Infant care apparatus and system comprising a tray molded in the shape of an infant's body; and fastening devices to fasten the tray around the caregiver's chest, to provide safe kangaroo care to infants. Some embodiments may include sensors to monitor the infant's physiological parameters, and/or a negative pressure ventilator and/or an automated urine and feces collection and disposal system, and/or an external cardiac compression system, and/or electroencephalograph cap, and/or a heat pump to maintain infant body temperature; and/or light emitting diodes to provide phototherapy; and/or an aspirator for suctioning secretions from nose and/or mouth of infant; and/or warm mist generating apparatus to humidify air around the infant. It may include a networking module for transmission of sensor data to and receiving of operating commands from remote servers accessible by medical professionals. The invention thus also provides safe and easy-to-operate intensive care for infants, along with kangaroo care.

A passive neonatal transport incubator (PNTI), useful for thermo-regulating a neonate, comprising an inner volume configured by means of size and shape to accommodate the neonate, the inner volume is defined by an envelope having a main longitudinal axis with a proximal end and an opposite distal end, the envelope is at least partially perforated. Further, the PNTI is configured to be ventilated by an independently ventilated medical device, and is configured by means of size, shape and material to allow the neonate to be examined by the medical device.

An infant incubator heat control device includes a temperature-detecting device providing chamber interior and incubator heater temperature measured values. A first mode of operation has an interior temperature set value, a temperature of the heater set value is calculated as a function of the interior temperature set value and of the chamber interior temperature measured value. A controlled variable is calculated for the heater as a function of the temperature of the heater set value and of the heater measured value. A second mode of operation calculates a temperature of the heater set value independently of the chamber interior temperature measured value. A controlled variable is calculated for the heater as a function of the set value for the temperature of the heater and of the heater temperature measured value.

The present invention relates to a device for carrying out cryotherapy treatments, which corresponds to a closed element, shaped like a tube or container, which mainly includes a treatment chamber into which the patient enters and is closed by an access door, as well as a system for supplying and storing a treatment gas, i.e. nitrogen, which allows to reach very low temperatures that are adequate for the recovery of the patient's muscular system. In this way, the device of the present invention has the advantage that the bottom thereof has a floor in the form of a grid, which allows that the gas used and applied to the patient to pass through same and then to be recovered by a feedback system that recirculates the gas and sends it back to the top of the device for application.

A system includes a patient support unit having an enclosed patient environment, a heating module, a skin temperature sensor module, an environmental sensor module, and a control system. The control system is configured to selectively operate the system in a pre-programmed weaning mode configured to gradually wean the patient from the warmed patient environment series of stepped air temperature decreases performed over a series of stepped time durations achieves a goal air temperature while maintaining a goal skin temperature within a weaning abort deviation.

A thermal transfer device for providing thermal treatment to a patient. A patient support portion supporting and contacting the patient includes a first segment of a fluid flow path to receive a fluid from a fluid source. A flexible covering coupled and movable relative to the patient support portion defines a space therebetween that substantially conforms to the patient. The flexible covering includes a second segment of the fluid flow path. The fluid is circulated through an inlet, an outlet, and fluid flow path for supplying heat to or removing heat from the patient support portion and the flexible covering. A fluid circulation system with a controller may selectively adjust heat transfer from temperature zones defining the patient support portion. The thermal transfer device or a mattress cover may provide for controlling the microclimate, or conditions at or near the interface between the patient and the patient support portion.

A thermal control unit for controlling a patient's temperature includes a fluid outlet for delivering temperature-controlled fluid to a patient, a pump, a heat exchanger, a controller, and a user interface that displays a graph of patient temperature readings over time. The user interface also displays one or more event icons on the graph at locations corresponding to the time at which events associated with the event icons occurred. In some embodiments, the graph is displayed on a touch screen adapted to allow a user set maximum and minimum permissible temperatures for the fluid by touching areas of the graphs and/or by drawing on certain areas of the graph. An image of a human body having different zones may also be displayed on the user interface along with information pertaining to the thermal therapy being applied to the corresponding zones of the patient's body.

In order to maximize spatial utilization and to minimize the volume of a thermotherapy bed so that the thermotherapy bed can be easily stored or moved, the thermotherapy bed includes: a bed body having a thermotherapy device placed therein; side frames connected to both side surfaces of the bed body, respectively; and bed legs configured to support the bed body and connected to the side frames, respectively, wherein the thermotherapy device is placed in a center of the bed body and forms a protrusion on a bottom surface of the bed body, and the bed legs are folded to face an inside of the bed body and are accommodated in spaces formed at both sides of the thermotherapy device.

An infant incubator heat control device includes a temperature-detecting device providing chamber interior and incubator heater temperature measured values. A first mode of operation has an interior temperature set value, a temperature of the heater set value is calculated as a function of the interior temperature set value and of the chamber interior temperature measured value. A controlled variable is calculated for the heater as a function of the temperature of the heater set value and of the heater measured value. A second mode of operation calculates a temperature of the heater set value independently of the chamber interior temperature measured value. A controlled variable is calculated for the heater as a function of the set value for the temperature of the heater and of the heater temperature measured value.

A system is provided with a thermoelectric device with a first heat transfer surface and a second heat transfer surface adapted for cooperation with a therapy device such that the first heat transfer surface is spaced apart from a contact surface of the therapy device to transfer heat to or from the contact surface. A fluid heat transfer system is in fluid communication with the thermoelectric device to transfer heat to or from the thermoelectric device.