A retrofittable commode attachment device that automatically measures and charts electronically one or more types of health data. The device includes a base platform with a back portion, a left side portion, a right side portion and a front portion, a plurality of load cells on the left side of the base platform and a plurality of load cells on the right side of the base platform, at least one microphone, at least one camera, and at least two commode connector brackets that engage the horizontal support of a commode and the base platform is positioned below the toilet seat of the commode and is not part of the toilet seat.

A retrofittable commode attachment device that automatically measures and charts electronically one or more types of health data. The device includes a base platform with a back portion, a left side portion, a right side portion and a front portion, a plurality of load cells on the left side of the base platform and a plurality of load cells on the right side of the base platform, at least one microphone, at least one camera, and at least two commode connector brackets that engage the horizontal support of a commode and the base platform is positioned below the toilet seat of the commode and is not part of the toilet seat.

Examples relate to devices, systems, and methods for fluid collection such as urine. The fluid collection device a urine collection device, a first conduit, a urine collection bag having an interior region, a second conduit, and a modular pump. The urine collection device is configured to be positioned proximate to a urethra of a user. The first conduit is in fluid communication with the fluid collection device. The second conduit is in fluid communication with the interior region of the urine collection bag. The modular pump is configured to pull a vacuum and draw urine from the urine collection device through the first conduit and force the urine through the second conduit into the urine collection bag.

A system for evaluating a kidney includes a processing device including an input module configured to acquire patient information, the patient information including at least one of demographic data, diagnostic data, physiological data and intervention data. The processing device also includes an evaluation module, which is configured to input patient class data to an initial kidney model, the initial kidney model configured to simulate a physiological response of a kidney and configured to simulate fluid and solute transport through one or more spatial locations of the kidney. The evaluation module is also configured to input patient data corresponding to an individual patient and calculating a model response, and adjust at least one parameter of the initial kidney model based on a comparison of the patient data and the model response to personalize the initial kidney model for the individual patient.

The test lab set-up includes a test flow bench for mounting one or more test devices, an adjustable nozzle for simulating urine flow, and a sensor for collecting data associated with the simulated urine flowing through the test device(s). A computing device for measuring and/or calculating various parameters associated with the simulated urine flow may also be included. The test device may have a shape corresponding to a handheld uroflowmeter subject to testing. The angle of the adjustable nozzle may be adjusted to test for various angles of urine flow. Similarly, the angle, pitch, and roll of the test device may be adjusted to test for various angles at which a uroflowmeter is held. As fluid flows through the test device, the sensor collects information such as, for example, flow rate, duration, volume, and the like. The sensor transmits the data collected to a computing device for additional processing.

The invention relates to a toilet device for the measurement of micturition parameters, the toilet device comprising a housing that has a housing opening for receiving urine and a capacitive sensor for the time-dependent, contactless measurement of micturition parameters. The invention also relates to a method for the contactless measurement of micturition parameters in a toilet device, said method being carried out more particularly using the toilet device according to the invention.

In some examples, a system is configured to determine a non-cerebral autoregulation status value of a patient using machine learning. In some examples, processing circuitry of the system is configured to determine, using a neural network algorithm that has been trained via machine learning training, an individualized adjustment value that is individualized for the patient, including inputting physiological data associated with the patient. The processing circuitry may determine a non-cerebral autoregulation status of the patient based on a cerebral autoregulation value of the patient based on the non-cerebral autoregulation status value of the patient and the adjustment value.

In one embodiment, a device for in vivo tissue evaluation includes an elongated manipulator including an elongated proximal tube and an articulable distal portion, and a sensor provided at a distal end of the articulable distal portion, the sensor including a sensor head configured to be pressed against tissue and measure a reaction force of the tissue.

In one embodiment, a device for in vivo tissue evaluation includes an elongated manipulator including an elongated proximal tube and an articulable distal portion, and a sensor provided at a distal end of the articulable distal portion, the sensor including a sensor head configured to be pressed against tissue and measure a reaction force of the tissue.

Offset illumination using multiple emitters in a fluorescence imaging system is described. A system includes an emitter for emitting pulses of electromagnetic radiation and an image sensor comprising a pixel array for sensing reflected electromagnetic radiation. The emitter comprises a first emitter and a second emitter for emitting different wavelengths of electromagnetic radiation. The system is such that at least a portion of the pulses of electromagnetic radiation emitted by the emitter comprises one or more of a hyperspectral emission, a fluorescence emission, and/or a laser mapping pattern.