This present disclosure relates to fluid therapy based on adjusted urine output rate and/or sodium output rate, and associated systems, devices, and methods. Exemplary methods can include receiving a sodium excretion input for the patient; receiving a urine output rate; determining an adjusted urine output rate based on the sodium excretion input and the urine output rate; and providing fluid therapy based on the adjusted urine output rate. By determining the amount and/or rate of the infused diuretic and/or hydration fluid based on a patient's actual sodium excretion levels, embodiments of the present technology can optimize and/or customize all or a subset of a diuretic therapy to an individual patient's physiology.

This present disclosure relates to fluid therapy based on sodium excretion, and associated systems, devices, and methods. Exemplary methods can include receiving a sodium excretion input for the patient; receiving a urine output rate; determining an adjusted urine output rate based on the sodium excretion input and the urine output rate; and providing fluid therapy based on the adjusted urine output rate. By determining the amount and/or rate of the infused diuretic and/or hydration fluid based on a patient's actual sodium excretion levels, embodiments of the present technology can optimize and/or customize all or a subset of a diuretic therapy to an individual patient's physiology.

Disclosed is an automated weight based fluid output monitoring system that can include a hanger having a securement ball defining a spherical surface and configured to engage a socket. The securement ball can include a sensor array configured to detect a change in pressure between the securement ball and the socket as well as a direction of force relative to a transverse axis of the socket. The hanger can further include a hook configured to be coupled to a fluid collection bag of a fluid drainage system. The hanger can further include a console having one or more processors, non-transitory storage medium, an energy source and a one or more logic modules configured to determine a change in fluid volume of the collection bag over time and an off-axis loading of the fluid collecting bag relative to the transverse axis.

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.

A medical device for monitoring physical, chemical, or biological characteristics of an organ, such as the urinary bladder. The medical device may include an elongate member having a proximal end and a distal end. The device may further include an end-effector assembly extending distally from the distal end of the elongate member. The end-effector assembly may also include a plurality of sensing elements for detecting abnormal organ function. Each of the plurality of sensing elements may include one or more of mechanical, visual, chemical, and biological sensors.

A fluid measurement device includes a container configured to contain a volume of fluid. The container defines an inlet and an outlet. A plurality of sensors are operatively coupled to the container. The plurality of sensors are configured to detect a fluid level within the container. A processing device is operatively coupled to the plurality of sensors. The processing device is configured to process data transmitted by the plurality of sensors to determine at least one rate-based property relating to the fluid.

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.

Provided are devices and methods suitable for immobilizing tissue and for use in non-invasive methods of assessing lower urinary tract symptoms as well as in surgical application.

A fluid analysis device including a fluid receipt chamber, a first capacitive element for measuring fluid flow into the fluid receipt chamber and a controller operatively coupled to the first capacitive element, wherein the controller is configured to measure a first capacitance of the first capacitive element.

A urine flow data processing method includes the following steps of: obtaining the urine volume data measured by a uroflowmeter, wherein the urine volume data comprises a first weight at a first time and a second weight at a second time; determining whether the difference between the first weight and the second weight is larger than a presetting threshold value; generating an updated second weight corresponding to the second time according to the first weight, the second weight, and a third weight at a third time when the difference between the first weight and the second weight is larger than the presetting threshold value, and replacing the second weight with the updated second weight to generate an updated urine volume data; and analyzing the updated urine volume data to generate a urine flow chart.