Message: EUROPEAN DEVELOPMENT OF BIONICS VESTIBULAR IMPLANT FOR BILATERAL VESTIBULAR DYSFUNCTION Fact SheetReportingResults Project Information BionicVEST Grant agreement ID: 801127 Project website Opens in new window Status Ongoing project Start date 1 September 2018 End date 31 August 2022 Funded under H2020-EU.1.2.1. Overall budget € 2 899 690 EU contribution € 2 899 690 Coordinated by SERVICIO CANARIO DE LA SALUD Spain Objective Vertigo of vestibular origin has a global prevalence of 38% in the elderly and deserves special attention because of the high risk of falls and permanent functional disability, and even death. This seriously handicaps their lives, disabling them of doing routine daily activities, such as driving and even walking. The associated total costs are around 60.000 million euros in Europe. It is estimated that at least 100 million people worldwide could benefit from a vestibular implant as an effective solution to this disease. Restoring the function of the vestibular labyrinths was not possible until now. Current devices, under research, detect change in angular velocity of the cephalic movements through gyroscopes and use this information to stimulate the semicircular canals. However, they do not code vertical and horizontal accelerations, used to sense gravitational forces, keep a stand up position and restore the sense of self-position. Linear accelerations are detected by a different set of structures which are a more complex and harder to access: the saccule and utricle. This project will develop the first system to electrically reproduce linear accelerations in the otolith organ by stimulating their neural ends. The project will have three phases: Device design, fabrication and clinical trial. Therefore, the objectives will be: 1) to study, for the first time, vestibular pathways through electrical saccule-utricle stimulation; 2) to develop a vestibular response telemetry system to analyse the evoked action potential of vestibular nerve; 3) to design, manufacture and test the first vestibular prosthesis that restores the sense of linear accelerations. The main objectives are to demonstrate the safety of a vestibular implant for human, to determine its efficacy in restoring vestibular function by measuring the improvement in objective and to objectify the improvement in Quality of Life of patients. Novel Telemetry System for Closed Loop Vestibular Prosthesis Cirmirakis, D; (2013) Novel Telemetry System for Closed Loop Vestibular Prosthesis (Cirmirakis, D, Trans.). Doctoral thesis , UCL (University College London). Full text not available from this repository. Abstract Disorders of the vestibular system result in loss of body balance and a steady vision in humans and animals. The most common consequences include vertigo, oscillopsia, postural instability and blurred vision. Currently, conventional medicine cannot cure the damage or restore the function of the vestibular system. Vestibular prosthesis may assist in restoring its function using electrical stimulation, which involves delivering current pulses into the nerves innervating the semi-circular canals in the inner ear. A vestibular prosthesis contains external electronics and an implantable medical device . The system delivers modulated electrical pulses and stimulates vestibular nerves with these pulses to inform the brain about the motion. Power transfer to, and communication with the implanted device, is provided by telemetry. In biomedical implanted devices the telemetry is usually implemented by radio-frequency induction using weakly coupled coils. Using a single set of coils for simulta neous power transfer and communication creates the challenge of contradicting requirements. For high data rates the inductive link must have a wide bandwidth but power transfer requires a low bandwidth. Moreover by modulating a carrier the power transfer is degraded. This thesis describes the design, implementation and experimental evaluation of a novel telemetry system for a three-dimensional vestibular prosthesis with neural recording. The developed telemetry system uses a single pair of inductively-coupled coils to power-up the implant and maintain bi-directional communication to control its operation. It also relays raw electroneurogram (ENG) data out of the body at high speed. For inductive power control two methods are combined: a geometrical approach and a feedback loop to maintain a constant level of delivered power. The communication to the implant (downlink) is obtained by amplitude modulation while the communication from the implant to the external transmitter (uplink) us es passive phase shift modulation. On-chip humidity sensing capabilities are facilitated in the implant microelectronics to monitor hermeticity of the package. The uplink achieves the highest data speed demonstrated in the literature of available methods using a single set of coils with combined power and communication links. The developed technique can be applied to other applications including RFID. |
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