A method for providing directions to a blind user of a smart device is described. The method includes detecting, by at least two sensors and in response to a selection of a find mode of the smart device, image data corresponding to a surrounding environment of the smart device and positioning data corresponding to a positioning of the smart device. The method also includes receiving, by an input device, the desired object or the desired location. The method also includes determining, by a processor, the initial location of the smart device based on the image data, the positioning data and map data stored in a memory of the smart device. The method also includes providing, by the output device, the directions to the desired object based on the initial location of the smart device and the map data.

An example method includes administering a treatment to a subject during a time interval. The example method further includes receiving, from an external device, a first signal indicating a physiological parameter of the subject detected during the time interval; removing, from the physiological parameter, an artifact associated with the treatment; and in response to removing the artifact from the physiological parameter, outputting a second signal indicating the physiological parameter.

A medical system for assisting with an intubation procedure for a patient. The system comprising airflow sensors configured to obtain data indicative of airflow in the patient's airway and physiological sensors configured to obtain information regarding airflow in the patient's lungs. The system further including a monitoring device communicatively coupled to the airflow sensors and the physiological sensors. The patient monitoring device comprising at least one processor coupled to memory and configured to: provide a user interface on a display and assist the rescuer in determining proper placement of an endotracheal tube, receive the data indicative of the airflow in the patient's airway, receive the physiological information regarding the airflow in the patient's lungs, and determine whether the tube is properly placed based on the received physiological information, and present an output of the determination of whether the ET tube was properly placed.

Systems, devices and methods for providing active and/or passive compression therapy to a body part can include a compression device worn over a compression stocking. The compression device can have a pulley based drive train that is driven by a motor to tighten and loosen compression elements, such as compression straps, in a precise, rapid, and balanced manner. Sensors can be used in the compression device and/or compression stockings to provide feedback to modulate the compression treatment parameters.

The invention is to provide a pressurized gas mist bathing system, ensuring hygiene and reduction in costs, by making only one part of the system disposable. This system causes a mist to contact the skin or the mucous membrane of a living body in a high pressure not less than a predetermined value, the mist is prepared by pulverizing liquid and the mist of micron size dissolving oxygen and/or carbon dioxide gases and comprises a gas supply means 10; a gas mist generating means 30 having a fluid nozzle 32 of generating the gas mist and a liquid storage 34 of storing liquid; a pressure cover 50 for covering the skin and the mucous membrane of the living body and formed with a space for sealing inside the gas mist supplied from the gas mist generating means 30; and a humors circulating means 41 for circulating the liquid from the liquid storage 34 of the gas mist generating means 30 to the fluid nozzle 32 and wherein, in the gas mist generating means 30, at least the liquid storage 34 is displaceable and replaced by another liquid storage.

An example system includes a first wearable computing device, and at least one additional wearable computing device. The first wearable computing device is configured to retrieve information regarding a series of tasks to be performed in treating a patient in cardiopulmonary arrest. The information includes, for each task, an indication of a user to perform the task, an indication of a time point to perform the task. The first wearable computing device is further configured identify one or more subsets of the information, and transmit each subset to a different corresponding one of the additional wearable computing devices. Each additional wearable computing device is configured to receive, from the first wearable computing device, at least one of the one or more subsets of the information, and output, for each task within a received subset, a corresponding prompt to perform the task at the respective time point associated with the task.

A pneumatic circulatory enhancer to enhance a blood flow of a leg of a patient that includes a chamber that surrounds the leg and is filled with gas having a negative, a zero-point, or a pressure, a pneumatic gas pump having a cylinder and a piston, the piston moving in the cylinder by an electrical motor, a plurality of ECG electrodes that are connected to body parts of the patient, a pressure sensor that is connected to the chamber and measures a pressure of the gas inside the chamber, a controller that receives the ECG signals from the plurality of ECG electrodes and controls the electrical motor based on the received ECG signals to pump-in or pump-out the gas from the chamber by moving the piston inside the chamber such that the zero-point pressure is an atmospheric pressure of a location that the pneumatic circulatory enhancer is operated.

A CPR system includes a retention structure to retain the patient's body, and a compression mechanism to perform CPR compressions to the patient's chest. The CPR system further includes a processor to control the compression mechanism, and thus the performance of the CPR compressions. In embodiments, the CPR system compresses at a rate or frequency that is varied based on feedback gathered from physiological sensors that detect physiological characteristics of the patient during treatment.

Disclosed are various embodiments for implementing and creating a customizable artificial hand massage apparatus configured to simulate actual hand movements associated with a human user. The customizable artificial hand massage apparatus may also be configured to execute a massage application. The massage application may be executed to store information associated with the user of the customizable artificial hand massage apparatus, detect sounds, detect motion, determine an amount of gas expelled from the user of the customizable artificial hand massage apparatus, determine the number of times an infant burps, detects how far an object or person is located with respect to the customizable artificial hand massage apparatus, and transfer information to a separate control application.

A pulmonary expansion therapy (PXT) device may be a handheld or wearable device that covers specific lung fields and may generate negative pressure fields locally. The device also may provide vibratory/percussion therapy for airway clearance. The PXT may generate a localized negative pressure field non-invasively to the exterior of the chest wall, thereby increasing the functional residual capacity in underlying lung fields. As a result, increased ventilation and perfusion to the targeted internal lung field may be achieved by creating a decrease in the external barometric pressure relative to the more positive intrinsic airway pressures. The PXT device also may improve lung compliance by elevating the chest wall to compensate for the dysfunction of the respiratory musculature responsible for lifting the chest wall. In some embodiments, once a targeted functional residual capacity (FRC) has been established, vibration or percussion may be applied.