It is disclosed an apparatus for restoring voluntary control of locomotion in a subject suffering from a neuromotor impairment comprising a multidirectional trunk support system and a device for epidural electrical stimulation. The robotic interface is capable of evaluating, enabling and training motor pattern generation and balance across a variety of natural walking behaviors in subjects with neuromotor impairments. Optionally, pharmacological cocktails can be administered to enhance rehabilitation results. It is also disclosed a method for the evaluation, enablement and training of a subject suffering from neuromotor impairments by combining robotically assisted evaluation tools with sophisticated neurobiomechanical and statistical analyses. A method for the rehabilitation (by this term also comprising restoring voluntary control of locomotion) of a subject suffering from a neuromotor impairment in particular partial or total paralysis of limbs, is also disclosed.

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.

The present disclosure relates to a system for relieving pain of a user comprising an electromechanical transducer configured to generate generate tactile sound waves (vibrations) with a frequency between 5 Hz and 200 Hz, a holder configured to keep the transducer in a fixed position adjacent to the mesenterial and internal organs' Pacinian corpuscles located in the abdominal cavity of the user, and a controller configured to control the amplitude and frequency of the transducer.

A vibration module for applying vibrational tractions to a wearer's skin is presented. Use of the vibration module in headphones is illustrated for providing tactile sensations of low frequency for music, for massage, and for electrical recording and stimulation of the wearer. Damped, planar, electromagnetically-actuated vibration modules of the moving magnet type are presented in theory and reduced to practice, and shown to provide a substantially uniform frequency response over the range 40-200 Hz with a minimum of unwanted audio.

A method of processing a raw acceleration signal, measured by an accelerometer-based compression monitor, to produce an accurate and precise estimated actual depth of chest compressions. The raw acceleration signal is filtered during integration and then a moving average of past starting points estimates the actual current starting point. An estimated actual peak of the compression is then determined in a similar fashion. The estimated actual starting point is subtracted from the estimated actual peak to calculate the estimated actual depth of chest compressions. In addition, one or more reference sensors (such as an ECG noise sensor) may be used to help establish the starting points of compressions. The reference sensors may be used, either alone or in combination with other signal processing techniques, to enhance the accuracy and precision of the estimated actual depth of compressions.

An electrotherapy system includes a control device, a pulse generator and an electrode pad unit. The control device receives a user input associated with one of twelve meridians of a human, and outputs a control signal associated with the one of the twelve meridians. The pulse generator generates an electrical stimulation signal according to a reference frequency of a reference signal and the one of the twelve meridians with which the control signal is associated. The electrode pad unit contacts a user at a location corresponding to the one of the twelve meridians, and is coupled to the pulse generator for introducing the electrical stimulation signal from the pulse generator to the user.

Aspects herein relate to a stimulation device. The stimulation device includes a flexible board configured for personal use, an array of one or more stimulating components disposed throughout at least a portion of the flexible board, and a stimulation controller in communication with at least one of the one or more stimulating components, the stimulation controller configured to process a stimulation signal that engages or disengages at least one of the one or more stimulating components.

A wearable computing device includes an input/output port for communicating with an external mobile device, a microphone for receiving speech data, a speaker for outputting audio feedback data, and a mobile processor. The mobile processor is designed to receive detected speech data corresponding to a request to open an application on the external mobile device, transmit the request to the external mobile device, and receive a description of content within the application from the external mobile device. The mobile processor is also designed to transmit the description to the speaker to be output, receive detected speech data corresponding to a request for the external mobile device to perform an action within the application, and transmit the request to the external mobile device. The mobile processor is also designed to receive results of the action from the external mobile device and transmit the results to the speaker to be output.

A walking assistance method may include: computing an amount of exercise of a user based on a biosignal of the user; adjusting a pattern of an assist parameter based on the amount of exercise; and/or generating a force corresponding to the amount of exercise, based on the adjusted pattern. A walking assistance apparatus may include: a pattern adjuster configured to compute an amount of exercise of a user based on a biosignal of the user; and/or a driver configured to generate a force corresponding to the amount of exercise based on a pattern of an assist parameter based on the amount of exercise.

A system for assisting with a cardiopulmonary resuscitation (CPR) treatment being administered to a patient. In one aspect, a system for assisting with a cardiopulmonary resuscitation (CPR) treatment being administered to a patient includes a sensor for determining a parameter of the patient (e.g., indicative of a blood flow or pressure waveform), and one or more processors configured for receiving input from the sensor, determining, based on the input from the sensor, whether a rate of chest compressions administered in the CPR treatment should be changed, and providing an indication to a user that the rate of chest compressions should be changed.