The present disclosure provides a grip sensor for quantifying pain experienced by a patient during spinal cord stimulation (SCS). The grip sensor includes an electronics enclosure, an annular outer shell substantially surrounding the electronics enclosure and sized to be held by the patient, a pressure sensor embedded in the outer shell and communicatively coupled to the electronics enclosure, the pressure sensor configured to measure a grip strength of the patient as SCS is applied to the patient, and a plurality of galvanic skin response sensors communicatively coupled to the electronics enclosure and configured to measure an electrical impedance of the skin of the patient as SCS is applied to the patient.

An electrical stimulation is applied to a patient via a lead by increasing a stimulation parameter over time. An anal sphincter response, a bellows response, and a toes response from the patient are detected as a result of the electrical stimulation. A first value of the stimulation parameter associated with the anal sphincter response, a second value of the stimulation parameter associated with the bellows response, and a third value of the stimulation parameter associated with the toes response are determined. A placement of the lead inside the patient is evaluated based on: a chronological occurrence of the anal sphincter response, the bellows response, and the toes response; a comparison of the first value with a predetermined threshold; a deviation of the second value from the first value; a deviation of the third value from the first value; or a deviation of the third value from the second value.

Disclosed is system for assessing a motor function, the system including a sensor configured to acquire human body exercise information including a joint position, a joint orientation, a grasp state, or a grasp force, a processor configured to extract an exercise feature for analyzing a human body motion time and human body motion information based on the acquired human body exercise information, analyze at least one target motion for assessment based on a set assessment condition using the extracted exercise feature, classify an assessment factor of the at least one target motion for assessment as a success or a failure, and determine a final assessment score of the at least one target motion for assessment based on the classified assessment factor, and a display configured to display the final assessment score.

Control system (200) for a strengthening glove (100) with fingers (101-105), comprising a force detecting sensor means (210) for detecting, at different measurement locations (211-218) on the palm side (106) of said glove fingers, a respective force between a finger (11-15) and a contact surface, further arranged to impart a force to respective glove fingers, bending them towards a gripping position, further arranged to read measurement values from the strengthening feedback loop based upon the measurement values. The invention is characterised in that a predetermined pattern is detected, comprising certain measurement values, in that, when the said pattern is not detected and the actuating means are controlled according to a first program, and further when the said pattern is detected, they are controlled according to a second program, which first and second programs are different.

One or more processors identify an occupant of a passenger vehicle, and then receive biometric sensor readings from a biometric sensor that is monitoring the occupant in real time, where the biometric sensor readings indicate a real-time emotional state of the occupant. The processor(s) generate a personal profile for the occupant of the passenger vehicle based on the biometric sensor readings. The processor(s) receive a desired destination and travel schedule for the occupant of the passenger vehicle, as well as environmental sensor readings indicating a real-time environmental state of the passenger vehicle. The processor(s) then create a travel route for the passenger vehicle based on the biometric sensor readings, the personal profile of the vehicle occupant, the desired destination and travel schedule, and the real-time environmental state of the passenger vehicle. One or more processors then transmit, to the passenger vehicle, directions for the travel route.

A grip pressure measurement device is embedded in a swing object used for sports, such as a golf club or a racquet. Embedding can occur during manufacturing or as an after-market modification. The grip measurement device comprises one or more pressure sensors, a local processor, and a network interface. One embodiment of the pressure sensors measures from two sides, a side of contact with a player's hand and a side of contact with the swinging object.

A resistive microfluidic pressure sensor is provided which comprises a first layer comprising a microfluidic channel with a carbon-based conductive liquid and a second layer comprising at least two electrodes, the at least two electrodes being adapted to measure resistance of the carbon-based conductive liquid upon deformation of the microfluidic channel as a result of a change in force applied on a surface of the sensor.

An information terminal is provided with a display device, a position detection unit that detects the position of a portion receiving a tactile force sense, an information processing unit that changes content according to the detected position and calculates the tactile force sense on the basis of the changed content, and a tactile force sense providing device. The tactile force sense providing device includes a fitting member including an operation input unit, a conveyance member that conveys a force via the fitting member, a drive unit that produces the force to the conveyance member, and a control unit that provides a tactile force sense by increasing or reducing an initial force, and outputs a signal to the information processing unit according to input from the operation input unit by a user. The information processing unit changes content according to the signal from the control unit.

A system includes a glove, sensors, actuator assemblies, and controller. The sensors include load sensors which measure an actual grasping force and attitude sensors which determine a glove attitude. The actuator assembly provides a grasp assist force to the glove. Respective locations of work cells in the work environment and permitted work tasks for each work cell are programmed into the controller. The controller detects the glove location and attitude. A work task is selected by the controller for the location. The controller calculates a required grasp assist force using measured actual grasping forces from the load sensors. The required grasp assist force is applied via the glove using the actuator assembly to thereby assist the operator in performing the identified work task.

A pulse generator is programmed to generate electrical stimulation to target a sacral nerve or a pudendal nerve of the patient. The electrical stimulation being delivered at least in part via a lead. The electrical stimulation is applied by ramping up a stimulation parameter over time. A first, a second, and a third physiological response are detected from the patient as a result of the electrical stimulation. A first value, a second value, and a third value of the stimulation parameter associated with the first, second, and third physiological response are measured, respectively. A placement of the lead inside the patient is evaluated based on at least one of: a chronological sequence in which the first, second, and third physiological responses occurred, a comparison of the first value with a predetermined threshold, or respective deviations of the second value or the third value from the first value.