A system includes a urination data storage unit, an absorbent article information storage unit, a changeable time storage unit, and a changing schedule proposal unit. The changing schedule proposal unit includes a changing schedule computation unit and a changing schedule outputting unit. The changing schedule computation unit finds, on the basis of urination amount data and urination time instant data stored in the urination data storage unit, a total urination amount within a predetermined time period selected from changeable time instants stored in the changeable time storage unit, and performs, by comparing the total urination amount that has been found and the urine absorption capacity of an absorbent article, computation for finding the absorbent article or the predetermined time period such that the urine absorption capacity does not fall below the total urination amount.

A fluid container measurement system is disclosed. The fluid container measurement system is configured to suspend a load measurement assembly a distance above a support surface. The load measurement assembly houses a load cell and a measurement control circuit. The measurement control circuit is coupled to the load cell and configured to receive electrical signals indicative of a force imposed on the load cell. Electrical signals generated by the load cell indicative of the force exerted on the load cell can be used to measure the fluid container attached to the load cell linkage member.

The present invention relates to the diagnosis and treatment of urinary incontinence. Th diagnosis and treatment involves the use of a multiple sensor-enabled catheter capable of providing real-time data regarding the patient's physiology, such as urinary flow and muscular function of the bladder sphincter, as well as the position and movement of the catheter within the patient.

The present invention includes devices, systems and methods in the field of uroflowmetry, more specifically in the field of home uroflowmetry. In one aspect, the present invention discloses a core unit comprising an accelerometer; a urine detector; a weight sensor; a communication module; a microprocessor; and, an energy source. Further provided is a uroflowmetry device comprising said core unit.

A method to protect kidneys of a patient undergoing cardiac surgery patient including: administrating a diuretic to the patient to increase urine output of the patient during cardiac surgery, wherein the diuretic is administered during the cardiac surgery; anesthetizing the patient with a general anesthetic during the cardiac surgery; infusing an intravenous liquid into the patient during the cardiac surgery; monitoring a rate or amount of urine output of the patient during the cardiac surgery, and automatically adjusting a rate or amount of the intravenous liquid infused into the patient to achieve or exceed a target urine output during the cardiac surgery.

There is provided a urine analysis device for bed side monitoring of a patient, comprising: an inlet sized and shaped for fluid communication with a urine collecting tube that receives urine from a patient; a drip chamber through which the urine flows towards an outlet; at least one sensor that analyzes each drop of urine and estimates a respective volume of each drop; a timing element that measures a reference time for each drop; a program store storing code; and at least one processing unit coupled to the program store for implementing the stored code, the code comprising: code to calculate a urine output flow rate of the urine output flowing through the chamber according to the estimated volume of each drop of the urine and the reference time for each drop; and code to output the urine output flow rate.

Systems, devices and methods for draining and analyzing bodily fluids and assessing health are described and generally comprise a drainage tube in fluid communication with at least one opening near or at a distal end of a catheter, a pump in fluid communication with the drainage tube and configured to apply a negative pressure to the drainage tube, and a valve configured for unidirectional flow and in fluid communication with the drainage tube. A controller is configured to actuate the pump to apply the negative pressure for clearing an airlock and to monitor a urine output from the patient over a first predetermined period of time above a urine output threshold and over a second predetermined period of time below the urine output threshold. The controller may determine a risk of acute kidney injury if the urine output below the urine output threshold exceeds the second predetermined period of time.

A miniaturized monitoring device can include electronic circuitry, housing, and communications protocols. The device can be a robust sensing device that can quantify electrolyte content accurately and transmit continuously from within fecal effluent or urine, or other human bodily fluid and/or solid samples. The device can be fully immersed in the testing sample, which can be in a container, an ostomy bag, or otherwise.

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 total patient management system according to an example embodiment includes a smart diaper configured to mount with a temperature sensor, a humidity sensor, a gas sensor, a capacitance sensor, a gyro sensor, a magnetic field sensor, and an acceleration sensor; a transmission device configured to transmit a sensor signal generated in the smart diaper; and a central processing device configured to analyze change information of the smart diaper and a defecation pattern of a wearer using the sensor signal received from the transmission device and to monitor posture information and abnormality of a patient.