A neural stimulator, suitable for implanting in a recipient, and configured to combine vagal nerve stimulation (VNS) with cochlear stimulation, to result in faster adaptation to new sounds and maps, and alleviation of tinnitus in the recipient.

Presented herein are techniques for initiating a night-time mode of operation in an implantable hearing prosthesis in response to detection of night-time recharging operations. More specifically, an implantable hearing prosthesis comprises a rechargeable battery that is configured to be recharged via an external night-time charging device, such as a pillow charger. The implantable hearing prosthesis is configured to detect inductive charging of the rechargeable battery by the external night-time charging device. In response, the implantable hearing prosthesis is switched to a night-time mode of operation.

Disclosed herein are methods, systems, and apparatus for treating a medical condition in a patient using an implantable medical device (IMD). The IMD is capable of generating a first electrical signal for treating a medical condition, for example epilepsy. The first electrical signal relates to a long term therapy during a first time period in which there is no indication that the patient's brain is in an stable state, the first electrical signal being a microburst stimulation signal. The implantable device is also capable of generating a second electrical signal for treating the medical condition. The second electrical signal relates to a short term therapy during a second time period, in response to an indication that the patient's brain is in an unstable state. The second electrical signal in one example, may be a conventional stimulation signal.

A system and method for enhancing sensory function of an individual are disclosed. The system comprises a generalized brain-skin interface (GBSI), configured to enable the individual to experience senses. The system further comprises a sensor, a processor, and an epidermal neuro-oscillating patch (ENOP). The sensor is configured to receive environmental data surrounding the individual. The processor in communication with the sensor is configured to receive environmental data from the sensor and convert it into an analog vibration pattern. The epidermal neuro-oscillating patch (ENOP) is removably fastened to the skin of the individual, configured to produce a sequence of vibrations based on the analog vibration pattern received from the processor and directly transmit it to the skin for stimulating the nerves of the individual, thereby effectively training the brain of the individual to learn and equate the sequence of vibrations for experiencing senses of the physical environment of the individual.

The present disclosure relates to methods, devices and systems used for the treatment of medical disorders via stimulation of the superficial elements of the trigeminal nerve. More specifically, cutaneous methods of stimulation of the superficial branches of the trigeminal nerve located extracranially in the face, namely the supraorbital, supratrochlear, infraorbital, auriculotemporal, zygomaticotemporal, zygomaticoorbital, zygomaticofacial, infraorbital, nasal and mentalis nerves (also referred to collectively as the superficial trigeminal nerve) are disclosed herein.

Methods and systems are provided for a sound device for making or treatment of tinnitus. In one example, a method includes determining a current sleep cycle and administering a therapy sound based on the current sleep cycle.

Timed stimulation of both somatosensory system and auditory system is controlled, in such a manner, that an individual's brain activity is altered through spike-timing dependent plasticity, thereby reducing or removing tinnitus.

Presented herein are techniques for initiating a night-time mode of operation in an implantable hearing prosthesis in response to detection of night-time recharging operations. More specifically, an implantable hearing prosthesis comprises a rechargeable battery that is configured to be recharged via an external night-time charging device, such as a pillow charger. The implantable hearing prosthesis is configured to detect inductive charging of the rechargeable battery by the external night-time charging device. In response, the implantable hearing prosthesis is switched to a night-time mode of operation.

The present application relates to a new stimulation design which can be utilized to treat neurological conditions. The stimulation system produces a burst mode stimulation which alters the neuronal activity of the predetermined site, thereby treating the neurological condition or disorder. The burst stimulus comprises a plurality of groups of spike pulses having a maximum inter-spike interval of 100 milliseconds. The burst stimulus is separated by a substantially quiescent period of time between the plurality of groups of spike pulses. This inter-group interval may comprise a minimum of 5 seconds.

An apparatus for use in treating a neurological disorder of the auditory system, comprising a stimulus generation unit and a somatosensory stimulation unit; the stimulus generation unit operable to analyse an audio signal, said audio signal comprising a first component comprising a broadband or white noise component and a second component comprising a plurality of complex tone bursts, and generate a plurality of actuation signals representative of at least one of the first or second component of said audio signal and further to spectrally modify said audio signal to generate a binaural modified audio signal for delivery to a subject; and wherein said somatosensory stimulation unit comprises: an array of stimulators each of which can be independently actuated to apply a somatosensory stimulation to the subject with the modified audio signal, and an input for receiving the plurality of actuation signals from said stimulus generation unit and directing individual actuation signals in a predetermined pattern to individual stimulators in the array, the stimulus generation unit being further configured to introduce a delay between the plurality of actuation signals representative of said audio signal and the binaural modified audio signal.