A system for contactless monitoring of gas levels within an incubator, the system comprising at least one gas sampling line having a proximal end exposed to the internal space of the incubator, and a distal end associated with a monitoring unit for receiving a gas sample obtained from the incubator via the proximal end.

An infant care station is described herein that can include a heating component of a microenvironment of the infant care station, at least one temperature measuring device, and a processor. The processor can calculate a baseline temperature of the heating component using the at least one temperature measuring device and monitor the heating component using the at least one temperature measuring device to determine one or more operating characteristics. The processor can also detect, based at least in part on the baseline temperature, that the one or more operating characteristics exceed a predetermined threshold and generate a response that results in a correction of the temperature maintained by the heating component.

A system configured to enclose a premature fetus within an extracorporeal environment to promote growth of the fetus and increase viability of the fetus. The system includes a chamber having an interior space configured to enclose the fetus, a first fluid circuit that delivers sterile fluid to the chamber, and a second fluid system that transfers oxygen to the fetus. The system chamber includes a stop mechanism including a clamp and an actuator, the clamp positioned in the interior space, the actuator coupled to the clamp such that movement of the actuator moves the clamp, and the actuator positioned at least partially outside the interior space.

A system configured to enclose a premature fetus within an extracorporeal environment to promote growth of the fetus and increase viability of the fetus. The system includes a chamber having an interior space configured to enclose the fetus, a first fluid circuit that delivers sterile fluid to the chamber, and a second fluid system that transfers oxygen to the fetus. The system chamber includes a stop mechanism including a clamp and an actuator, the clamp positioned in the interior space, the actuator coupled to the clamp such that movement of the actuator moves the clamp, and the actuator positioned at least partially outside the interior space.

A system for safely containing an infant on a mattress is described. The system includes a base that supports the mattress and panels that extend upwardly from the base and together form an enclosure around the mattress. A porthole is defined through at least one of the panels, where the porthole provides access into the enclosure. A porthole door has locked and unlocked positions and covers the porthole only in the locked position. A detection system detects when the porthole door is in the unlocked position. A lighting system is operatively coupled to the detection system and is configured to emit light when the porthole door is detected to be in the unlocked position. A power system provides energy to the lighting system for emitting the light.

A neonatal care system includes an enclosure configured to provide a microenvironment for a neonate, one or more physiological sensors configured to sense a plurality of physiological parameters of the neonate, one or more microenvironmental sensors configured to sense a plurality of microenvironmental parameters within the enclosure, and at least one external environmental sensor configured to sense at least one external parameter outside the enclosure. A control system is configured to control the microenvironment based on a plurality of control settings, track at least one setting change to any of the control settings and in corresponding time of change, and store at least one event and a corresponding time for each event. A longitudinal log is generated including each of the physiological parameters, microenvironmental parameters, external parameter, setting change, and event with respect to time. A display is then generated and displayed based on the longitudinal log.

A neonatal care system includes an enclosure configured to provide a microenvironment for a neonate, one or more physiological sensors configured to sense a plurality of physiological parameters of the neonate, one or more microenvironmental sensors configured to sense a plurality of microenvironmental parameters within the enclosure, and at least one external environmental sensor configured to sense at least one external parameter outside the enclosure. A control system is configured to control the microenvironment based on a plurality of control settings, track at least one setting change to any of the control settings and in corresponding time of change, and store at least one event and a corresponding time for each event. A longitudinal log is generated including each of the physiological parameters, microenvironmental parameters, external parameter, setting change, and event with respect to time. A display is then generated and displayed based on the longitudinal log.

In an exemplary embodiment, a phototherapy device capable of delivering natural sunlight to a subject is provided. The phototherapy device includes an incubator configured to hold a subject for treatment, a support for supporting the incubator, and an enclosure made from a flexible, transparent material connected to the incubator to create a space therein. The enclosure formed around the incubator allows visible sunlight to enter the enclosure in any direction for treating the subject while partially filtering ultraviolet (UV) and infrared radiation (IR) rays of the visible sunlight. The enclosure includes a first part made from a first material and a second part made from a second material different than the first material.

In an exemplary embodiment, a phototherapy device capable of delivering natural sunlight to a subject is provided. The phototherapy device includes an incubator configured to hold a subject for treatment, a support for supporting the incubator, and an enclosure made from a flexible, transparent material connected to the incubator to create a space therein. The enclosure formed around the incubator allows visible sunlight to enter the enclosure in any direction for treating the subject while partially filtering ultraviolet (UV) and infrared radiation (IR) rays of the visible sunlight. The enclosure includes a first part made from a first material and a second part made from a second material different than the first material.

A neonatal incubator system includes an enclosure having a series of side panels that create a chamber that receives an infant. At least one of the side panels includes a porthole having a porthole door that is movable between open and closed positions. A rotary latch is positioned to engage the porthole door to retain the porthole door in the closed position when the latch is in a latched position. The rotary latch is designed such movement of the rotary latch to an unlatched position creates physical separation between the porthole door and a sealing gasket or bumpers located between the porthole door and the side panel. The rotary latch is designed such that a control knob can be moved to a cleaning position in which the control knob is spaced from the side panel to expose a liquid gutter that is formed as part of a stationary base.