Abstract: A cannulation simulation device and methods for using the device are described. The device is designed to teach dialysis technicians/nurses or patients to cannulate arteriovenous (AV) fistulas for hemodialysis. The simulator includes one or more artificial fistulas. The simulator includes a pad of simulated flesh that can cover the artificial fistula(s). The pad can be reversed, rotated, and replaced with thicker or thinner pads. A personal simulation device for teaching self-cannulation can include a sleeve for a limb that can carry an artificial fistula. A clinical simulation device can include a plurality of artificial fistulas held in a support. Optionally, the artificial fistulas can vibrate to simulate an actual fistula.

Abstract: A retrofit cabling kit is suitable for use connecting an organ and a speaker, wherein the organ may be one of a Hammond® brand, model B3 or C3 organ and the speaker may be one of a Leslie® brand, model 122 or 147 speaker. The kit may include interfaces for attachment to each of the organ and the speaker and cables connecting the interfaces.

Abstract: A cannulation simulation device and methods for using the device are described. The device is designed to teach dialysis technicians/nurses or patients to cannulate arteriovenous (AV) fistulas for hemodialysis. The simulator includes one or more artificial fistulas. The simulator includes a pad of simulated flesh that can cover the artificial fistula(s). The pad can be reversed, rotated, and replaced with thicker or thinner pads. A personal simulation device for teaching self-cannulation can include a sleeve for a limb that can carry an artificial fistula. A clinical simulation device can include a plurality of artificial fistulas held in a support. Optionally, the artificial fistulas can vibrate to simulate an actual fistula.

Abstract: A retrofit cabling kit is suitable for use connecting an organ and a speaker, wherein the organ may be one of a Hammond® brand, model B3 or C3 organ and the speaker may be one of a Leslie® brand, model 122 or 147 speaker. The kit may include interfaces for attachment to each of the organ and the speaker and cables connecting the interfaces.

Abstract: A cannulation simulation device and methods for using the device are described. The device is designed to teach dialysis technicians/nurses or patients to cannulate arteriovenous (AV) fistulas for hemodialysis. The simulator includes one or more artificial fistulas. The simulator includes a pad of simulated flesh that can cover the artificial fistula(s). The pad can be reversed, rotated, and replaced with thicker or thinner pads. A personal simulation device for teaching self-cannulation can include a sleeve for a limb that can carry an artificial fistula. A clinical simulation device can include a plurality of artificial fistulas held in a support. Optionally, the artificial fistulas can vibrate to simulate an actual fistula.

Abstract: A power system for and method of operation of an arteriovenous access valve system including two valves positioned near arteriovenous grafts, an actuator assembly in fluid communication with the valves and including a driver assembly, at least one pressure sensor, a separate activator device for driving the driver assembly, and a sensor communications device communicatively coupled to the at least one pressure sensor for wirelessly transmitting pressure measurements. The power system and method also include using an initiator device located in the activator device to power remotely the sensor communications device, for example via near field communication such as via a radio frequency field.

Abstract: A power system for and method of operation of an arteriovenous access valve system including two valves positioned near arteriovenous grafts, an actuator assembly in fluid communication with the valves and including a driver assembly, at least one pressure sensor, a separate activator device for driving the driver assembly, and a sensor communications device communicatively coupled to the at least one pressure sensor for wirelessly transmitting pressure measurements. The power system and method also include using an initiator device located in the activator device to power remotely the sensor communications device, for example via near field communication such as via a radio frequency field.

Abstract: In one aspect, an arteriovenous access valve system may generally include a first valve configured to be positioned at or adjacent to an end of an arteriovenous graft and a second valve configured to be positioned at or adjacent to an opposite end of the arteriovenous graft. In addition, the system may include an actuator assembly in fluid communication with the first and second valves. The actuator assembly may include a housing, a driver assembly positioned within the housing and a drive magnet positioned within the housing. The drive magnet may be rotatably coupled to the driver assembly such that, when the drive magnet is rotated, the driver assembly is configured to be rotatably driven so as to supply fluid to the first and second valves or to draw fluid out of the first and second valves depending on a rotational direction of the driver assembly.

Abstract: The present invention is directed to an electronic data transfer cable comprising (a) a first end; (b) a second end; (c) a plurality of data transmission wires running the length of the data transmission cable; (d) an insulating sheath disposed at one of said data transfer cable first or second ends having a first end, a second end opposite the first end and connected to either of the data transfer cable first or second ends, at least one side surface extending between said insulating sheath first and second ends, and a tab extending outwardly from the sheath side surface and defining a through-hole; (e) a connector which slidably engages the through-hole; and (f) a plug extending outwardly from the sheath first end, the plug having a plurality of data transfer pins whereat said plurality of data transmission wires terminate.

Abstract: A device for an isochronous data communication system between a first data terminal having a first clock and a remote communication unit having a second clock. A clock multiplex circuit receives the first and second clock signals. A logic means selects either the first or second clock signal as a data timing signal. The data timing signal will correspond with the second clock signal if present, if no second clock signal is present then the data timing signal will correspond with the first clock signal. A communication control device receives the data timing signal for controlling the timing of the communication.

Abstract: A method and apparatus for storing data in which the data is checked for an error without requiring the data to include an error correction code. Included in the system is a logic circuit for dividing a data word by a polynomial during the time the data word is being written into the primary memory unit resulting in the generation of a remainder which is stored in an auxiliary memory unit. When reading the data word from the primary memory unit, the data word is again divided by the same polynomial and the remainder compared with the remainder stored in the auxiliary memory unit. If the remainders match, no error was introduced during the storing of the data in the main memory unit. If the remainders do not match, an error is indicated. This system allows a data word to be stored in a main or primary memory unit without requiring the word to include error correction bytes.