A device for measuring a temperature at one or more locations in an organ or tissue inside the human or animal body, a related kit and a related method. The device includes a catheter tube having a distal end for inserting into the body and a proximal end for remaining outside the body in use of the device, and at least one resistive temperature sensor in the tube, and a plurality of electrical wires in the tube that are connected to the at least one resistive temperature sensor. The plurality of electrical wires includes at least some electrical wires running from the proximal end of the tube through the tube. The device includes a connector at the proximal end of the tube for electrically connecting the plurality of electrical wires to an external device. The resistive temperature sensor includes a thermal resistor and a first terminal and a second terminal.

Methods, implantable devices, and systems for treating a cancer or inhibiting cancer growth or recurrence in a subject are described herein. Such methods can include electrically stimulating a thoracic splanchnic nerve (such as a greater splanchnic nerve) of the subject with a plurality of electrical pulses emitted from one or more electrodes m electrical communication with the splanchnic nerve, wherein the plurality of electrical pulses triggers one or more action potentials in the splanchnic nerve to increase circulating natural killer (NK) cells in the subject. An implantable device may include one or more electrodes configured to be in electrical communication with a thoracic splanchnic nerve of a subject with cancer, and be configured to operate the one or more electrodes to electrically stimulate the splanchnic nerve with a plurality of electrical pulses that triggers one or more action potentials in the splanchnic nerve that increase circulating NK cells.

A photobiomodulation therapy low-level laser targeting system has a controller, a low lever laser emitter controlled by the controller and a projector operably coupled to the emitter and controlled by the controller to control the projection direction of light from the emitter. The controller has a targeting controller configured for controlling the projector to project light from the emitter onto a skin surface target area in use to target a subdermal target region.

A photobiomodulation therapy low-level laser targeting system has a controller, a low lever laser emitter controlled by the controller and a projector operably coupled to the emitter and controlled by the controller to control the projection direction of light from the emitter. The controller has a targeting controller configured for controlling the projector to project light from the emitter onto a skin surface target area in use to target a subdermal target region.

Systems and methods for measuring vitals in accordance with embodiments of the invention are illustrated. One embodiment includes a method for measuring vital signs. The method includes steps for identifying regions of interest (ROIs) from video data of an individual, generating temporal waveforms from the ROIs, analyzing the generated temporal waveforms to extract vital sign measurements, and generating outputs based on the analyzed temporal waveforms.

Technology is disclosed for detecting scratch events and predicting flares of pruritus, utilizing motion data sensed from a wearable sensor. Detecting scratch may be done with a two-tier approach by first detecting a hand motion from motion sensed data and then classifying that hand motion as a scratch event using one or more computerized classification models. Embodiments may focus on detecting nighttime scratch by utilizing motion sensed data captured during a user's detected sleep opportunity. Additionally, historical scratch event data may be used to predict a user's itch and flare risk for a future time interval. Decision support tools in the form of computer applications or services may utilize the detected scratch events or predicted itch or flare risk to initiate an action for reducing current itch and/or mitigating future risk, including initiating a treatment protocol that includes therapeutic agent.

Technology is disclosed for detecting scratch events and predicting flares of pruritus, utilizing motion data sensed from a wearable sensor. Detecting scratch may be done with a two-tier approach by first detecting a hand motion from motion sensed data and then classifying that hand motion as a scratch event using one or more computerized classification models. Embodiments may focus on detecting nighttime scratch by utilizing motion sensed data captured during a user's detected sleep opportunity. Additionally, historical scratch event data may be used to predict a user's itch and flare risk for a future time interval. Decision support tools in the form of computer applications or services may utilize the detected scratch events or predicted itch or flare risk to initiate an action for reducing current itch and/or mitigating future risk, including initiating a treatment protocol that includes therapeutic agent.

A system includes a sensor configured to generate data associated with movements of a resident for a period of time, a memory storing machine-readable instructions, and a control system arranged to provide control signals to one or more electronic devices. The control system also includes one or more processors configured to execute the machine-readable instructions to analyze the generated data associated with the movement of the resident, determine, based at least in part on the analysis, a likelihood for a fall event to occur for the resident within a predetermined amount of time, and responsive to the determination of the likelihood for the fall event satisfying a threshold, cause an operation of the one or more electronic devices to be modified.

A vital signal detection device includes: an antenna unit provided with a planar antenna of a MIMO radar on a front surface; and a display unit including a display panel on the front surface. The antenna unit is combined with the display unit or the display unit is combined with the antenna unit in a rotatable manner so that, from a state where the planar antenna and the display panel face in a direction ahead of the front surface, the planar antenna is turned to be directed to a direction of a back surface of the display unit opposite from the display panel. The portable non-contact vital signal detection device detects a vital signal on a side ahead of the front surface and a vital signal on a side in the direction of the back surface opposite from the front surface.

A respiratory status examination apparatus and method, and a sleep disorder control device and method are proposed. The apparatus may include at least one image capturing unit that is movably arranged to adjust a distance with respect to a subject and configured to obtain a thermal image by photographing the subject. The apparatus may also include a motion sensor unit configured to detect a motion of the subject to generate motion information, and a temperature information extracting unit configured to specify at least one examination region from the thermal image obtained by the image capturing unit and extract temperature information from the examination region. The apparatus may further include a respiratory status examining unit configured to determine a respiratory status of the subject based on the temperature information extracted by the temperature information extracting unit and the motion information generated by the motion sensor unit.