Abstract: An airship may include a geodesic frame and a material at least substantially enclosing the geodesic frame and configured to contain a gas within a volume enclosed by the material. A vent may be configured to selectively open and close, wherein when the vent is open, the volume enclosed by the material is in fluid communication with an exterior of the material, and when the vent is closed, the volume enclosed by the material is impeded from passing to the exterior of the material. The material may be configured to absorb solar radiation to heat the gas within the volume enclosed by the material. The vent may be configured to selectively open or close to maintain a pressure within the volume enclosed by the material at least substantially equal to an atmospheric pressure.

Abstract: An airship may include a plurality of struts and a plurality of hubs joined to form a geodesic frame. A material may at least substantially enclose the frame. The material may be configured to contain a gas within a volume enclosed by the material, and may also be configured to absorb solar radiation for heating the gas. The airship may include a vent configured to selectively open and close to regulate one or more of a temperature and a pressure of the gas. When the vent is open, the volume enclosed by the material may be in fluid communication with an exterior of the material. When the vent is closed, the volume enclosed by the material may be at least substantially hermetically sealed from the exterior of the material. Also disclosed are methods of carrying a payload with the airship.

Abstract: A system including a self-expanding prosthesis configured to foreshorten during deployment thereof and a delivery device configured to percutaneously deliver the self-expanding prosthesis. The delivery device includes a handle having an actuator thereon, an outer sheath including a proximal end coupled to the handle and a pusher shaft slidingly disposed within the outer sheath. The pusher shaft has a proximal end coupled to the handle and a distal end configured to releasably couple to the self-expanding prosthesis such that the self-expanding prosthesis axially moves therewith. The inner shaft has a distal portion of the inner shaft that is configured to receive a self-expanding prosthesis thereon. The outer sheath and the pusher shaft are configured to simultaneously move in opposing axial directions via actuation of the actuator on the handle to compensate for the foreshortening of the self-expanding prosthesis during deployment.

Abstract: A system including a self-expanding prosthesis configured to foreshorten during deployment thereof and a delivery device configured to percutaneously deliver the self-expanding prosthesis. The delivery device includes a handle having an actuator thereon, an outer sheath including a proximal end coupled to the handle and a pusher shaft slidingly disposed within the outer sheath. The pusher shaft has a proximal end coupled to the handle and a distal end configured to releasably couple to the self-expanding prosthesis such that the self-expanding prosthesis axially moves therewith. The inner shaft has a distal portion of the inner shaft that is configured to receive a self-expanding prosthesis thereon. The outer sheath and the pusher shaft are configured to simultaneously move in opposing axial directions via actuation of the actuator on the handle to compensate for the foreshortening of the self-expanding prosthesis during deployment.

Abstract: An airship may include a plurality of struts and a plurality of hubs joined to form a geodesic frame. A material may at least substantially enclose the frame. The material may be configured to contain a gas within a volume enclosed by the material, and may also be configured to absorb solar radiation for heating the gas. The airship may include a vent configured to selectively open and close to regulate one or more of a temperature and a pressure of the gas. When the vent is open, the volume enclosed by the material may be in fluid communication with an exterior of the material. When the vent is closed, the volume enclosed by the material may be at least substantially hermetically sealed from the exterior of the material. Also disclosed are methods of carrying a payload with the airship.

Abstract: A system including a self-expanding prosthesis configured to foreshorten during deployment thereof and a delivery device configured to percutaneously deliver the self-expanding prosthesis. The delivery device includes a handle having an actuator thereon, an outer sheath including a proximal end coupled to the handle and a pusher shaft slidingly disposed within the outer sheath. The pusher shaft has a proximal end coupled to the handle and a distal end configured to releasably couple to the self-expanding prosthesis such that the self-expanding prosthesis axially moves therewith. The inner shaft has a distal portion of the inner shaft that is configured to receive a self-expanding prosthesis thereon. The outer sheath and the pusher shaft are configured to simultaneously move in opposing axial directions via actuation of the actuator on the handle to compensate for the foreshortening of the self-expanding prosthesis during deployment.

Abstract: A system including a self-expanding prosthesis configured to foreshorten during deployment thereof and a delivery device configured to percutaneously deliver the self-expanding prosthesis. The delivery device includes a handle having an actuator thereon, an outer sheath including a proximal end coupled to the handle and a pusher shaft slidingly disposed within the outer sheath. The pusher shaft has a proximal end coupled to the handle and a distal end configured to releasably couple to the self-expanding prosthesis such that the self-expanding prosthesis axially moves therewith. The inner shaft has a distal portion of the inner shaft that is configured to receive a self-expanding prosthesis thereon. The outer sheath and the pusher shaft are configured to simultaneously move in opposing axial directions via actuation of the actuator on the handle to compensate for the foreshortening of the self-expanding prosthesis during deployment.

Abstract: A system including a self-expanding prosthesis configured to foreshorten during deployment thereof and a delivery device configured to percutaneously deliver the self-expanding prosthesis. The delivery device includes a handle having an actuator thereon, an outer sheath including a proximal end coupled to the handle and a pusher shaft slidingly disposed within the outer sheath. The pusher shaft has a proximal end coupled to the handle and a distal end configured to releasably couple to the self-expanding prosthesis such that the self-expanding prosthesis axially moves therewith. The inner shaft has a distal portion of the inner shaft that is configured to receive a self-expanding prosthesis thereon. The outer sheath and the pusher shaft are configured to simultaneously move in opposing axial directions via actuation of the actuator on the handle to compensate for the foreshortening of the self-expanding prosthesis during deployment.

Abstract: A rectangular shaped lockable bin is defined by four walls and a bottom wall. A lid is hingedly mounted to the rear wall and has a slot located in a front portion thereof. A lock having a latch is pivotably mounted to the front wall of said bin at a pivot point and is configured to be selectively rotated between a locked position and an unlocked position by an actuator. A tail extending from the lock contacts a post located on the wall of the bin and basis the lock in the unlocked position. A series of such bins may be received in a delivery module, which may be received in a drawer.

Abstract: The exemplary embodiments herein provide a method for controlling access to medications. The method preferably includes the step of electronically unlocking a lid for a single bin out of a plurality of bins within a delivery module at a first location, to accept a medication into the unlocked bin, where the rest of the bins in the same delivery module remain locked. The method should then engage a mechanical lock on the lid once it has been closed, maintain the bin in a locked state during transport to a second location, and engage a mechanical lock on the delivery module once it has been lowered into a drawer at the second location.

Abstract: The exemplary embodiments herein provide a medical cart having a drawer with a post which extends upwardly from a bottom surface of the drawer. The cart further includes a removable medication delivery module having four sidewalls and a bottom wall as well as a plurality of individually-lockable bins placed above the bottom wall and within the four sidewalls. A lock may be positioned above the bottom wall and below the plurality of individually-lockable bins with an aperture on the lock which engages with the post and a hole in the bottom wall sized to accept the post.

Abstract: A rectangular shaped lockable bin is defined by four walls and a bottom wall. A lid is hingedly mounted to the rear wall and has a slot located in a front portion thereof. A lock having a latch is pivotably mounted to the front wall of said bin at a pivot point and is configured to be selectively rotated between a locked position and an unlocked position by an actuator. A tail extending from the lock contacts a post located on the wall of the bin and basis the lock in the unlocked position. A series of such bins may be received in a delivery module, which may be received in a drawer.

Abstract: The exemplary embodiments herein provide a method for controlling access to medications. The method preferably includes the step of electronically unlocking a lid for a single bin out of a plurality of bins within a delivery module at a first location, to accept a medication into the unlocked bin, where the rest of the bins in the same delivery module remain locked. The method should then engage a mechanical lock on the lid once it has been closed, maintain the bin in a locked state during transport to a second location, and engage a mechanical lock on the delivery module once it has been lowered into a drawer at the second location.

Abstract: The exemplary embodiments herein provide a medical cart having a drawer with a post which extends upwardly from a bottom surface of the drawer. The cart further includes a removable medication delivery module having four sidewalls and a bottom wall as well as a plurality of individually-lockable bins placed above the bottom wall and within the four sidewalls. A lock may be positioned above the bottom wall and below the plurality of individually-lockable bins with an aperture on the lock which engages with the post and a hole in the bottom wall sized to accept the post.

Abstract: A system for Remote and Automated Manufacture of Products from User Data is designed to allow a user with no knowledge of design, engineering, or manufacturing to create a custom product from data they provide, in the form of tomography data, photographs, voice command, sketches etc. The system provides a user interface, the Front End, where users input data and select what to manufacture. This information is then sent to the Back End, which processes the data, creates a manufacturable 3D model, determines the best production method, and calculates a price and the amount of time required to make and deliver the product. This information is presented to the user, who confirms the proposal or makes changes the selection, materials etc, until they are happy with the result. Once they confirm their order, the system automatically produces the object and it is shipped to the user.

Abstract: An intelligent energy management system contains one or more autonomous modules. Modules may be portable or stationary. Each consists of an intelligent controller, power converters, distribution bus, and energy storage unit, and can function independently. The intelligent controller uses artificial intelligent algorithms to learn from past performance and improves itself during operation. The system can interface with a variety of energy sources. When connected together the modules form a micro-grid which manages, stores, and distributes power. Each module in the intelligent micro-grid may be different. Each module may connect to different types of energy generation or contain different energy storage units. The system might consist of modules with energy storage units that may be removable from each module. In another embodiment, energy generation may also be integrated into each module. In another, each module may be used alone or with external energy sources, but without other modules.