The various embodiments disclosed here relate to systems, methods, and devices for monitoring bladder health. Certain implementations are directed to patients who require daily catheterization. The various embodiments have at least one tube coupled to a catheter, a pressure sensor, a pump, and a processor. Certain embodiments include a digital device with a software application capable of displaying the monitored readings.

Systems, devices and methods for sensing physiologic data and draining and analyzing bodily fluids are described which are capable of sensing physiologic data based on sensors incorporated into a catheter adapted to reside in any of a urinary tract, gastrointestinal tract, rectal location, pre-peritoneal, pleural space or other body cavity. The devices aid emptying of the bladder, measure urine output and various urine parameters such as oxygen tension, urine conductance and urine specific gravity, monitor renal function, analyze urine parameters, including urine content, including the presence of infection, and track and/or control fluid administration.

The urine amount measuring device (100) includes a container-side support portion (10), a sensor (32), a housing (101), a first fixing portion (20), and a second fixing portion (60). The container-side support portion (10) supports the suspension portion (50) on which a urine storage container (C) is hung. The urine storage container (C) stores urine of a person lying on the bed (B). The sensor (32) outputs a signal that changes according to change in force acting on the container-side support portion (10). The housing (101) houses the sensor (32). The first fixing portion (20) fixes a tubular member (T) to the housing (101). The tubular member (T) allows the urine to flow from the person to the urine storage container (C). The second fixing portion (60) fixes the tubular member (T) to the suspension portion (50).

Disclosed is a non-therapeutic use of a sensor for detecting biological fluids in vitro, the sensor comprising a substrate coated with conductive ink, the substrate being inert relative to the conductive ink, the sensor comprising means for measuring conductivity or resistivity of the conductive ink, wherein the conductive ink comprises a carbon substrate and a surfactant. The sensor may also comprise a polymer such as a gum. Also disclosed are methods of detecting biological fluids and uses of the sensor.

Devices and systems compare incoming and outgoing gas and fluid flowrate measurements with each other and with additional physiological measurements of a patient to trigger an alarm to healthcare providers of an issue with a patient. The device can include a sensor that measures incoming flow of gas and fluid and a sensor for measuring the outgoing flow of gas and fluid (for example, urine) from the patient. The sensors can be connected to wireless transmitters to send data describing the flow to a computer processor. The computer processor receives the data from the processors and generates an alarm based on comparisons between the input flow and the output flow. The devices and system can be used to detect issues in a patient by monitoring a flow of intravenous fluids being administered to an amount of urine being generated. The devices and system can be used to detect issues in a patient by comparing a flow of gas being administered to a patient compared to blood gas content in the patient.

According to one aspect of the invention, there is provided a method for calculating information on urination. The method includes the steps of acquiring a sound signal related to urination of a user, calculating a urination parameter related to an effective value (or urination parameters related to an effective value and a spectral centroid) from the acquired sound signal, and estimating a urine flow rate of the user with reference to the calculated urination parameter.

Embodiments of the invention provide devices and systems to monitor fullness of a patient's bladder. One embodiment of a bladder fullness (BF) measure system comprises a sensor device (SD) and a controller. The SD generates an output signal (OS) based on the force exerted by the bladder against SD the wherein the OS corresponds to a degree of BF. The SD may be attached to the bladder wall or adjoining tissue and positioned between the bladder and the pubic bone such that the SD is not affected by tissues force other than that from the bladder. The controller connects to the SD and causes an associated implant to perform a function when the SD output signal exceeds a predetermined threshold. Embodiments are particularly useful for providing information on BF to patients suffering from spinal injury or other conditions whereby they have lost the ability to sense BF and/or voluntarily urinate.

Systems and methods for monitoring and/or controlling a state of a subject during volume resuscitation are disclosed. One method includes acquiring cardiovascular data from a subject, obtaining previous volume administration information, and analyzing the cardiovascular data to determine a past time trajectory for at least one cardiovascular parameter. The method also includes determining a future state of the subject with and without additional volume administration using a statistical model, and determining, based on the future state of the subject, a likelihood that the at least one cardiovascular parameter will exceed or fall below a threshold at one or more pre-determined time points. The method further includes generating a report including a recommendation for administering an additional volume to the subject based on the determined likelihood and controlling administration of an additional fluid volume to the subject based on the report.

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.

A urodynamic investigation apparatus for receipt of urine from a bladder is provided. The apparatus is characterized by a tubular element, first and second fittings, and a sleeve element, for select passage of urine there through, within the tubular element. The tubular element is characterized by opposing first and second end portions, and a port. The fittings are adapted to be received by the opposing end portions of the tubular element so as to delimit an apparatus chamber. The sleeve element, suspended between the fittings within the chamber, has collapsed and open configurations. The collapsed configuration is indicative of a no urine flow condition, and the open configuration indicative of a urine flow condition, with the sleeve element urine flow condition being a function of pressure applied to the chamber via the port of the tubular element.