This present invention relates to a customizable intelligent footwear. More specifically, the intelligent footwear identifies the needs and requirements of the users and accordingly can self-adjust its various features such as ankle support, arch support, quarter support, and others to enhance comfort and performance of the footwear. The intelligent footwear is integrated with a plurality of sensors and chipsets that collects information regarding user's needs, and based on the collected information adjusts different parameters of the footwear. Additionally, the footwear can be easily paired with a compatible software application to allow the wearers to access information related to their footwear features, step counts, sports related content, walking habits, and other relevant information.

An electronic device and a method for controlling the same are provided. The electronic device includes a communicator including circuitry, a first sensor configured to detect movement information of the electronic device, a memory including a first determination module configured to determine whether a user carries the electronic device and a second determination module configured to determine a detecting method for detecting a user location, and a processor configured to identify whether a user of the electronic device carries the electronic device based on the movement information of the electronic device obtained by the first sensor by using the first determination module, and determine a detecting method for detecting location information of the user according to whether the user carries the electronic device by using the second determination module.

Systems, devices and methods for monitoring analyte levels using a self-powered analyte sensor and associated sensor electronics are provided.

A monitor device for an ostomy system and a method of monitoring an ostomy appliance is disclosed, the monitor device comprising a processor; memory; and a first interface connected to the processor and the memory, the first interface comprising a plurality of terminals including a ground terminal and a first terminal for collecting ostomy data from an ostomy appliance of the ostomy system via the first interface. The processor is configured to process the ostomy data according to a processing scheme, the processor comprising an ostomy processing controller configured to control the processing scheme, wherein to control the processing scheme comprises applying a first processing scheme or a second processing scheme different from the first processing scheme.

A charger for charging a plurality of pressure sensing catheters is provided. The charger has a plurality of charging ports of which a first charging port and a second charging port receives a first connector and a second connector respectively. The first and second connectors each have a first and second radiofrequency identification tags respectively, having information indicative of identifiable information of a first and second pressure sensing catheters respectively. The charger has a plurality of antennas, of which a first antenna and a second antenna can be positioned proximate to the first charging port, and second charging port respectively. When the first connector is inserted into the first charging port, the first radiofrequency identification tag is guided to a predetermined orientation with respect to the first antenna to minimize a spacing therebetween, and to maximize absorption of radiofrequency energy therebetween.

A physiological sensing system is provided. The physiological sensing system includes a wearable device and an electronic device. The wearable device senses a body temperature signal of a user, an audio signal of a respiratory tract of the user, a capacitance sensing signal of the respiratory tract and an activity status of the user to generate a sampled body temperature signal, a sampled audio signal, a sampled sensing capacitance value and a sampled activity status. The electronic device determines a physiological status of the user in response to variations in the sampled body temperature signal, the sampled audio signal, the sampled sensing capacitance value and the sampled activity status.

A system for monitoring a vascular access is provided. The system includes a wearable vascular access monitor which can be a sleeve or other protective covering fitted with two or more sensors for obtaining physiological measurements at different locations from the vascular access. The sleeve or other protective covering is also fitted with an ultra-low power processor for relaying the physiological measurements to a patient's mobile phone. The patient's phone can evaluate the physiological measurements to determine a state of the vascular access, and if the physiological measurements fall out of nominal ranges, the patient's phone can alert a clinic, nurse, or physician. The system can be used to monitor fistulas or grafts used for hemodialysis or peritoneal dialysis.

A patient support apparatus includes a frame and a mattress supported by the frame and arranged to support a patient thereon. A sensor is included to detect moisture on the patient and/or the patient support apparatus. The sensor produces signals indicative of the presence of moisture on the patient support apparatus. One or more alerts are output in response to the signals provided by the sensor to notify a caregiver of the presence of moisture on the patient support apparatus.

A patient communication system having a medical sensing device operable to collect medical data, a network communication module operable to transmit the medical data onto a data network, a controller operable route the first medical sensing data to the network communication module, and a power source operable to provide power to the first medical sensing device, the controller, and the network communication module.

Systems and methods for analyte monitoring, particularly systems and methods for monitoring and managing life of a battery in an analyte sensor system worn by a user, are provided.