Abstract: A surgical instrument is disclosed herein. The surgical instrument can include an end effector that includes jaws configured to transition between an opened condition and a closed condition, a plurality of electrodes positioned within the jaws of the end effector, a control circuit, and a memory configured to store an algorithm configured to cause the control circuit to determine an impedance signal based on signals received from the plurality of electrodes, detect a media positioned between the jaws of the end effector based on the determined impedance signal, determine a position of the detected media based on the received signals, and generate an alert associated with the detected media and the determined position.

Abstract: A gaming device includes a processor and a memory storing symbol data, trigger probability data for wager options, and instructions. The symbol data includes reel strips including positions dynamically configurable with trigger symbols associated with feature games, and trigger symbol sets including different versions of the trigger symbols and corresponding to the wager options. The instructions, when executed, cause the processor to receive a selected wager option; configure the reel strips by selecting a trigger symbol from the trigger symbol set corresponding to the selected wager option for the dynamically configurable positions; select symbols from the configured reel strips for display in symbol positions; control display of the selected symbols; and upon the selected symbols including a trigger symbol associated with a feature game, determine whether the feature game is triggered based on the trigger probability data for the selected wager option and an identity of the trigger symbol.

Abstract: A system for treating and/or diagnosing tissue from a tissue surface comprises: a console; an interface assembly; and a mobile device. The mobile device is configured to navigate a tissue surface and can comprise: a first tissue attachment assembly; a second tissue attachment assembly; and at least one articulation assembly. The interface assembly operably connects the console to the mobile device. The console is configured to manipulate the at least one articulation assembly via the interface assembly. The at least one articulation assembly is configured to navigate from a first tissue location to a second tissue location. The mobile device is configured to diagnose and/or treat tissue at the second tissue location. Methods of treating and/or diagnosing tissue are also described.

Abstract: Non-limiting embodiments of the present disclosure relate to a method comprising: obtaining asphalt shingle waste (ASW) and performing grinding, screening, and separating steps on the ASW. In some embodiments, granules are removed from the ASW. In some embodiments, the method transforms ASW into ASW powder. In some embodiments, the ASW powder is formed into a plurality of briquettes. In some embodiments, at least one of: the ASW powder, the plurality of briquettes, or any combination thereof is fed into a mixing process that results in an ASW powder filled coating.

Abstract: Non-limiting embodiments of the present disclosure relate to a method comprising: obtaining asphalt shingle waste (ASW) and performing grinding, screening, and separating steps on the ASW. In some embodiments, granules are removed from the ASW. In some embodiments, the method transforms ASW into ASW powder. In some embodiments, the ASW powder is formed into a plurality of briquettes. In some embodiments, at least one of: the ASW powder, the plurality of briquettes, or any combination thereof is fed into a mixing process that results in an ASW powder filled coating.

Abstract: The present disclosure provides compositions and methods for expanding T cells or tumor infiltrating lymphocytes (TILs) in vitro. K562 feeder cells engineered to express a costimulatory molecule (e.g., 41BB ligand (41BBL)) and either interleukin 21 (IL21) or interleukin 7 (IL7) can be used in a rapid expansion protocol (REP) step to expand the T cells or TILs. Thus, provided herein is a culture comprising T-cells or TILs and modified K562 feeder cells. The T cells can be modified to express a chimeric antigen receptor (CAR) or a T cell receptor (TCR) or the TILs can be modified to express membrane-bound IL15 (mbIL15). The T cells or TILs can be expanded in vitro using aREP without the use of exogenous interleukin 2 (IL2), and the expanded cells can be used in adoptive cell therapy for treatment of cancer without concomitant use of an exogenous cytokine such as IL2.

Abstract: An apparatus includes a first member coupled to a second member. The first member defines a chamber containing a dry powder and includes a chamber wall that forms an outer boundary of the chamber. The second member includes a surface covering the chamber and defines an intake channel and an exit channel. The exit channel is fluidically coupled to the chamber via an exit opening. The intake channel is fluidically coupled to the chamber via an intake port. A center line of the intake channel is tangential to a portion of the chamber wall such that a portion of an inlet airflow conveyed into the chamber via the intake channel has a rotational motion. The intake port is defined at least in part by an intake ramp. The intake ramp includes a transition surface that forms an exit angle with respect to the surface of less than 105 degrees.

Abstract: A charging apparatus for a vehicle where a terminal (1, FIG. 2) is connected to at least one kerbside power/data unit (9) to provide a power (4) and a data connection (5) to the power/data unit (9), the power/data unit (9) being connected to a nearby vehicle (17) to provide power to charge the vehicle (17) and receive data from the vehicle (17). The fact that the kerbside power/data unit (9) can charge a vehicle (17) using power supplied from a terminal (1, FIG. 2) and can transmit data from the vehicle (17) to the terminal (1, FIG. 2) provides the power and data requirements for connected autonomous vehicles at a kerbside location.

Abstract: A charging apparatus for a vehicle where a terminal (1, FIG. 2) is connected to at least one kerbside power/data unit (9) to provide a power (4) and a data connection (5) to the power/data unit (9), the power/data unit (9) being connected to a nearby vehicle (17) to provide power to charge the vehicle (17) and receive data from the vehicle (17). The fact that the kerbside power/data unit (9) can charge a vehicle (17) using power supplied from a terminal (1, FIG. 2) and can transmit data from the vehicle (17) to the terminal (1, FIG. 2) provides the power and data requirements for connected autonomous vehicles at a kerbside location.

Abstract: A surgical instrument is disclosed herein. The surgical instrument can include an end effector that includes jaws configured to transition between an opened condition and a closed condition, a plurality of electrodes positioned within the jaws of the end effector, a control circuit, and a memory configured to store an algorithm configured to cause the control circuit to determine an impedance signal based on signals received from the plurality of electrodes, detect a media positioned between the jaws of the end effector based on the determined impedance signal, determine a position of the detected media based on the received signals, and generate an alert associated with the detected media and the determined position.

Abstract: A method of, and apparatus for, aligning an ophthalmic instrument relative to an eye is disclosed, and can include aligning an esthesiometer with a patient's eye. Other aspects of the method and apparatus of the present invention are further described herein.

Abstract: A surgical instrument is disclosed herein. The surgical instrument can include an end effector comprising a first jaw and a second jaw, a plurality of electrodes positioned within the jaws of the end effector, a flexible circuit comprising a conductive track configured for multiplexed transmission of a plurality of signals to and from the end effector, a control circuit communicably coupled to the plurality of electrodes via the flexible conductor, and a memory configured to store an algorithm configured to cause the control circuit to: receive signals from the plurality of electrodes; determine an impedance based on the signals received from the plurality of electrodes; detect a media positioned between the jaws of the end effector based on the impedance; determine a position of the detected media along the longitudinal axis based on the received signals; and generate an alert associated with the detected media and the determined position.

Abstract: The present invention is directed to an electrochemical device for at least partially removing or reducing a target ionic species from an aqueous solution using faradic immobilization, the electrochemical device including at least one first electrode and at least one second electrode with different void fraction and surface area properties, due to differences in void fraction (also referred to as void ratio) of the at least one first and the at least one second electrode, water flows through an electrode with a high porosity, while the aqueous solution does not flow through an electrode with a low porosity. The asymmetry of the electrodes provides a desired voltage distribution across the device, which equates to a different voltage at each electrode, to control the speciation of the target ionic species at the anode and the cathode.

Abstract: A wireless load cell monitoring system and method may comprise a remote load cell assembly and a base station. Embodiments of the remote load cell assembly comprise a remote processor, a remote memory, a battery, a remote transceiver, an analog-to-digital converter, and a load cell. Embodiments of the base station comprise a base processor, a base memory, a base transceiver, and a digital-to-analog converter. Embodiments of the remote load cell assembly pair with the base station using a wireless communication protocol, read analog voltage data from the load cell, convert the load cell analog voltage data into digital load data, and transmit the digital load data to the base station. Embodiments of the base station convert the digital load data into analog voltage data and output the analog voltage data.

Abstract: A ferroresonant transformer assembly comprising, a core, a main shunt, first, second, and third windings, first and second tap connectors, and a selection connector. The first windings configured to be operatively connected to a primary power source. The first tap connector operatively connected to a first intermediate point defined by the third windings. The second tap connector operatively connected to a second intermediate point defined by the third windings. The selection connector operatively connected to the at least one load. Based on voltage requirements of the at least one load, the selection connector is operatively selectively connected to a selected tap connector selected from the first and second tap connectors.

Abstract: A wireless load cell monitoring system and method may comprise a remote load cell assembly and a base station. Embodiments of the remote load cell assembly comprise a remote processor, a remote memory, a battery, a remote transceiver, an analog-to-digital converter, and a load cell. Embodiments of the base station comprise a base processor, a base memory, a base transceiver, and a digital-to-analog converter. Embodiments of the remote load cell assembly pair with the base station using a wireless communication protocol, read analog voltage data from the load cell, convert the load cell analog voltage data into digital load data, and transmit the digital load data to the base station. Embodiments of the base station convert the digital load data into analog voltage data and output the analog voltage data.

Abstract: A method of installing an insert in an aperture of a panel includes inserting a sleeve central portion into the aperture so that a sleeve flange opposes a first side of the panel. The sleeve central portion extends from the sleeve flange. The method further includes inserting a plug central portion into the aperture so that a plug flange opposes a second side of the panel. The plug central portion extends from the plug flange. The method also includes pressing at least one of the plug and sleeve into sliding engagement with the other until the plug and sleeve are installed. When installed, a distal end of the plug is received into a sleeve cavity and resilient beams defined by an extension of the sleeve central portion are elastically deflected by a wall of the plug central portion. The plug flange defines an aperture extending into a plug cavity.

Abstract: A charging apparatus for a vehicle where a terminal (1, FIG. 2) is connected to at least one kerbside power/data unit (9) to provide a power (4) and a data connection (5) to the power/data unit (9), the power/data unit (9) being connected to a nearby vehicle (17) to provide power to charge the vehicle (17) and receive data from the vehicle (17). The fact that the kerbside power/data unit (9) can charge a vehicle (17) using power supplied from a terminal (1, FIG. 2) and can transmit data from the vehicle (17) to the terminal (1, FIG. 2) provides the power and data requirements for connected autonomous vehicles at a kerbside location.

Abstract: Discloses are systems, methods and computer readable mediums for automated verifications of potential vulnerabilities of one or more sites or code utilizing one or more neural networks. The systems, methods and computer readable mediums can transmit one or more scan operations to one or more sites, receive one or more responses to the one or more scan operations, tokenize the one or more responses, transmit to one or more neural networks the one or more tokenized responses, receive from the one or more neural networks verification of the one or more tokenized responses, and determine one or more confidences of the one or more verified responses.

Abstract: A ferroresonant transformer assembly comprising, a core, a main shunt, first, second, and third windings, first and second tap connectors, and a selection connector. The first windings configured to be operatively connected to a primary power source. The first tap connector operatively connected to a first intermediate point defined by the third windings. The second tap connector operatively connected to a second intermediate point defined by the third windings. The selection connector operatively connected to the at least one load. Based on voltage requirements of the at least one load, the selection connector is operatively selectively connected to a selected tap connector selected from the first and second tap connectors.