Abstract: Tissue stabilizing devices and methods for stabilizing, and optionally closing, a target tissue, such as the left atrial appendage, generally include an elongate body with a first lumen and a second lumen, a suction tip coupled to the elongate body, and an injection tip coupled to the elongate body proximal of the suction tip. The suction tip may define a suction aperture and the suction aperture may be in fluid communication with the first lumen to apply suction to the target tissue. The injection tip may be in fluid communication with the second lumen to dispense a contrast fluid.

Abstract: Described here are devices, systems, and methods for closing the left atrial appendage. The methods described here utilize a closure device for closing the left atrial appendage and guides or expandable elements with ablation or abrading elements to ablate or abrade the left atrial appendage. In general, these methods include positioning a balloon at least partially within the atrial appendage, positioning a closure assembly of a closure device around an exterior of the atrial appendage, inflating the balloon, partially closing the closure assembly, ablating the interior tissue of the atrial appendage with the inflated balloon, removing the balloon from the atrial appendage, and closing the atrial appendage with the closure assembly.

Abstract: Provided are methods of forming stiffened stringer panels with integrated plank structures. A skin member having an inner surface is provided. A plank is positioned onto the inner surface of the skin member. The plank extends from a first side to a second side, and each laminate ply of the set of layered laminate plies is sized to form a geometric profile for each of the first side and the second side. Each laminate ply of the set of layered laminate plies is arranged to extend from the first side to the second side. A stringer is placed onto a support tool. The support tool, and the stringer thereon, is positioned upon an uppermost laminate ply of the set of layered laminate plies. The skin member, the plank, and the stringer are joined.

Abstract: Provided are methods of forming stiffened stringer panels with integrated plank structures. A skin member having an inner surface is provided. A plank is positioned onto the inner surface of the skin member. The plank extends from a first side to a second side, and each laminate ply of the set of layered laminate plies is sized to form a geometric profile for each of the first side and the second side. Each laminate ply of the set of layered laminate plies is arranged to extend from the first side to the second side. A stringer is placed onto a support tool. The support tool, and the stringer thereon, is positioned upon an uppermost laminate ply of the set of layered laminate plies. The skin member, the plank, and the stringer are joined.

Abstract: Provided are stiffened stringer panels with integrated plank structures. An example composite panel comprises a skin member having an inner surface, and a plank on the inner surface. The plank comprises a set of layered laminate plies and extends from a first side to a second side. Each laminate ply of the set of layered laminate plies is sized to form a desired geometric profile for each of the first side and the second side. The composite panel further comprises a stringer including a cap portion that spans from the first side of the plank to the second side of the plank to form a first flange portion and a second flange portion, respectively, on the inner surface of the skin member. Base segments of the cap portion conform to the desired geometric profile of respective first and second sides of the plank.

Abstract: Induction-heated vessels, and processes for manufacturing induction-heated vessels and vessel components, are provided. The vessels can include a ceramic outer layer and a conductive heating element, which can be provided as a conductive glaze or coating, a conductive inner layer, or a label comprising a conductive element and an RFID tag, to allow the thermal transfer or conduction of heat from the heated surface directly to the contents of the vessel, while the ceramic outer layer of the vessel insulates the contents of the vessel. Also, systems and methods for heating and controlling induction-heated vessels and for tracking loyalty, use, and/or sales using RFID-enabled induction-heated vessels are provided.

Abstract: A system and method for integrating inductive heating into packaging and other product vessels that allows for controlled heat distribution. The system and method provides for multidimensional heating of a packaged item on multiple sides at the same time using electromagnetic energy emitted from a single source. The inductively heated package may include a heating element having a plurality of conductive elements configured to implement a desired heating profile. The conductive elements may be arranged in layers to allow heating on different surfaces of a packaged item. Each layer of the heating element may be configured to distribute the available energy as needed for an ultimate cooking experience. The present invention provides a method of design where the sum of the available energy is distributed in accordance with the desired heating profile.

Abstract: An intelligent heating system and method for providing varied heating experiences to food product packages and their contents in connection with pick-up food service, delivery food service, or both. The intelligent heating system dynamically controls energy provided to food packages and their contents in order to provide different heating experiences. The system can use location information to heat the food just before pick-up or delivery to enhance the consumption experience. The system can also control temperature to reduce the amount of condensation that forms within the package.

Abstract: A smart package and/or a smart tag may be used for inductive heating. The inductive heating may comprise heating a food product, a beverage product, and/or any other substance. The smart package and/or tag may comprise at least one of: an antenna (e.g., for radio frequency communications), a communication module (e.g., for communicating information relating to inductive heating), and/or an inductive receptor (e.g., for transferring heat to a substance). The inductive receptor may be configured to avoid/minimize contact and/or to avoid/minimize interference with the communication module and/or with the antenna, which may provide various advantages as described herein.

Abstract: Various smart package configurations may include a package intelligence and communication module (PICM) intelligently interacting with smart heating appliances and users. A thermodynamic load profile may correlate thermodynamic response characteristics of the package and be stored in or associated with a unique identifier in the PICM. The TLP enables efficient and safe heating of packages on a smart appliance as well as package validation and authentication. Package configurations also include structural elements for efficient heating of food, beverage, cosmetic and personal care products.

Abstract: A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.

Abstract: Provided are stiffened stringer panels with integrated plank structures. An example composite panel comprises a skin member having an inner surface, and a plank on the inner surface. The plank comprises a set of layered laminate plies and extends from a first side to a second side. Each laminate ply of the set of layered laminate plies is sized to form a desired geometric profile for each of the first side and the second side. The composite panel further comprises a stringer including a cap portion that spans from the first side of the plank to the second side of the plank to form a first flange portion and a second flange portion, respectively, on the inner surface of the skin member. Base segments of the cap portion conform to the desired geometric profile of respective first and second sides of the plank.

Abstract: A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.

Abstract: Induction-heated vessels, and processes for manufacturing induction-heated vessels and vessel components, are provided. The vessels can include a ceramic outer layer and a conductive heating element, which can be provided as a conductive glaze or coating, a conductive inner layer, or a label comprising a conductive element and an RFID tag, to allow the thermal transfer or conduction of heat from the heated surface directly to the contents of the vessel, while the ceramic outer layer of the vessel insulates the contents of the vessel. Also, systems and methods for heating and controlling induction-heated vessels and for tracking loyalty, use, and/or sales using RFID-enabled induction-heated vessels are provided.

Abstract: A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.

Abstract: Various smart package configurations may include a package intelligence and communication module (PICM) intelligently interacting with smart heating appliances and users. A thermodynamic load profile may correlate thermodynamic response characteristics of the package and be stored in or associated with a unique identifier in the PICM. The TLP enables efficient and safe heating of packages on a smart appliance as well as package validation and authentication. Package configurations also include structural elements for efficient heating of food, beverage, cosmetic and personal care products.

Abstract: A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.

Abstract: Various smart package configurations may include a package intelligence and communication module (PICM) intelligently interacting with smart heating appliances and users. A thermodynamic load profile may correlate thermodynamic response characteristics of the package and be stored in or associated with a unique identifier in the PICM. The TLP enables efficient and safe heating of packages on a smart appliance as well as package validation and authentication. Package configurations also include structural elements for efficient heating of food, beverage, cosmetic and personal care products.

Abstract: Various smart package configurations may include a package intelligence and communication module (PICM) intelligently interacting with smart heating appliances and users. A thermodynamic load profile may correlate thermodynamic response characteristics of the package and be stored in or associated with a unique identifier in the PICM. The TLP enables efficient and safe heating of packages on a smart appliance as well as package validation and authentication. Package configurations also include structural elements for efficient heating of food, beverage, cosmetic and personal care products.

Abstract: A smart inductive heating appliance includes an interface for interacting with a package intelligence and communication module on a smart package. The smart heating appliance may also detect and charge chargeable devices inductively. A number of data sets may be utilized to enhance control of heating/cooking and to enhance safety. A thermodynamic load profile of the package may include detailed data correlations established in a package testing step and utilized to control heating of the package as well as to validate and authenticate the package.