therein. 24. The cartridge of claim 21, wherein the container is shaped to fit into a radiation well chamber that identifies breakthrough activity of a parent radioisotope from the generator. 25. A single-use, self-sealed, radioisotope concentration cartridge for concentrating therein a radioisotope contained in an eluate solution generated by a radioisotope generator and carried by a first fluid delivery system, thereby preparing the radioisotope to be re-eluted by a second fluid delivery system and to be carried into a sterile, collection vial via a third fluid delivery system, the cartridge comprising: 26. The cartridge of claim 25, wherein the container includes at least three openings and the at least one septum includes 27. The cartridge of claim 25, further including an eluate waste receptacle sealed within the container that is in fluid communication with the output of the radioisotope trap for collecting therein eluate waste from the first elution.