A portable device for monitoring vascular access status is disclosed. The portable device comprises a measurement device and a monitoring module. The measurement device senses vibration data induced by blood flow over certain part of a vascular access of a subject via a vibration-sensing module, and sends the sensed data to outside via its communication module. The monitor module controls an electronic device to receive the sensed data and determines a vibration evaluation index corresponding to a status of the part of the vascular access. The portable device for monitoring vascular access status of the present disclosed example has advantages of small size, easy to carry, low cost, and so on, so as to be applicable to home vascular access status monitor.

A device for monitoring fluid leakage. A flexible plastic sheet (11) is provided with a tear-off strip (12), which divides the sheet in a first sheet portion (21) and a second sheet portion (20) and forms a folding line. An adhesive (22) is arranged at the first portion (21). The sheet is folded along the folding line and the first portion is attached to the second portion via the adhesive to form a pocket along the folding line for enclosing a connector and hose assembly to be monitored. An optical sensor having an absorbent pad and an optical fiber is enclosed in said pocket when formed. The exterior end of the optical fiber is connected to an optical detector device for monitoring if the interior end of the optical fiber comes into contact with a fluid, indicating a leakage of the connector.

An access cannula which includes a dwell tube that serves as an access during treatment. A blocking device that maintains the dwell tube kinked in an idle position. In the idle position, the dwell tube is maintained kinked, preferably at a predetermined kink point that corresponds to a position in which a force exerted by the blocking device upon the dwell tube, the elastic reset force of the dwell tube and, where appropriate, a pressure prevailing in the dwell tube, balance one another.

A method for blood flow assessment in an arteriovenous (AV) fistula includes steps of: emitting a carrier radio wave toward the AV fistula, and receiving a return wave signal; generating a transmission signal based on the return wave signal; recovering a digital signal from the transmission signal, performing a digital filtering process on the digital signal to result in a filtered signal, and generating a plurality of graphic files based on a waveform of the filtered signal; and performing image recognition on the graphic files, and outputting a result of the image recognition as a result of the blood flow assessment of the AV fistula.

The present disclosure relates to a hemodialysis catheter that can monitor intravascular pressure using a MEMS sensor. The hemodialysis catheter comprises a venous lumen, an atrial lumen, and at least one MEMS system sensor. The hemodialysis catheter also comprises a data acquisition and processing system. The hemodialysis catheter can communicate with a monitor system to display pressure data.

The present invention refers to a container comprising a connection portion allowing for an easy, efficient and more hygienic connection of the container to a fluid dosing unit of a blood treatment device. According to the present invention the fluid dosing unit comprises a valve that fluidically closes the fluid dosing unit if no container is connected to the fluid dosing unit and that opens the fluid dosing unit upon connection of a container to the fluid dosing unit. Thus, undesired spillages potentially arising upon disconnection of the container from the fluid dosing unit can be avoided.

The present invention refers to a system and method for opening a concentrate container without the need for a human to directly handle the concentrate container and connecting the concentrate container to a blood treatment device. Aspects of the invention are directed to a container for concentrate and a blood treatment device.

The present invention refers to a system and method for connecting a concentrate container with a blood treatment device with improved hygiene. Furthermore, the invention refers to a container and blood treatment device to be used in a method according to the present invention.

Systems and methods to non-invasively measure sub-cutaneous processes in a patient are disclosed. Examples of systems may optically detect biological fluid properties. The optical detection techniques described herein may be incorporated into a wearable monitoring system. Examples of wearable monitoring systems may simultaneously measure a plurality of sensory modalities. Systems of the present disclosure may be mounted on the skin of a patient.

A monitoring device implements a monitoring method that comprises: activating a first monitoring technique that operates to detect the disruption and generate a corresponding alarm signal while a second monitoring technique is deactivated, obtaining at least one of a first count of false alarms generated by the primary monitoring technique and a second count of false alarms generated by the second monitoring technique if activated, and selectively, based on at least one of the first and second counts, activating the second monitoring technique to operate, instead of or jointly with the first monitoring technique, to detect the disruption and generate the corresponding alarm signal. The monitoring device may be connected to or part of an apparatus for blood treatment and operable to detect a disconnection of an extracorporeal blood circuit from a vascular system of a patient, e.g. a venous-side disconnection.