Abstract: An infant care system creates a microenvironment about an infant patient. An environmental control device is operable to change an environmental condition within the microenvironment. An auxiliary sensor is operable to intermittently obtain auxiliary data. A processor operates the environmental control device based upon at least the intermittently obtained auxiliary data.

Abstract: An infant care system includes an infant care tower configured to receive at least one medical device. A processor operates the infant care tower and the at least one medical device. A bassinet is configured to receive an infant patient within a microenvironment defined and maintained by the bassinet. Upon connection of the bassinet to the infant care tower, the processor operates to control both the infant care tower and the bassinet in maintain the microenvironment of the bassinet. In a method of treating an infant patient, an infant patient is provided in a microenvironment defined and maintained by a bassinet. The bassinet is communicatively connected to the care tower and a first processor of the infant care tower operates the bassinet to maintain the microenvironment to provide medical care to the infant patient with the at least one medical device of the infant care tower.

Abstract: An infant care system creates a microenvironment about an infant patient. An environmental control device is operable to change an environmental condition within the microenvironment. An auxiliary sensor is operable to intermittently obtain auxiliary data. A processor operates the environmental control device based upon at least the intermittently obtained auxiliary data.

Abstract: An infant care system and apparatus includes a horizontal surface to support an infant. A microenvironment region is defined around the horizontal surface by at least one wall. A graphical display is disposed within the microenvironment region. A diagnostic imaging device is at least partially disposed within the microenvironment region to obtain diagnostic images of an infant disposed within the microenvironment region.

Abstract: A system for monitoring the physiological conditions of a plurality of infants in a neonatal intensive care unit (NICU). The system includes a plurality of microenvironments, a plurality of environmental sensors to detect a first environmental condition in the microenvironments, and a plurality of external environmental sensors to detect a second environmental condition in the NICU. The system also includes a central processor that compares signals from the environmental sensors to signals from the external environmental sensors and determines a correlation between the first environmental condition and the second environmental condition. A method of monitoring the conditions of a plurality of infants is also disclosed.

Abstract: A system for monitoring the physiological conditions of an infant includes an infant microenvironment. A motion sensor is disposed about the microenvironment. A processor is communicatively connected to the motion sensor. The processor receives motion signals from the motion sensors and processes the motion signals to derive an indication of a stress level of the infant. A method of monitoring the physiological condition of an infant includes detecting motion of the infant with motion sensors. A baseline motion for the infant is derived from the detected motion with a processor. An onset or change in at least one auxiliary parameter is monitored with an auxiliary sensor. Motion of the infant is monitored with the motion sensor after the onset or change in the at least one auxiliary parameter. A stress level of the infant is derived with the processor from the monitored motion of the infant.

Abstract: An infant care system creates a microenvironment about an infant patient. An environmental control device is operable to change an environmental condition within the microenvironment. An auxiliary sensor is operable to intermittently obtain auxiliary data. A processor operates the environmental control device based upon at least the intermittently obtained auxiliary data.

Abstract: An infant care system includes an infant care tower configured to receive at least one medical device. A processor operates the infant care tower and the at least one medical device. A bassinet is configured to receive an infant patient within a microenvironment defined and maintained by the bassinet. Upon connection of the bassinet to the infant care tower, the processor operates to control both the infant care tower and the bassinet in maintain the microenvironment of the bassinet. In a method of treating an infant patient, an infant patient is provided in a microenvironment defined and maintained by a bassinet. The bassinet is communicatively connected to the care tower and a first processor of the infant care tower operates the bassinet to maintain the microenvironment to provide medical care to the infant patient with the at least one medical device of the infant care tower.

Abstract: A method and microenvironment includes accessing a dynamic image from a computer-readable medium and displaying the dynamic image on a display device communicatively connected to the microenvironment. The dynamic image includes a representation of an action performed by a clinician with respect to the microenvironment.

Abstract: A system for monitoring the physiological conditions of a plurality of infants in a neonatal intensive care unit (NICU). The system includes a plurality of microenvironments, a plurality of environmental sensors to detect a first environmental condition in the microenvironments, and a plurality of external environmental sensors to detect a second environmental condition in the NICU. The system also includes a central processor that compares signals from the environmental sensors to signals from the external environmental sensors and determines a correlation between the first environmental condition and the second environmental condition. A method of monitoring the conditions of a plurality of infants is also disclosed.

Abstract: A system for monitoring the physiological conditions of an infant includes an infant microenvironment. A motion sensor is disposed about the microenvironment. A processor is communicatively connected to the motion sensor. The processor receives motion signals from the motion sensors and processes the motion signals to derive an indication of a stress level of the infant. A method of monitoring the physiological condition of an infant includes detecting motion of the infant with motion sensors. A baseline motion for the infant is derived from the detected motion with a processor. An onset or change in at least one auxiliary parameter is monitored with an auxiliary sensor. Motion of the infant is monitored with the motion sensor after the onset or change in the at least one auxiliary parameter. A stress level of the infant is derived with the processor from the monitored motion of the infant.

Abstract: An infant care system and apparatus includes a horizontal surface to support an infant. A microenvironment region is defined around the horizontal surface by at least one wall. A graphical display is disposed within the microenvironment region. A diagnostic imaging device is at least partially disposed within the microenvironment region to obtain diagnostic images of an infant disposed within the microenvironment region.

Abstract: An infant care bed for supporting an infant having incorporated therein, certain testing and evaluation devices to carrying out the evaluation of an infant in a medical care facility. The apparatus can carry out at least one of the following tests on the infant: determining the weight of an infant, determining the sucking strength of an infant, determining the ability of the infant to hear certain frequencies and determining the bilirubin level of the infant's blood. The infant care bed includes a computer with a memory device such that the hospital can input a customized protocol of the tests to be performed on the infant and the criteria for passing the tests. A data input allows the personnel to input test results and a display provides an account of the tests performed and the tests not performed to assure that all of the tests required by the protocol are conducted.

Abstract: A patient carestation for providing care to a patient including at least one environmental sensor sensing information concerning the environment surrounding the patient and providing electronic signals indicative of that environment. There are also physiological sensors sensing information relating to physiological conditions of the patient other than skin temperature and providing electronic signals indicative of physiological conditions of the patient. There may also be therapeutic sensors providing data based on therapy administered by peripheral apparatus and an input receiving patient information. A signal processor receives the signals from the physiological sensors, the environmental sensor, the therapeutic sensor and the patient information input and combines those signals into an integrated combination of signals for use by the caregiver. The integrated combination of signals can be used in a smart alarm or to generally appraise the caregiver at a central location as to the status of the patient.

Abstract: A blanket or article of wearing apparel for a subject such as an infant. A fiber optic temperature sensing element is integrated into the fabric by a process such as weaving. The temperature sensing element is a optic fiber having inscribed therein one or more fiber Bragg grating sensors such that a light is introduced into the optic fiber and that light directed onto the subject at a grating interface. A return light signal is received, either by a reflectance mode or a transmission mode, where the return light signal has a wavelength shift indicative of the temperature of the subject by Bragg resonant effect. Higher temperature sensitivity is obtained with a metal material of a high thermal expansion coefficient that is coated around the fiber sensor cladding.

Abstract: A patient carestation for providing care to a patient including at least one environmental sensor sensing information concerning the environment surrounding the patient and providing electronic signals indicative of that environment. There are also physiological sensors sensing information relating to physiological conditions of the patient other than skin temperature and providing electronic signals indicative of physiological conditions of the patient. There may also be therapeutic sensors providing data based on therapy administered by peripheral apparatus and an input receiving patient information. A signal processor receives the signals from the physiological sensors, the environmental sensor, the therapeutic sensor and the patient information input and combines those signals into an integrated combination of signals for use by the caregiver. The integrated combination of signals can be used in a smart alarm or to generally appraise the caregiver at a central location as to the status of the patient.

Abstract: An infant care apparatus for supporting an infant upon an infant platform having a humidification control system. The user can initial select a manual mode where the humidity is inputted through a user input to control the humidity within an infant compartment. The system has an automatic mode where the user can then input humidity levels and a successive time periods to establish a protocol for controlling the humidity within the infant compartment over the time period the infant is being treated within the infant care apparatus. Each successive time period inputted by the user has a different humidity level associated herewith. As a further feature, there is an evaluation system to monitor whether the infant has been overstressed by any of the automatic reductions in the levels of humidity.

Abstract: A blanket or article of wearing apparel for a subject such as an infant. A fiber optic temperature sensing element is integrated into the fabric by a process such as weaving. The temperature sensing element is a optic fiber having inscribed therein one or more fiber Bragg grating sensors such that a light is introduced into the optic fiber and that light directed onto the subject at a grating interface. A return light signal is received, either by a reflectance mode or a transmission mode, where the return light signal has a wavelength shift indicative of the temperature of the subject by Bragg resonant effect. Higher temperature sensitivity is obtained with a metal material of a high thermal expansion coefficient that is coated around the fiber sensor cladding.