In one embodiment, a monitoring system includes a monitoring device configured to removably attach to a tracheotomy tube, the monitoring device including a skin sensor configured to detect contact with skin of a patient's neck.

A method for monitoring a flowrate of cerebrospinal fluid (CSF) in a ventriculo-peritoneal (VP) shunt implanted in a human patient includes: (i) receiving, at a device external to the human patient, data sensed by a plurality of sensors within the device and positioned relative to the VP shunt to drain excess cerebrospinal fluid from the human patient's brain; (2) determining, by the device and based on the sensed data, a rate of flow of the CSF in the VP shunt; and (3) transmitting (e.g., wirelessly), by the device, data indicating the rate of flow to a computing server.

Disclosed herein are methods, systems, and devices for controlling a gas mixture within a mechanical ventilator. According to one embodiment, a computer implemented method includes receiving first peripheral arterial oxygen saturation (SpO.sub.2) data from a pulse oximeter via a pulse oximeter interface, wherein the pulse oximeter is configured to monitor a patient receiving invasive ventilation; determining a first mode of operation for a ventilator mechanism, wherein the ventilator mechanism is configured to provide at least a portion of the invasive ventilation; determining first partial pressure of oxygen (PaO.sub.2) data stored in a first lookup table using the first SpO.sub.2 data, wherein the first lookup table is derived from a sigmoid shaped oxyhemoglobin dissociation curve; determining first fraction of inspired oxygen in air (FiO.sub.2) data for setting a mixture in a gas blender in the ventilator mechanism based on the first PaO.sub.2 data and a variable offset; and providing the FiO.sub.2 data to the ventilator mechanism.

A cartridge acting as a dispenser for liquid treatments of a human or animal body is U shaped or hoop shape. The cartridge has a container containing a liquid treatment which when required to be dispensed is ejected through one or more nozzles projecting through the wall of the cartridge into the centre of the U or of the hoop. A base is provided for cartridges, the base controlling timing and quantity of treatments.

Temperature-controlled mattress control system and method based on sleep posture detection are provided. The control system includes an information collecting unit, an information processor and an output instruction unit. The information collecting unit is used to collect a temperature parameter of a human body during sleeping, video information, and a temperature parameter of a temperature-controlled mattress. The information processing unit receives information collected by the information collecting unit, calculates a sleep posture value K, a thermal sensation value P and a facial skin thermal value Q to obtain a final estimated thermal sensation, and determines setting temperature variation of the temperature-controlled mattress based on the temperature parameter of the temperature-controlled mattress. The output instruction unit receives the setting temperature variation and the temperature parameter of the temperature-controlled mattress, and issues an instruction to a water chiller-heater unit to enable the water chiller-heater unit to carry out fluid temperature regulation.

Disclosed herein is a system for performing urinalysis of transurethral patients. The system includes a tubing set to receive urine from a urethral catheter. A detector assembly is operatively coupled between the tubing set and a urinalysis module coupled. The system can perform urinalysis of a urine sample disposed within the tubing set and render urinalysis information on a display of the module. Also disclosed is a method of performing urinalysis that can include operations of: (i) placing a urine sample within a cuvette of a urinalysis system, the cuvette including a lumen extending between an inlet and an outlet; (ii) projecting coherent light into the sample; (iii) collecting output light exiting the sample; (iv)extracting urinalysis data from the collected light; and (v) rendering urinalysis results on a display of the system.

Cerebrospinal fluid (CSF) drainage systems. A system includes a conduit having a proximal end and a distal end. The conduit receives the CSF from a patient from the proximal end. The system includes a collection chamber coupled to the distal end. The collection chamber collects the CSF. The system includes a valve positioned on the conduit. The valve controls CSF flow into the collection chamber. The system includes a camera that captures an image of the CSF within the collection chamber. The system includes a processor coupled to the camera. The processor measures a flow rate of the CSF based on the image and controls the first valve to open for a first predetermined period and close for a second predetermined period until a determination of a predetermined amount of the CSF being drained from the patient is made by the processor based on the flow rate.

Provided is a detector assembly for determining a ratio of lactate to pyruvate from dialysis, said detector assembly comprising: a first pump, a dialysis probe, a first tube fluidically coupling the first pump to an inlet of the dialysis probe, an infrared (IR) detector, a second tube fluidically coupling an outlet of the dialysis probe to the IR detector, and a controller. The first pump pumps a perfusate at a first flow rate to the dialysis probe, via the first tube, and to, in turn, pump a dialysate at a second flow from the dialysis probe to the IR detector, via the second tube. The IR detector detects respective absorbances due to lactate and pyruvate in the dialysate, and the controller determines the ratio of lactate to pyruvate in the dialysate.

A stopper is disclosed herein. The stopper is configured to be disposed within a medical cartridge. The stopper includes a shell defining a cavity, a core arranged within the cavity, and at least one electronic device embedded within the core, wherein the at least one electronic device includes a sensor and wherein the shell is configured to pass a sensing signal therethrough.

A portable hemodialysis system is provided including a dialyzer, a closed loop blood flow path which transports blood from a patient through the dialyzer and back to the patient, and a closed loop dialysate flow path which transports dialysate through the dialyzer. Preferably, the hemodialysis system comprises a sorbent filter in the dialysate flow path. Furthermore, the hemodialysis system comprises a dialysate quality sensor disposed directly in the dialysate flow path. The dialysate quality sensor is configured to change color based on a pH level, ammonia level, or ammonium level of the dialysate.