One general aspect of technical solutions described herein includes a biomechanical assistive device that includes one or more sensors, a back-drivable motor system, and a controller. The controller, when the motor system is inactive, records measurements from the one or more sensors for user motion pattern analysis during a user activity being performed by a user. The controller, when the motor system is active, records the measurements from the one or more sensors, and generates an assist torque to assist the user to perform the user activity.

According to one or more embodiments, a biomechanical assistive device is described that generates and provide assist torque by detecting user intent. An example biomechanical assistive device includes a motor, and a controller that generates a torque command for providing assist torque using the motor based on a user activity being performed using the biomechanical assistive device. The controller determines a stride frequency based on a position signal indicative of a position of a joint of the biomechanical assistive device. The controller dynamically adjusts the torque command based on the stride frequency to generate a final torque command. The controller applies the final torque command to the motor.

A method to treat a dry eye condition of an individual, includes: receiving a switch signal generated based on a manipulation of a control switch at a handheld device; and activating a motor in response to the switch signal to oscillate a member at an oscillation frequency, the member having an elongated configuration, and having a portion for placement outside the individual; wherein the oscillation frequency is sufficient to induce tear production when the portion of the member is applied towards a surface of a body portion of the individual.

A garment assembly includes a sleeve member having outer and inner surfaces, a first vibration assembly associated with the sleeve member, and a control module associated with the sleeve member. The first vibration assembly includes a plurality of vibration motors that are arranged in a circle about a center point. An angular distance between each vibration motor of the plurality of vibration motors is approximately the same. The control module includes a battery, and the first vibration assembly is in electrical communication with the control module.

Time after time studies find that often, even when administered by trained professionals, cardiopulmonary resuscitation (CPR) compression rates and depth are inadequate. Too week, shallow or too forceful compressions may contribute to suboptimal patient outcome. Several parameters are crucial for optimal and properly-administered CPR. Crucial parameters include proper hand positioning on the patient's chest, depth of compression of 4-5 cm, and compression rate of 100 compressions per minute. The crucial parameters are often affected by patient parameters, and relative to the patient, rescuer parameters, such as patient thoracic volume; weight; age; gender; and rescuer's, relative to the patient's, parameters, such as weight, height; physical form, etc. Proposed is an automated CPR feedback device with user programmable settings for assisting with real-time feedback and subsequently correcting rescuers patient customized CPR technique.

An example of a system for providing emergency care to a patient is described that includes a backboard arranged to support the patient, a chest compressor attached to the backboard and positioned to engage the patient at the chest, the chest compressor configured to provide multiple chest compression cycles to the patient, a cuirass attached to the backboard and positioned to engage the patient at the abdomen, the cuirass configured to generate negative pressure to pull outward on the abdomen and to provide multiple abdominal compression cycles to the patient and a controller including processors configured to: control the chest compressor to perform the multiple chest compression cycles according to a programmed sequence, control the cuirass to perform the multiple abdominal compression cycles according to the programmed sequence, and control the cuirass to generate the negative pressure to pull outward on the abdomen during the multiple abdominal compression cycles.

Systems and methods related to the field of cardiac resuscitation, and in particular to devices for assisting rescuers in performing cardio-pulmonary resuscitation (CPR).

Systems and methods related to the field of cardiac resuscitation, and in particular to devices for assisting rescuers in performing cardio-pulmonary resuscitation (CPR).

A method for providing emergency care to a patient of an adverse cardiac event is disclosed that includes causing multiple chest compressions to be provided to the patient, and causing multiple inducements of ventilation to be provided to the patient. Particular ones of the multiple chest compressions can overlap time-wise with corresponding ones of the multiple inducements of ventilation, and can be substantially out of phase with the corresponding ones of the multiple inducements of ventilation.

Time after time studies find that often, even when administered by trained professionals, cardiopulmonary resuscitation (CPR) compression rates and depth are inadequate. Too week, shallow or too forceful compressions may contribute to suboptimal patient outcome. Several parameters are crucial for optimal and properly-administered CPR. Crucial parameters include proper hand positioning on the patient's chest, depth of compression of 4-5 cm, and compression rate of 100 compressions per minute. The crucial parameters are often affected by patient parameters, and relative to the patient, rescuer parameters, such as patient thoracic volume; weight; age; gender; and rescuer's, relative to the patient's, parameters, such as weight, height; physical form, etc. Proposed is an automated CPR feedback device with user programmable settings for assisting with real-time feedback and subsequently correcting rescuers patient customized CPR technique.