Abstract: Systems and methods for generating radionuclides, such as radium-224. Systems herein may include a first cartridge having a first opening, a second opening, and a chamber therebetween having a first resin having affinity for thorium-228 and bismuth-212; a second cartridge having a first opening, a second opening, and a chamber therebetween having a second resin having affinity for thorium-228 and bismuth-212, a third cartridge having a first opening, a second opening, and a chamber therebetween comprising a third resin having affinity for thorium-228 and bismuth-212, a fourth cartridge having a first opening, a second opening, and a chamber therebetween having a third resin having affinity for lead-212; wherein a continuous flow path is formed from a top of the first cartridge though the second cartridge, through the third cartridge, and to a bottom of the fourth cartridge during system use.

Abstract: Systems and methods for generating radionuclides, such as radium-224. Systems herein may include a first cartridge having a first opening, a second opening, and a chamber therebetween having a first resin having affinity for thorium-228 and bismuth-212; a second cartridge having a first opening, a second opening, and a chamber therebetween having a second resin having affinity for thorium-228 and bismuth-212, a third cartridge having a first opening, a second opening, and a chamber therebetween comprising a third resin having affinity for thorium-228 and bismuth-212, a fourth cartridge having a first opening, a second opening, and a chamber therebetween having a third resin having affinity for lead-212; wherein a continuous flow path is formed from a top of the first cartridge though the second cartridge, through the third cartridge, and to a bottom of the fourth cartridge during system use.

Abstract: Systems and methods for generating radionuclides, such as radium-224, are disclosed herein. Systems herein may include a first cartridge having a first opening, a second opening, and a chamber therebetween having a first resin having affinity for thorium-228 and bismuth-212; a second cartridge having a first opening, a second opening, and a chamber therebetween having a second resin having affinity for thorium-228, a third cartridge having a first opening, a second opening, and a chamber therebetween comprising a third resin having affinity for thorium-228 and bismuth-212, and a fourth cartridge having a first opening, a second opening, and a chamber therebetween having a fourth resin having affinity for lead-212; wherein a continuous flow path is formed from a top of the first cartridge though the second cartridge, through the third cartridge, and to a bottom of the fourth cartridge during system use.

Abstract: Systems and methods for generating radionuclides, such as radium-224. Systems herein may include a first cartridge having a first opening, a second opening, and a chamber therebetween having a first resin having affinity for thorium-228 and bismuth-212; a second cartridge having a first opening, a second opening, and a chamber therebetween having a second resin having affinity for thorium-228 and bismuth-212, a third cartridge having a first opening, a second opening, and a chamber therebetween comprising a third resin having affinity for thorium-228 and bismuth-212, a fourth cartridge having a first opening, a second opening, and a chamber therebetween having a third resin having affinity for lead-212; wherein a continuous flow path is formed from a top of the first cartridge though the second cartridge, through the third cartridge, and to a bottom of the fourth cartridge during system use.

Abstract: A method for separating a lead radioisotope from a mixture comprising the lead radioisotope and a radioisotope of radium or thorium is provided, along with a system comprising a plurality of chromatographic columns. The system can include a first cartridge having a lead-complexing media that preferentially binds the lead radioisotope over radioisotopes of radium or thorium, and a second cartridge having a weak cationic exchange media, where a pH of a loading solution used to load the second cartridge is pH2L, and a pH of an eluent used to elute the lead radioisotope from the second cartridge is pH2E, and pH2L is greater than pH2E. The system can also comprise further third and fourth cartridges with chromatographic media to extract and purify the lead radioisotope, to provide a purified solution of lead radioisotope that can be used for medical and other purposes, such as in the labeling of radiopharmaceutical compounds.

Abstract: A method for separating a lead radioisotope from a mixture comprising the lead radioisotope and a radioisotope of radium or thorium is provided, along with a system comprising a plurality of chromatographic columns. The system can include a first cartridge having a lead-complexing media that preferentially binds the lead radioisotope over radioisotopes of radium or thorium, and a second cartridge having a weak cationic exchange media, where a pH of a loading solution used to load the second cartridge is pH2L, and a pH of an eluent used to elute the lead radioisotope from the second cartridge is pH2E, and pH2L is greater than pH2E. The system can also comprise further third and fourth cartridges with chromatographic media to extract and purify the lead radioisotope, to provide a purified solution of lead radioisotope that can be used for medical and other purposes, such as in the labeling of radiopharmaceutical compounds.

Abstract: A method for separating a lead radioisotope from a mixture comprising the lead radioisotope and a radioisotope of radium or thorium is provided, along with a system comprising a plurality of chromatographic columns. The system can include a first cartridge having a lead-complexing media that preferentially binds the lead radioisotope over radioisotopes of radium or thorium, and a second cartridge having a weak cationic exchange media, where a pH of a loading solution used to load the second cartridge is pH2L, and a pH of an eluent used to elute the lead radioisotope from the second cartridge is pH2E, and pH2L is greater than pH2E. The system can also comprise further third and fourth cartridges with chromatographic media to extract and purify the lead radioisotope, to provide a purified solution of lead radioisotope that can be used for medical and other purposes, such as in the labeling of radiopharmaceutical compounds.

Abstract: An instrumented flexible waterside security barrier system secures a waterside infrastructure to detect and localize a breach in the barrier caused by an intruder, thereby permitting a user to perform one or more security actions. The system includes a plurality of panels coupled together and disposed in the waterway, each panel having a plurality of optical fibers and a plurality of wire strength members embedded within a polyurethane layer, and a detection system connected to the plurality of panels to monitor the optical fibers in each panel to detect an attenuation of light in any one of the plurality of optical fibers caused by the breach. The detection system determines a location of the breach in the optical fibers, thereby permitting the user to perform the one or more security actions in response to the breach.

Abstract: A method for encapsulating an assembly with a methyl phenyl silicone rubber compound is provided. In various embodiments, the method can include exposing the assembly to a solvent, plasma etching the assembly, and producing a potting mixture, wherein the potting mixture comprises a methyl phenyl room temperature vulcanization silicone and a curing agent. The method can further include pouring the potting mixture over the assembly while under a vacuum until the assembly is encapsulated, pouring at least two control samples of the potting mixture while under the vacuum, curing the encapsulated assembly and the control samples in a first environment and monitoring the one of the control samples for hardness, and determining whether additional cure time in the first environment is needed based upon the results of the control sample hardness tests.

Abstract: A method for encapsulating an assembly with a methyl phenyl silicone rubber compound is provided. In various embodiments, the method can include exposing the assembly to a solvent, plasma etching the assembly, and producing a potting mixture, wherein the potting mixture comprises a methyl phenyl room temperature vulcanization silicone and a curing agent. The method can further include pouring the potting mixture over the assembly while under a vacuum until the assembly is encapsulated, pouring at least two control samples of the potting mixture while under the vacuum, curing the encapsulated assembly and the control samples in a first environment and monitoring the one of the control samples for hardness, and determining whether additional cure time in the first environment is needed based upon the results of the control sample hardness tests.