There is provided an assistance apparatus in which when assistance provided to a user in walking is to be stopped, a motor reduces a tension of a first wire and a tension of a second wire, which couple an upper-body belt and a left knee belt to each other on or above a front part and a back part of a body of the user, to less than a second threshold value during a first stop period in a gait phase of a left leg of the user, the first stop period being a period from a period included in a first period and including a timing at which the left leg shifts from a stance phase to a swing phase to a start period of a second period, and reduces a tension of a third wire and a tension of a fourth wire, which couple the upper-body belt and a right knee belt to each other on or above the front part and back part of the body of the user, to less than the second threshold value during a second stop period in a gait phase of a right leg of the user, the second stop period being a period from a period included in a third period and including a timing at which the right leg shifts from the stance phase to the swing phase to a start period of a fourth period.

An assistance apparatus includes wires that couple an upper body belt to be worn on an upper body of a user to first and second knee belts to be worn above left and right knees of the user, and a motor. In a case of assisting the user in turning left, the motor generates a tension in second and fourth wires in a period of 65% or more and 100% or less of a first gait phase of a left leg and a period of 0% or more and 20% or less of a second gait phase of the left leg, and generates a tension in sixth and eighth wires in a period of 65% or more and 100% or less of a first gait phase of a right leg and a period of 0% or more and 20% or less of a second gait phase of the right leg.

An assisting torque setting apparatus and method, wherein the apparatus is configured to generate a reference gait model by applying body information of a user to a predetermined body model, and set an optimal assisting torque by adjusting an assisting torque provided from a walking assistance apparatus to the user based on the reference gait model is disclosed.

Technologies and implementations for wearable healthcare devices are generally disclosed. An example method performed by a wrist-wearable device includes: detecting, by a sensor, a physiological parameter of a user; determining, by a processor based on the physiological parameter, that the user is experiencing atrial fibrillation (AF); outputting, by a display, a visual signal indicating that the user is experiencing the AF; and transmitting, by a transceiver to a first external computing device, a first wireless signal indicating that the user experienced the AF.

A motorized rehabilitation device includes a mobile base bound by a lower surface and an upper surface. A first motorized wheel assembly is supported on the upper surface of the mobile base. The mobile base also includes a second motorized wheel assembly at least partially extending below the lower surface of the base. A dome is bound by an exterior convex surface and an interior concave surface. The dome is biased for friction contact of the interior concave surface with the first motorized wheel assembly. An end-effector is positioned above the exterior concave surface. The end-effector is configured to engage an animal body part.

A massage unit includes a treatment member; an arm that supports the treatment member; a drive shaft that supports the arm and causes the treatment member to approach and be separated with respect to a treatment target site; a movable portion that causes the treatment member to be operable in a direction of being separated from the treatment target site when the treatment member comes into contact with the treatment target site by a force equal to or greater than predetermined strength; and biasing means for biasing the treatment member in an approaching direction.

A comprehensive system for treatment of wrist joint proprioception. The system includes a manipulandum unit and a controller. The unit includes a base, a handle, a linkage assembly, and motors. The base supports a subject's forearm, and the handle is gripped by the palm. The linkage assembly connects the handle to the base, and establishes three DOFs. The motors are operatively connected to the linkage assembly. The controller is programmed to actuate, and receive feedback information from, each of the plurality of motors. Further, the controller is programmed to perform wrist proprioception assessment operations by actuating the plurality of motors to effectuate movement of the handle relative to the base in a prescribed manner indicative of position motion sense acuity as an objective measure of wrist proprioception functioning. The controller is optionally further programmed to perform rehabilitation training via controlled operation of the unit and a virtually reality environment.

A system for use during administration of cardiopulmonary resuscitation (CPR) chest compressions on a victim is described. The system includes a chest compression monitor that includes a motion sensor configured to generate signals indicative of the victim's chest motion and a control system communicatively coupled to the chest compression monitor and configured to receive the generated signals, detect compression waveform features representative of the chest compressions based on the received signals, compare the features to a pre-determined criterion that distinguishes between a manual source of the chest compressions and a piston-based chest compression device source, determine whether the source of the chest compressions is the manual or the piston-based chest compression device source based on the comparison, and generate an output based on whether the source of the chest compressions is determined to be the manual or the piston-based chest compression device source.

Exosuit systems may be assistive, as it physically assists the wearer in performing particular activities, or can provide other functionality such as communication to the wearer through physical expressions to the body, engagement of the environment, or capturing of information from the wearer. In order to transmit assistance to the user of the exosuit, loads need to be translated by the exosuit. This is can be through the use of load distribution members. Load distribution members can be placed around the pelvis, waist, thighs, and other body parts.

A gait management apparatus applies stimulation to a user suffering from a neurological disease (such as Parkinson's Disease) gait dysfunction. Motion sensors are arranged to be worn by a patient, and electrical stimulation electrodes are on the legs for stimulation. A controller receives motion sensing signals, and processes these signals to generate stimulation signals for operation of the electrodes to stimulate limb movement upon detection of a gait abnormality. There may be a user actuator for user actuation of electrical stimulation, and the inputs may be a series of taps. The controller may provide signals to prevent occurrence of freezing of gait when it senses that a patient is walking or has an intention to walk. Also, it may apply stimulation at an intensity level which is insufficient for functional muscle stimulation but sufficiently high to trigger activation of efferent nerves.