An intelligent defecation device for living creature includes a device body, a supporting portion, an image module, and a first analysis module. The supporting portion is formed within the inner side of the device body for accommodating a moisture absorption member so as to allow the living creature to leave over its excrement therein. The image module is also arranged at the device body for dynamically capturing the images of the excrement in the supporting portion and outputting the image. The first analysis module is arranged in the device body and connected with the image module to analyze and calculate the defecation mode with the image based on preset or accumulated data, so as to generate a signal when an abnormal defecation mode is diagnosed.

Technologies for monitoring impaction and predicting impaction state during an orthopaedic surgical procedure include one or more impaction sensors that generate sensor data. The surgical procedure includes impaction of an orthopaedic implement such as a surgical instrument or a prosthetic component. An impaction analyzer generates an impaction state prediction with a machine learning model based on the sensor data. The impaction state prediction may include an unseated state, a seated state, and a fracture state. An impaction state user interface outputs the impaction state prediction. A model trainer may train the machine learning model with labeled sensor data.

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 hydrophobic materials provided around the light-emitting diode and the detector, wherein the hydrophobic materials reduce water absorption and prevent bacterial growth within the sensor.

Systems, devices, and methods are provided to facilitate the implementation of a “proning protocol” to improve a clinical outcome for a person having SARS-CoV-2 (COVID-19) or other condition that may benefit from spending time in the prone position. For example, a system may include a mobile device (e.g., smartphone, tablet, etc.) providing a proning application configured to manage a configuration and implementation of a proning protocol for a person and configured to receive sensor data from (a) a wearable sensor device secured to the person and including sensor(s) (e.g., accelerometer(s)) that monitor the person body position, and/or (b) other sensor(s) that monitor other physiological parameters relative to the proning protocol. The proning application may determine and output feedback to manage the person's position based at least on the received sensor data and defined parameters of the proning protocol.

A caregiver assistance system is disclosed for assisting a caregiver to ensure the beds of high fall risk patients are in desired states for reducing the likelihood of a patient falling. The system may also help the caregiver to perform rounding tasks. The system comprises a server in communication with the patients' beds and one or more mobile electronic devices (e.g. smart phones). The mobile devices receive answers to a plurality of fall risk questions and forward them to the server. The server generates a patient fall risk assessment from the answers, determines a desired state for fall-risk components of the bed if the patient fall risk assessment indicates the patient has a high risk of falling, compares the states of the fall-risk components to corresponding desired states, and issues an alert at the mobile device if any of the fall-risk components are not in their desired state.

Devices, systems, and methods for detecting unexpected movement of a surgical instrument during a robot-assisted surgical procedure are provided. The surgical robot system may be configured to measure forces and torques experienced by the surgical instrument during the surgical procedure and determine if the forces and torques are within an acceptable range. The robot system is further configured to notify the user of the presence of the unexpected movement.

This disclosure relates to a process for forming a membrane on an analyte sensor and further relates to an analyte sensor obtainable by this process. This disclosure also relates to a process for forming a sensing layer on an electrode of an analyte sensor and to an analyte sensor having the sensing layer obtainable by the inventive process as well as the membrane obtainable by the inventive process. The analyte sensors obtainable by the inventive processes may be used for conducting an analyte measurement of a body fluid of a user or a patient. This disclosure may be applied in the field of home care as well as in the field of professional care, such as in hospitals. Other applications are generally feasible.

A head health care device and a head care system are provided. The head health care device includes: a body; a plurality of sensing components provided and projected on an outer surface of the body, in which each sensing component is configured to sense head information of a user; and a plurality of health care components provided and projected on the outer surface of the body, in which the health care components are configured to perform health care operations on a head of the user according to a control signal.

A support pad, including a first cushion layer, a second cushion layer, and a sensing device, is provided. The sensing device is positioned between the first and second cushion layers. The sensing device includes a plurality of sensing elements and a substrate. The substrate includes a plurality of tab portions and a plurality of expandable portions. The sensing elements are respectively mounted to the tab portions. The expandable portions are moveable between contracted and expanded positions in response to pressure applied thereto.

Some embodiments include a method. The method can include providing a scintillator structure. Providing the scintillator structure can include providing a scintillator support layer, providing a scintillator layer, and coupling the scintillator layer to the scintillator support layer. Meanwhile, the scintillator support layer has a substantially non-planar surface, the scintillator layer having a first surface and a second surface opposite the first surface and being configured to scintillate, and the first surface of the scintillator layer is coupled to the substantially non-planar surface of the scintillator support layer such that the second surface of the scintillator layer has a contour of the substantially non-planar surface of the scintillator support layer. Other embodiments of related methods and systems are also disclosed.