Disclosed herein is urinary output monitoring system including a urinary collection device having a flow meter in communication with a monitor. The urinary collection device catheter includes a urine collection bag, a drainage tube and a urinary catheter. A console of the flow meter wirelessly communicates with a console of the monitor. The monitor depicts urine flow rate information on a display and wirelessly transmits urine flow rate information to an EMR system. The flow meter includes a flow meter identifier and the system links the urine flow rate information to the flow meter identifier. The monitor further links the flow meter identifier with a patient identification from the EMR system and depicts the patient identification on the display.

A method to treat patients suffering from fluid overload including: administrating a diuretic to the patient to increase urine output of the patient; monitoring intravascular volume of the patient; and maintaining the patient in a condition in which the intravascular volume is below a baseline intravascular volume and above a hemodynamic level by adjusting the administered diuretic.

Wearable uroflowmetry systems having wearable uroflowmeters are disclosed. A disclosed example uroflowmetry system comprises a wearable uroflowmeter including: a funnel portion having an end configured to secure the funnel portion against a person, an outlet opposite the end, and a funnel configured to capture urine excreted by the person when the end is secured against the person, and to direct the captured urine into the outlet; a fluid passage portion having an opening configured to receive the urine from the outlet of the funnel portion, and a fluid channel to pass the received urine along a length of the fluid passage portion; and a measuring portion having a sensor in the fluid channel configured to collect one or more measurements of the urine as the urine passes the sensor, the measurements representative of at least one of a property of the urine, or a flow characteristic of the urine.

The present invention provides a system for measuring instantaneous inflow rate of liquid, comprising: a receptacle, comprising an opening at a top side, a nozzle at a bottom and/or multiple holes on the side section of said receptacle configured to receive the inflow of liquid from said top opening, and simultaneously release said liquid through said nozzles; a sensing device, configured to sense the level of liquid within the receptacle and produce signals indicative of the level of liquid in the receptacle; and a processor, configured to receive said signals, calculate the level of liquid in the receptacle according to said signals; and analyze said calculations, to obtain the instantaneous inflow rate of liquid.

Urine collection systems and associated methods and devices are disclosed herein. A representative system can include a urine collection device, a flow control assembly configured to direct a urine flow from the patient to the urine collection device, and a urine measurement device including a first sensor and a second sensor. The first sensor is configured to generate first sensor data based on a weight of the container, and the second sensor is configured to generate second sensor data based on the urine flow from the patient to the container. The system can further include non-transitory computer readable media having instructions that, when executed by one or more processors, cause the system to perform operations comprising determining a first patient urine output based on the first sensor data; and determining a second patient urine output based on the second sensor data.

An automated urinary output monitoring system includes a urine collection assembly, a scale, and a pump. The urine collection assembly includes a urinary catheter coupled to a first drainage tube. The interim container coupled to the first drainage tube and a second drainage coupled to a final container. The scale measures the weight of urine collected in the final container and a display can depict the volume of urine collected in the final container. A vacuum pump can be coupled with the final container to draw urine from the interim container into the final container, and an air vent can isolate the patient from the vacuum within the final container. The system can be configured to wirelessly transmit urine volume data to an external computing device. A gyroscope can be coupled with the scale to determine the orientation of the scale.

An excretion collection and evaluation system including at least one waste receptacle including a waste collection area. and a sensor configured to be coupled to a toilet, selectively coupled to the at least one waste receptable, and configured to generate a signal indicative of a quantity of waste deposited in the waste collection area.

A method and a device are disclosed including a urine collection device with sensors for determining the volume of the urine collected. A controller determines urine volume based on the height of sensors that show urine proximate to them within the device. A display indicates to the user whether the collected urine is sufficient for the required sample.

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.

A smart fluid discharge monitoring device can have a housing; a frame within the housing; a cartridge positioned within an upper shell of the housing, the cartridge having a window, through which a discharge fluid can flow; a door removably attached to the housing, the door delimiting an interior region of the housing below the upper shell; a tube connected to the cartridge; a plurality of tanks removably secured within the interior region, the tanks receiving the discharge fluid from the cartridge. The smart fluid discharge monitoring device can detect one or more optical characteristics of the discharge fluid through the window as the discharge fluid flows through the cartridge. The smart fluid discharge monitoring device can be a smart catheter or a smart chest tube.