A system and associated method for computerized rotational head impulse test (crHIT) to assess the semicircular canals of the human vestibular system clinically in patients with balance disorders. The system utilizes a rotary chair combined with a head mounted VOG system with head tracking sensors. The crHIT protocol uses the same physiologic principles as the known video head impulse test (vHIT). The crHIT utilizes whole-body rotation via the chair to yield a persistent controlled, repeatable, comfortable, reliable stimulus can be delivered while recording eye movements with video-oculogaphy.

The invention provides a method and system for navigating a user based on a type of maneuver for correction of a vestibular condition. The method and system collects sensor data regarding orientation of head and body of a person for creating a three-dimensional model of the person. The method and system then generates a sequence of steps corresponding to the type of maneuver along with an instruction set and a time duration for performing each step of the sequence of steps, thus enabling the user to perform each step of the sequence of steps corresponding to the type of maneuver, on the person for correcting the vestibular condition.

A vestibular electrode is described that is for implantation into a vestibular semi-circular canal. An intra-labyrinthine electrode carrier with a C-shaped cross-section has an inner concave surface and an outer convex surface, and is configured to fit through an electrode opening in an outer surface of the bony labyrinth into the perilymph fluid without breaking the membranous labyrinth so as to fit the inner concave surface of the electrode carrier adjacent to the membranous labyrinth and the outer convex surface adjacent to the bony labyrinth. There are one or more electrode contacts on a surface of the electrode carrier that are configured for electrical interaction with adjacent neural tissue.

Apparatus and methods are described herein that provide a vibratory device that can apply a vibratory signal to a portion of a head of a user such that the vibratory signal can be conducted via bone to a vestibular system of the user and cause a portion of the vestibular system to move in a manner equivalent to that of a therapeutically effective vibratory signal applied to an area overlaying a mastoid bone of the user. The vibratory device can be associated with frequencies less than 200 Hz. The vibratory device can be effective at treating a physiological condition associated with the vestibular system.

A system is disclosed for configuring a hearing device. The system includes an audiogram processing component arranged to process image data indicative of an image of an audiogram associated with a person so as to produce audiogram data indicative of the audiogram, and a hearing device configuration component arranged to produce hearing device configuration data based on the audiogram data. The configuration data is indicative of configuration settings for a hearing device that will cause the hearing device to assist the hearing of the person.

In one embodiment, one or more suspension systems of a vehicle may be used to mitigate motion sickness by limiting motion in one or more frequency ranges. In another embodiment, an active suspension may be integrated with an autonomous vehicle architecture. In yet another embodiment, the active suspension system of a vehicle may be used to induce motion in a vehicle. The vehicle may be used as a testbed for technical investigations and/or as a platform to enhance the enjoyment of video and/or audio by vehicle occupants. In some embodiments, the active suspensions system may be used to perform gestures as a means of communication with persons inside or outside the vehicle. In some embodiments, the active suspensions system may be used to generate haptic warnings to a vehicle operator or other persons in response to certain road situations.

A method of assessing the balance impairment of a subject includes the steps of presenting the subject with a static scene on a display, collecting a first set of orientation measurements, presenting the subject with an unstable scene on a display, collecting a second set of orientation measurements, storing the first and second sets of orientation measurements on a computing device, referenced to a set of time indices, and calculating a balance score for the subject by comparing the second set of orientation measurements with the first set of orientation measurements. A system for assessing the balance impairment of a subject is also disclosed.

In an infrared camera configuration, a modular goggle assembly can diagnose patients having vestibular dysfunction, concussion, or other maladies observable with an examination of the eyes. In a virtual reality display configuration, the assembly can be used to provide treatment to patients once the cause of the illness or malady is determined. The assembly is lightproof, mobile, and easily configurable.

Methods and systems relate to determining sensory motor performance based on user non-postural movements within a generated dynamic virtual environment. The generated environment requires users to: (i) utilize primary sensor inputs (e.g., vision, vestibular sensation and somatosensation); (ii) assess the dynamic virtual environment; and (iii) integrate and translate those inputs into movement to control the dynamic virtual environment. The methods may include receiving non-postural user input with respect to a state of one or more attributes of a dynamic virtual environment provided on a user interface for one or more sessions, the one or more attributes including a control object and a target which moves with respect to the control object; determining performance information based on the user input and the state of the one or more attributes for the one or more sessions; and determining sensory motor performance information from the performance information.

A multi-axis measurement device for loading force and center of gravity is provided comprising a first loading plate, and comprising: a first slidable element and a first piezoelectric pressure sensing element. A second loading plate comprising: a second slidable element and a second piezoelectric pressure sensing element. A connecting plate, respectively connects to the first slidable element, the first piezoelectric pressure sensing element, the second slidable element, and the second piezoelectric pressure sensing element. A plurality of third piezoelectric pressure sensing elements connects to the first loading plate. The first piezoelectric pressure sensing element measures the changes in force of the X-axis direction, the second piezoelectric pressure sensor element sensing element measures the changes in force of the Y-axis direction, and the third piezoelectric pressure sensor element sensing elements measure the changes in force of the Z-axis direction.