The present disclosure relates to a dialysis device (1), more particularly a microdialysis device for the sampling of substances from the surface of a body organ. The device is particularly useful in the context of the monitoring of a moving organ, such as a beating heart, as the device comprises attachment means (2) allowing for a flexible and reliable attachment thereto. Furthermore, the microdialysis device provides for an efficient exchange of substances, such as metabolic substances, between the organ and the dialysis fluid through a semi-permeable material forming part of the device. There is also provided a method encompassing the device of the disclosure.

A method and system is provided for determining a discrimination index in a subject that may be suffering from or at risk for a stress-induced psychiatric disorder. The discrimination index may be equal to a ratio of a subject's cued fear response and non-cued fear response measured during a fear-potentiated startle (FPS) paradigm. Such a value may allow a physician or researcher to quantify how well a subject discriminates between signaled (cued) fear and un-signaled (non-cued) fear, which may be a biomarker for psychiatric disorders like post-traumatic stress disorder, panic disorder, phobias, and/or generalized anxiety disorder. The determined discrimination index may provide a standardized way of diagnosing and evaluating mental illnesses, more uniform treatment of patients, and/or more precise monitoring and evaluation of treatment efficacy.

Provided is a detector assembly for determining a ratio of lactate to pyruvate from dialysis, said detector assembly comprising: a first pump, a dialysis probe, a first tube fluidically coupling the first pump to an inlet of the dialysis probe, an infrared (IR) detector, a second tube fluidically coupling an outlet of the dialysis probe to the IR detector, and a controller. The first pump pumps a perfusate at a first flow rate to the dialysis probe, via the first tube, and to, in turn, pump a dialysate at a second flow from the dialysis probe to the IR detector, via the second tube. The IR detector detects respective absorbances due to lactate and pyruvate in the dialysate, and the controller determines the ratio of lactate to pyruvate in the dialysate.

A sampling apparatus can have an elongate tube and a liquid partitioning unit, first port can receive an incoming flow of test liquid and a second port may be coupled to the elongate tube. The liquid partitioning unit can combine the flow of test liquid with a plurality of partitioning elements to define a plurality of discrete liquid samples for movement along and storage in the elongate tube.

A device selected from microelectrode, temperature sensor, optical sensor, optical fibre, temperature control element, and microdialysis probe for insertion into soft tissue comprises a body with a distal terminal section and a layer of an agent such as gelatin capable of forming a gel with aqueous body fluid on the terminal section. The terminal section and the gel-forming layer have a temperature of more than 30° C. below body temperature during a period of time prior and up to insertion. Also disclosed is method of insertion, an insertion assembly and a use of the device.

The present disclosure relates to a molecular exchange device. In particular, the molecular exchange device comprises at least one fluid passageway and an actuator, the actuator positioned to provide a secondary fluid pathway within at least one of the fluid passageways.

Methods and systems include a long-term implantable ultra-filtrate monitoring system that uses micro-porous membranes to produce an ultra-filtrate of tissue interstitial fluid or blood plasma. The ultra-filtrate is transported through a sensor to detect a level of analyte in the ultra-filtrate. The long-term implantable fluid monitoring system thus includes a first porous catheter, a second porous catheter, a sensor configured to measure an amount of analyte in fluid, and a pump configured to move fluid through the first porous catheter to the sensor and from the sensor through the second porous catheter.

A medical monitoring unit for continuously monitoring a glucose value and a lactate value is provided. The monitoring unit comprises: a display unit, a first unit adapted to: receive a glucose/lactate/pyruvate signal based on a measured glucose/lactate/pyruvate value, transform the glucose signal into a graphically displayable glucose/lactate/pyruvate signal, and transmit the graphically displayable glucose/lactate/pyruvate signal to the display unit of the monitoring unit, and a second unit adapted to: receive a glucose/lactate/pyruvate signal based on a measured glucose/lactate/pyruvate value, transform the glucose/lactate/pyruvate signal into a graphically displayable glucose/lactate/pyruvate signal, and transmit the graphically displayable glucose/lactate/pyruvate signal to the display unit of the monitoring unit. Furthermore, a system comprising the monitoring unit, and a sensor unit for sensing glucose and/or lactate and/or pyruvate values, is provided, as well as a method for performing the steps made possible through the provided unit and method.

This document describes devices for in vivo drug testing in the brain. This document also describes implantable devices for long-term drug delivery to the brain parenchyma, and for access to biomarkers from the parenchyma.

A monitoring system for an analyte in a bodily fluid of a patient comprises a housing, a sensor disposed within the housing, and a cannula. The sensor detects and reports the detection of an analyte. The sensor includes a sensor inlet and a sensor outlet. The cannula includes a cannula inlet and a cannula outlet, where the cannula inlet is fluidly coupled to the sensor inlet and the cannula outlet is fluidly coupled to the sensor outlet. The monitoring system can provide real-time monitoring of an intravenous analyte, where a fluid delivery unit can automatically administer a fluid in response to detection of a predetermined amount of the analyte.