Abstract: A system of generating an aerosol, by: (a) placing a liquid into a liquid chamber in an ultrasonic nebulization system having a cylindrical aerosol production chamber received within a cylindrical master chamber, and having top and bottom ultrasonic transducers; (b) passing air up through the aerosol production chamber; and (c) producing acoustic standing waves above the surface of the liquid with the top and bottom ultrasonic transducers, thereby generating an aerosol of the liquid by action of the standing waves.

Abstract: A vent bypass system is created by forming a bypass hole through a vent cover door of two adjacent vent cover doors. A tube flange is extended from a bottom surface of the vent cover door, concentric with the bypass hole. A first vent cover door covers an entry vent and the second vent cover door covers an exit vent. One end of a flexible tube is secured to one of the two tube flanges and the other end of the flexible tube is secured to the other one of the two tube flanges. Air/gas blown into the room will bypass circulating through the room by going through the flexible tube from the entry vent to the exit vent. Any suitable means to connect the various vents can be used, such as, but not limited to any pipe, hose, tube, conduit, or the like.

Abstract: A vent bypass system is created by forming a bypass hole through a vent cover door of two adjacent vent cover doors. A tube flange is extended from a bottom surface of the vent cover door, concentric with the bypass hole. A first vent cover door covers an entry vent and the second vent cover door covers an exit vent. One end of a flexible tube is secured to one of the two tube flanges and the other end of the flexible tube is secured to the other one of the two tube flanges. Air/gas blown into the room will bypass circulating through the room by going through the flexible tube from the entry vent to the exit vent. Any suitable means to connect the various vents can be used, such as, but not limited to any pipe, hose, tube, conduit, or the like.

Abstract: An improved apparatus and methods are presented for a new and improved ultrasonic aerosol generation apparatus and air/gas and deployed aerosol movement system, which is able to increase and improve the reliability and quality of coverage and treatment of the various targeted surfaces within an enclosed space, with the generated and deployed disinfecting aerosol, by providing an improved system to detect one or more of any layers and stratifications of gas(s) and deployed aerosols within the atmosphere of the treated area(s) at any time, and a means to remove and effectively disrupt, the said layers, so the deployed aerosol can effectively treat the targeted area(s), as well as additional enhancements to the systems used for processing the atmosphere in the targeted area(s) after the treatment cycle has completed deploying the aerosol, such as improving the cleaning of the dehumidification device, and the effective operation of the dehumidification and filter components.

Abstract: An improved apparatus and methods are presented for a new and improved ultrasonic aerosol generation apparatus and air/gas and deployed aerosol movement system, which is able to increase and improve the reliability and quality of coverage and treatment of the various targeted surfaces within an enclosed space, with the generated and deployed disinfecting aerosol, by providing an improved system to detect one or more of any layers and stratifications of gas(s) and deployed aerosols within the atmosphere of the treated area(s) at any time, and a means to remove and effectively disrupt, the said layers, so the deployed aerosol can effectively treat the targeted area(s), as well as additional enhancements to the systems used for processing the atmosphere in the targeted area(s) after the treatment cycle has completed deploying the aerosol, such as improving the cleaning of the dehumidification device, and the effective operation of the dehumidification and filter components.

Abstract: An improved apparatus and methods are presented for a new and improved ultrasonic aerosol generation apparatus and air/gas and deployed aerosol movement system, which is able to increase and improve the reliability and quality of coverage and treatment of the various targeted surfaces within an enclosed space, with the generated and deployed disinfecting aerosol, by providing an improved system to detect one or more of any layers and stratifications of gas(s) and deployed aerosols within the atmosphere of the treated area(s) at any time, and a means to remove and effectively disrupt, the said layers, so the deployed aerosol can effectively treat the targeted area(s), as well as additional enhancements to the systems used for processing the atmosphere in the targeted area(s) after the treatment cycle has completed deploying the aerosol, such as improving the cleaning of the dehumidification device, and the effective operation of the dehumidification and filter components.

Abstract: An ultrasonic aerosol generation apparatus preferably includes an aerosol generation case, a case cover, at least one outlet pipe, an air feed manifold, at least one, transducer, transducer power supply, and microprocessor based controller. The aerosol generation case preferably includes a fluid reservoir and a transducer chamber. The case cover is attached to a top of the aerosol generation case. Each outlet pipe preferably includes an outer base tube, an inner tube and an exhaust tube. The at least one outlet pipe is attached to the case cover over the at least one transducer. The air feed manifold includes an inlet tube, a supply tube and at least one exhaust pipe tube. The supply tube communicates with the transducer chamber and the at least one exhaust pipe communicates with the at least one outlet pipe. The microprocessor based controller is used to monitor, power, and/or control, the above mentioned components.

Abstract: An ultrasonic aerosol generation apparatus preferably includes an aerosol generation case, a case cover, at least one outlet pipe, an air feed manifold, at least one, transducer, transducer power supply, and microprocessor based controller. The aerosol generation case preferably includes a fluid reservoir and a transducer chamber. The case cover is attached to a top of the aerosol generation case. Each outlet pipe preferably includes an outer base tube, an inner tube and an exhaust tube. The at least one outlet pipe is attached to the case cover over the at least one transducer. The air feed manifold includes an inlet tube, a supply tube and at least one exhaust pipe tube. The supply tube communicates with the transducer chamber and the at least one exhaust pipe communicates with the at least one outlet pipe. The microprocessor based controller is used to monitor, power, and/or control, the above mentioned components.

Abstract: An ultrasonic aerosol generation apparatus preferably includes an aerosol generation case, a case cover, at least one outlet pipe, an air feed manifold, at least one, transducer, transducer power supply, and microprocessor based controller. The aerosol generation case preferably includes a fluid reservoir and a transducer chamber. The case cover is attached to a top of the aerosol generation case. Each outlet pipe preferably includes an outer base tube, an inner tube and an exhaust tube. The at least one outlet pipe is attached to the case cover over the at least one transducer. The air feed manifold includes an inlet tube, a supply tube and at least one exhaust pipe tube. The supply tube communicates with the transducer chamber and the at least one exhaust pipe communicates with the at least one outlet pipe. The microprocessor based controller is used to monitor, power, and/or control, the above mentioned components.

Abstract: An ultrasonic aerosol generation apparatus preferably includes an aerosol generation case, a case cover, at least one outlet pipe, an air feed manifold, at least one, transducer, transducer power supply, and microprocessor based controller. The aerosol generation case preferably includes a fluid reservoir and a transducer chamber. The case cover is attached to a top of the aerosol generation case. Each outlet pipe preferably includes an outer base tube, an inner tube and an exhaust tube. The at least one outlet pipe is attached to the case cover over the at least one transducer. The air feed manifold includes an inlet tube, a supply tube and at least one exhaust pipe tube. The supply tube communicates with the transducer chamber and the at least one exhaust pipe communicates with the at least one outlet pipe. The microprocessor based controller is used to monitor, power, and/or control, the above mentioned components.

Abstract: A vent cover system preferably includes a portable automated vent cover and a vacuum release door. The portable automated vent cover includes a drive system, a telescoping tube, a vent cover door and a collapsible mobile tripod. A vacuum break opening is formed through a middle of the vent cover door. The vacuum release door preferably includes a vacuum door plate, a plurality of retention pins, a sealing gasket and a tube flange. A plurality of pin holes are formed around a perimeter of the vacuum door plate to receive the plurality of retention pins. The plurality of retention pin are inserted through the plurality of pin holes and attached to the vent cover door. The tube flange includes an opening, which is sized to snugly receive an inner cover tube of the telescoping tube and is attached to a bottom of the vacuum door plate.

Abstract: The present invention refers to methods for determining the interaction between a nucleic acid molecule and a nucleic acid binding molecule. The methods of the invention are particularly suitable for the analysis of genes associated with pathologic disorders and for the identification of novel therapeutic agents.