We disclose an in-toilet urinalysis system which includes a system for collection urine and applying the urine to a urine test strip. The system may include an orifice within a toilet bowl which leads into a channel. The channel may be connected to a capillary which has an orifice at each end. Urine may pass through the orifice, into the channel, then may be moved by capillary action through the capillary. A urine test strip dispenser may move reaction pads on a urine test strip to the distal end of the capillary to load the reaction pads with urine. The reaction pads may absorb the urine from the most distal orifice of the capillary. A measurable chemical reaction may occur in the reaction pads in response to urine analytes.

An incontinence detection system monitors an area for moisture events and wirelessly transmits moisture-related information to one or more notification devices. The system has a pad that includes a substrate and one or more sensors supported by the substrate. The sensor(s) emit wireless signals indicative of the moisture-related information. A sensor event communication system forwards the sensor signals to another device, such as a notification device. Portions of the system are included in a patient support apparatus, such as a bed.

Sensor devices and systems for monitoring the basic needs of an infant comprising feeding, sleeping, and/or voiding (urinating and/or defecating) are described herein.

Provided herein are methods, devices and compositions for assessing neuromodulation efficacy based on changes in the level of one or more biomarkers in plasma or urine collected from a human subject following a renal neuromodulation procedure.

Example embodiments relate to a sterile urine collection mechanism for medical diagnostic systems. An example device includes an initial collection component configured to collect a midstream urine sample from a patient. The device also includes a plurality of test strips configured to indicate a condition of the patient at a point of care. In addition, the device includes a sensor configured to capture an image of at least one test strip exposed to a portion of the midstream urine sample. Further, the device includes a computing device configured to analyze the image of the test strip captured by the sensor in order to determine the condition of the patient. Even further, the device includes a motor configured to position the test strip near the sensor. Yet further, the device includes an additional collection component configured to collect an additional portion of the midstream urine sample for central laboratory testing.

A device can be coupled to a foley catheter inserted into the bladder of a patient, where the foley catheter includes a urine passage through which urine can be drained from the bladder. The device includes a pressure sensor that is connected to a urine outlet of the urine passage and configured to measure a pressure value of the urine being drained through the urine outlet, a processor connected to the pressure sensor and configured to determine whether the foley catheter can be removed by comparing the pressure value and a predetermined threshold value, and a display unit connected to the processor and displaying whether the foley catheter can be removed according to the control of the processor.

This specification discloses devices and apparatus for collecting a material specimen, including a sheath; and an inner assembly. The inner assembly can include a handling element; one or more fluid chamber elements; and a swab element. The handling element, the one or more fluid chamber elements, and the swab element are connected and arranged along a first axis; and the inner assembly is operable to slide within the sheath between (i) a first position in which the swab element is in a non-retracted position outside of the sheath while at least a portion of the inner assembly remains within the sheath, and (ii) a second position in which the swab element is in a retracted position within the sheath.

An automated therapy system having an infusion catheter; a sensor adapted to sense a patient parameter; and a controller communicating with the sensor and programmed to control flow output from the infusion catheter into a patient based on the patient parameter without removing fluid from the patient. The invention also includes a method of controlling infusion of a fluid to a patient. The method includes the following steps: monitoring a patient parameter with a sensor to generate a sensor signal; providing the sensor signal to a controller; and adjusting fluid flow to the patient based on the sensor signal without removing fluid from the patient.

A patient support apparatus includes a frame and a mattress supported by the frame and arranged to support a patient thereon. A sensor is included to detect moisture on the patient and/or the patient support apparatus. The sensor produces signals indicative of the presence of moisture on the patient support apparatus. One or more alerts are output in response to the signals provided by the sensor to notify a caregiver of the presence of moisture on the patient support apparatus.

A substrate suitable for incorporation into an absorbent article for automatic detection of wetness events therein, the substrate comprising a first surface capable of being arranged proximal to a body facing side of the absorbent article and a second surface opposite said first surface and capable of being arranged proximal to a garment facing side of said absorbent article, said substrate comprising a plurality of sensor tracks disposed on said first surface and said sensor tracks comprising: at least one central track extending parallel to a length of the substrate and parallel to a longitudinal axis crossing a first end and a second end of the substrate; at least two side tracks extending parallel to the central track and oppositely arranged such that the central track extends therebetween; and wetness sensing tracks extending outboard of said two side tracks, wherein said central track, said side tracks, and said wetness sensing tracks are in electrical communication via one or more shortening elements positioned proximal to said second end and distal from said first end, and wherein the substrate is connectable to a clip-on data processing module at a position proximal to said first end and distal from said shortening elements such to form a closed electrical circuit, typically for measuring resistance and/or capacitance therethrough. In an embodiment said substrate consists of a liquid impermeable backsheet, preferably a breathable liquid impermeable backsheet.