A method for diagnosing a body malfunction is provided. At least one change in urinary parameter values, being indicative of the body malfunction, is monitored and detected. A volumetric urinary output of kidneys is monitored using a urine flow monitoring apparatus having a low flow metering device. It is determined whether a change exists in at least one of a volume value of the volumetric urinary output, and a trend of the corresponding urinary parameter value during a predetermined period. Signals are received from a plurality of electrodes, representing the urinary parameter values. The body malfunction is detected based on the determination of the change in at least one of the volume value and the trend.

Catheter monitor integration with patient support systems, such as patient beds, and with other healthcare communication systems including hand hygiene systems is provided. A patient bed that transmits bed data and catheter monitor data is disclosed. When catheter tubing is connected to a catheter monitor integrated into a patient bed, the bed automatically implements a falls prevention protocol. A countdown timer pertaining to removal of catheter tubing from a patient is displayed on one or more display devices. Monitoring for caregiver handwashing compliance in connection with use of a catheter monitor or a catheter kit is also provided.

Parametrical analysis of uroflowmetry test results to identify urological disorders particularly to distinguish men who have low urinary tract disorder/benign prostatic hyperplasia from those who have overactive bladder. Primary urine flow dynamic parameters and secondary urine flow dynamic parameters are calculated. Patient's urological disorders can be assessed by comparing the primary and secondary urine flow dynamic parameters with a library or database of comparable data derived from healthy or normal individuals as well as comparable data derived from individuals afflicted with specific urological disorders. A predictive model of lower urinary tract function disorders can be developed from existing reference primary and secondary urine flow dynamic parameters. The model allows for complex analysis and objective disease prediction.

A urinary bladder irrigation device includes: a first pipe, a second pipe, a third pipe, a liquid supply member, a liquid collection member, a detection member, and an elevation member. The first pipe has a first opening at one end thereof. The second pipe has a second opening at one end thereof. The third pipe has an end connected to another end of the first pipe and another end of the second pipe and has a third opening at another end thereof. The liquid supply member is connected to the first opening. The liquid collection member is connected to the second opening. The detection member is positioned in the second pipe. The elevation member accommodates the detection member.

A vesical pressure measurement system is provided. One or more elements of the system are operably combinable with a previously deployed urinary drainage catheter. The system includes a urodynamic data system and a urinary drainage catheter balloon adaptor. The data system is characterized by a pressure sensor for vesical pressure measurement, and a processor/controller for receiving, processing and/or displaying select urodynamic patient parameters comprising sensed/monitored pressure data. The adaptor operably unites the pressure sensor of the data system to a balloon inflation valve of the catheter. The adaptor includes an adaptor valve for connection to the balloon inflation valve, and a housing, the housing including a balloon inflation valve portion and an adaptor valve portion, the portions urgingly uniteable in furtherance of establishing and maintaining a secure interface between the balloon inflation valve and the adaptor valve.

The present disclosure generally relates to uroflowmeters and methods for processing data generated therefrom. In one aspect, the uroflowmeter is a handheld device. The uroflowmeter includes a handle, a flow chamber coupled to the handle, and a sensor associated with the flow chamber that detects a parameter of urine received in the flow chamber. The uroflowmeter may include both reusable and disposable components. As a uroflowmeter it can identify and record data corresponding to the rate of flow over the measured duration of a void of urine, but may also timestamp the voiding act and communicate the data to an external data collection center for additional analysis and incorporation into a comprehensive voiding report or voiding diary.

A health monitoring system includes a measurement unit that measures fluid information on fluid in reserved water into which urine of a user of a toilet has flowed, an interpretation unit that interprets the urine by analyzing a fluid model obtained by modeling a region in which the fluid flows on the basis of the fluid information, and an inference unit that infers a disease of the user on the basis of urination information of the urine, and the measurement unit includes a cartridge that stores films of which color changes according to components of the reserved water into which the urine has flowed, and extrudes the film to be used for measurement from the cartridge each time the measurement unit measures the fluid information.

A measurement apparatus comprises optical components arranged to provide parallel measurements of a biological sample. The parallel sample measurements provide improved accuracy with lower detection limit thresholds. The parallel measurements may comprise one or more of Raman spectroscopy measurements or infrared spectroscopy measurements. The parallel measurements can be combined with a light source. In many embodiments, the light source comprises one or more wavelengths corresponding to resonance frequencies of one or more molecules of the sample, such as wavelengths of ultraviolet light. The wavelengths of light corresponding to resonance frequencies can provide an increased signal to noise ratio. The parallel array optical configuration can be combined with wavelengths of light corresponding to resonance frequencies in order to provide increased measurement accuracy and detection of metabolites.

A monitoring system which constitutes an oxygen measurement system includes: an oxygen partial pressure calculation unit that calculates an oxygen partial pressure in urine based on an output signal from the oxygen measurement device; a monitor that displays the oxygen partial pressure calculated by the oxygen partial pressure calculation unit; and a display control unit that changes a format of display of the oxygen partial pressure displayed by the monitor according to the flow rate of urine acquired based on the output signal from the oxygen measurement device.

Devices, systems, and methods for delivering fluid therapy to a patient are disclosed herein. An exemplary method can comprise obtaining a urine output rate from a patient; causing a diuretic to be provided to the patient at a dosage rate, and increasing the dosage rate of the diuretic from the initial dosage rate to additional dosage rates higher than the initial dosage rate over a period of time. In some embodiments, the additional dosage rates include a first dosage rate higher than the initial dosage rate, a second dosage rate higher than the first dosage rate, and a third dosage rate higher than the second dosage rate.