A computer-implemented method and corresponding output generator for handling alarm events, generated by a subject/patient monitoring device, and generating clinician-perceptible outputs indicative of the alarm events. Alarm events are divided into non-actionable and actionable alarm events. Information on non-actionable alarm events is stored. Stored information on non-actionable alarm events is contained in a clinician-perceptible output generated in response to detecting an actionable alarm event.

The present disclosure relates to a blood collection device, including: a shell; a blade seat, arranged in the shell; an elastic component for providing an elastic force for pivoting the blade seat; a triggering portion, including an operating end and an abutting end, wherein the triggering portion has a first position and a second position for pivoting, the operating end extends to the outside of the shell, the abutting end is located in the shell, based on the operation of the operating end, the triggering portion is suitable for pivoting from the first position that prevents the blade seat from pivoting to the second position that allows the blade seat to pivot based on the elastic force of the elastic component, wherein: a cooperation column is arranged in the shell and is located at the upper side of the triggering portion spaced from the triggering portion; and an elastic arm is connected to the upper side of the triggering portion, the end part of the elastic arm includes a blocking portion, the end part of the elastic arm is suitable for being located on one side of the cooperation column when the triggering portion is at the first position, and is located on the other side of the cooperation column when the triggering portion pivots from the first position to the second position, and the blocking portion provides resistance for the end part of the elastic arm while moving from one side of the cooperation column to the other side.

A system for EIT imaging comprises an electrode array for positioning on a patient and measuring an impedance distribution, a data entry unit and a calculation unit. The electrode array contains a visual aid coupled to the electrode array for visually indicating the position of at least one electrode, the data entry module accepts an entry of data describing the position of the visual aid, and the calculation unit calculates the position of the individual electrodes relative to the patient's body and provides correction for the image creation algorithm. A sensor device for EIT imaging may comprise the electrode array, which is connectable to an EIT imaging system comprising a data entry unit and a calculation unit. An EIT imaging method may employ the system or sensor device.

An infant warming system comprising a platform for supporting an infant, at least two chest electrodes configured to connect to and detect cardiac potentials from a chest of the infant, an ECG monitor configured to receive the cardiac potentials from the at least two chest electrodes and determine a heart rate based on the cardiac potentials, a pulse oximeter device configured to determine an SpO.sub.2 for the infant, and a processor configured to compare the heart rate for the infant to a first heart rate threshold and compare the SpO.sub.2 for the infant to a first SpO.sub.2 threshold. The processor can also adjust a display of the heart rate and the SpO.sub.2 on a display device based on the comparisons and generate a first care instruction via a user interface based on the heart rate, the SpO.sub.2, or a combination thereof.

The present disclosure relates to a transfer cart suitable for use in association with an MR scanner. The transfer cart may include a transfer table assembly coupled to the support frame such that the transfer table assembly and the horizontal support structure portion of the support frame extend substantially perpendicularly from the vertical support structure of the support frame and in substantially parallel planes to each other. The transfer table assembly may be maintained at substantially the same vertical level of a scanning bore of an MR scanner. The transfer cart may include a frame designed to dock with the MR scanner.

An neonatal care unit comprising: a hood defining an interior space and having a bottom opening, wherein the hood is dimensioned to accommodate a neonate; a sealing skirt extending along at least a portion of a peripheral edge of the bottom opening and configured to engage at least part of a front torso region of a human in a sealing engagement; at least one access opening located about a sidewall of the hood and dimensioned to allow passage of the neonate therethrough; at least two arm ports located about the sidewall and dimensioned to allow passage of a hand therethrough; and at least one port configured to allow passage of a medical conduit therethrough.

A patient monitoring sensor having a communication interface, through which the patient monitoring sensor can communicate with a monitor is provided. The patient monitoring sensor includes a light-emitting diode (LED) communicatively coupled to the communication interface and a detector, communicatively coupled to the communication interface, capable of detecting light. The patient monitoring sensor includes a silicone patient-side adhesive.

A system and method for pain level recognition using an automated approach which incorporates a pain-affect dataset comprising bioVid pain and bioVid emotion datasets for the assessment of patient pain in clinical settings where patients often experience other affect states, such as anger and anxiety, in addition to pain.

According to some aspects, a system configured to facilitate imaging an infant using a magnetic resonance imaging (MRI) device is provided herein. The system comprises an infant-carrying apparatus comprising an infant support configured to support the infant and an isolette for positioning the infant relative to the MRI device, the isolette comprising: a base for supporting the infant-carrying apparatus; and a bottom surface configured to be coupled to the MRI device. In some embodiments, the infant-carrying apparatus further comprises at least one radio frequency (RF) coil coupled to the infant support and configured to be coupled to the MRI device to detect MR signals during imaging performed by the MRI device. A method for positioning an infant relative to an MRI device using an infant-carrying apparatus and isolette is further provided herein.

Various methods and systems are provided for selecting sensors for acquiring physiological data of a patient. In one embodiment, a system comprises a plurality of sensors, a dynamic selection switch communicatively coupled to the plurality of sensors, a plurality of acquisition channels communicatively coupled to the dynamic selection switch, and a processor communicatively coupled to the dynamic selection switch and configured with executable instructions in non-transitory memory that when executed cause the processor to: select a subset of sensors; control the dynamic selection switch to connect the subset of sensors to the plurality of acquisition channels; and acquire, from the subset of sensors via the plurality of acquisition channels, physiological data of a patient. In this way, a subset of sensors in a plurality of sensors may be dynamically selected in real-time for acquiring physiological data of the patient.