A neonatal incubator system includes a platform configured to support a neonate and an enclosure supported above the platform and configured to create a chamber around the neonate. The enclosure includes a movable side panel on a side of the enclosure openable to place the neonate on the platform enclosable to secure the neonate within the chamber. The enclosure also includes a latch engageable when the movable side panel is in a closed position and configured to maintain the movable side panel in the closed position, and also includes a biasing device configured to force the movable side panel away from the closed position when the latch is not engaged.

An incubator includes an incubator main body, a baby accommodation chamber disposed in the incubator main body and capable of being shielded from external air, and a humidifier disposed in the incubator main body so as to generate steam for supplying humidified air into the baby accommodation chamber. The humidifier has a connection portion to which a water supply hose is connectable so as to supply water for generating the steam from a water supply container located outside the incubator main body. In addition, the humidifier includes a humidifying tank which stores the water for generating the steam, a water supply port portion which supplies the water into the humidifying tank in communication with the connection portion, and a float valve which opens and closes the water supply port portion by moving upward and downward in response to a water level of the water stored inside the humidifying tank.

A system configured to support growth and development of a premature fetus is disclosed. Specifically, a method and apparatus configured to provide extracorporeal support for premature fetuses is disclosed.

A neonate incubator for positioning a neonate within a magnetic resonance imaging (MRI) device is provided. The neonate incubator can include: a proximal end and a distal end; a radio frequency (RF) shielding door coupled to the distal end, the RF shielding door to mate with a bore of the MRI device to provide RF shielding; and a RF channel that extends along an axis that is substantially parallel to a longitudinal axis of the neonate incubator from an interior chamber of the neonate incubator through the RF shielding door, the RF channel having a length to width ratio of at least 5 to 1.

A method and apparatus includes an infant holding area, a display area, a heating system for warming the infant holding area, an environmental sensor, a physiological sensor, and a processor. The processor is configured to receive an environmental sensor input from the environmental sensor and a physiological sensor input from the physiological sensor. The processor is configured to determine a recommended skin temperature based on the environmental sensor input and the physiological sensor input. The processor is configured to display the recommended skin temperature on the display area.

A system for safely containing an infant on a mattress is described. The system includes a plurality of panels that extend upwardly from a base that supports the mattress, wherein the plurality of panels and the base form an enclosure around the mattress, and wherein at least one of the plurality of panels is configured to have a locked position and an unlocked position. The system also includes a detection system that detects when the at least one of the plurality of panels is in the unlocked position and a lighting system operatively coupled to the detection system, wherein the lighting system is configured to emit light when the at least one of the plurality of panels is detected to be in the unlocked position. Furthermore, the system includes a power system that provides energy to the lighting system for emitting the light.

A system configured to support growth and development of a premature fetus is disclosed. Specifically, a method and apparatus configured to provide extracorporeal support for premature fetuses is disclosed.

A neonatal incubator system includes a platform configured to support a neonate and an enclosure supported above the platform and configured to create a chamber around the neonate. The enclosure includes a movable side panel on a side of the enclosure openable to place the neonate on the platform enclosable to secure the neonate within the chamber. The enclosure also includes a latch engageable when the movable side panel is in a closed position and configured to maintain the movable side panel in the closed position, and also includes a biasing device configured to force the movable side panel away from the closed position when the latch is not engaged.

A collapsible containment apparatus (36) with a first hub (21), a second hub (22), a plurality of articulated arms (23, 25) coupled to the first hub (21), a plurality of support arms (24) coupled to both the second hub (22) and the articulated arms (23), and a flexible canopy (73) carried by the articulated arms (23). The apparatus (36) is collapsed by relative movement of the two hubs (21, 22) away from one another, and deployed by relative movement of the hubs (21, 22) toward one another. When the apparatus (36) is deployed the canopy (73) creates a closed interior environment, which may be sterile.

A patient bed assembly unit as well as to a thermotherapy device for newborns includes a bed frame and a drawer. The bed frame has a drawer guide configured to make possible a drawer movement from a central pushed-in position in the bed frame along a first pull-out direction and in a second pull-out direction, which direction is opposite the first pull-out direction, into a pulled-out position of the drawer. A drawer-centering device acts on the drawer to move it into the central pushed-in position. The drawer can be removed from the guide. A drawer anti-tilt device is provided, which transmits a torque acting on the drawer directly to a bed frame and prevents the downward tilting of the drawer relative to the bed frame about an axis extending at right angles to the pull-out directions.