A toilet comprising a frame; a bowl supported by the frame; a seat also supported by the frame; a shroud covering the frame; a lift mechanism supported by the frame for adjusting the position of the seat; a foot platform positioned to support the feet of a user sitting on the seat wherein the foot platform comprises at least one foot platform weight sensor; at least one seat weight sensor between the frame and the seat for measuring the weight of a user on the seat; and a controller receiving data from the at least one foot platform weight sensor and from the at least one seat weight sensor, wherein the controller uses the data from the foot platform weight sensor and from the frame weight sensor to control the at least one lift mechanism is disclosed.

The present invention provides an elongated active thermo-regulated neonatal transportable incubator (ANTI), having a main longitudinal axis with a proximal end and an opposite distal end comprising adjacent to at least one of the ends a temperature regulating vent (TRV). The TRV is configured to stream air from one end towards the opposite end substantially along the axis, and the ANTI is configured, by means of size and shape, to accommodate the neonate in parallel to the axis. Further the ANTI can be configured by means of size shape and material to at least partially inserted into an MRD having an open bore in its longitudinal axis, further accommodating the neonate parallel to the MRD bore. An incubator with a temperature regulating vent located outside the incubator and its base.

A patient support apparatus includes a frame, a support surface, and a sensor. The frame cooperates with the support surface to support a patient. The sensor is coupled to one of the frame and the support surface and is configured to provide an input signal indicative of a characteristic associated with the patient.

A patient support apparatus for patients. The patient support apparatus comprises a base and a litter supported by the base. The patient support apparatus also comprises powered devices that perform one or more predetermined functions on the patient support apparatus. A user interface is employed to control the powered devices. The user interface is designed to enable caregivers to cause operation of the powered devices with fewer buttons, while retaining functionality in using powered devices.

A control device for a power assist wheelchair which includes a compensation turning torque calculation unit that calculates a compensation turning torque value for compensating for at least a part of the shortage or excess of the actual turning torque value with respect to the predicted turning torque value, in which the compensation turning torque value is smaller when the vehicle speed is a first speed than when the vehicle speed is a second speed faster than the first speed; a first target current determination unit that determines a target current of the first electric motor based upon the first manual torque value and the compensation turning torque value; and a second target current determination unit that determines a target current of the second electric motor based upon the second manual torque value and the compensation turning torque value.

A patient support apparatus includes a controller having a processor and a memory. The memory may have instructions stored therein related to an exercise regimen for a patient. A graphical user interface may be provided. The controller may be configured to display an alert on the graphical user interface when the patient requires exercise. User inputs may be displayed on the graphical user interface to enable a caregiver to record exercises completed by the patient.

Introduced here are pressure-mitigation apparatuses able to mitigate the pressure applied to a human body by the surface of an object. A controller device can be fluidically coupled to a pressure-mitigation device that includes a series of selectively inflatable chambers. When a pressure-mitigation device is placed between a human body and a surface, the controller device can continuously, intelligently, and autonomously circulate air through the chambers of the pressure-mitigation device. As further discussed below, the controller device may cause the chambers to be selectively inflated, deflated, or any combination thereof. Such an approach is useful in a variety of contexts. For example, pressure-mitigation apparatuses may be used to improve treatment of patients suffering from respiratory illnesses and patients who are partially or completely immobilized for extended durations (e.g., as part of a medical procedure).

Introduced here are pressure-mitigation apparatuses able to mitigate the pressure applied to a human body by the surface of an object. A controller device can be fluidically coupled to a pressure-mitigation device that includes a series of selectively inflatable chambers. When a pressure-mitigation device is placed between a human body and a surface, the controller device can continuously, intelligently, and autonomously circulate air through the chambers of the pressure-mitigation device. As further discussed below, the controller device may cause the chambers to be selectively inflated, deflated, or any combination thereof. Such an approach is useful in a variety of contexts. For example, pressure-mitigation apparatuses may be used to improve treatment of patients suffering from respiratory illnesses and patients who are partially or completely immobilized for extended durations (e.g., as part of a medical procedure).

Systems and methods for providing data continuity for a mobile medical cart are provided. A battery board comprising a voltage detection circuit (“VCD”), a microcontroller, and a switching device electrically interposed between an alternative power source, a removable battery, and system boards for controlling cart functions. The microcontroller commands the switching device to: begin sourcing power solely from the alternative power source upon detection of a voltage decrease, begin sourcing power solely from the removable battery upon detection of a voltage increase where a valid charge state exists, and continue sourcing power solely from the alternative power source upon detection of the voltage increase where no valid charge state exists.

A neonatal care system includes a platform for supporting an infant, at least one load cell configured to sense a weight of the infant supported on the platform, and an inclinometer configured to measure an angle of the platform. A controller is configured to determine an infant weight based on the sensed weight and the measured angle of the platform.