Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An implantable apparatus and method are provided for use in conjunction with an implantable neurostimulation signal generator that provides an electrical stimulation signal to an active electrode. In auditory stimulation applications, the apparatus includes at least one anchor member having a distal end portion for directly contacting a patient's cranial bone and an electrically conductive portion extending from the distal end portion to a contact location proximal to the distal end portion. An electrical connection line may be electrically interconnected at a first end to the contact location of the anchor member and electrically interconnected at a second end to an implantable auditory neurostimulation signal generator to define a reference electrode. A bracket member may be mounted to a patient's cranial bone utilizing the anchor member, wherein an electrically conductive pathway extends from a first contact location to a second contact location of the bracket member.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: A tissue stimulation assembly, including an elongate electrode assembly having a longitudinal axis and including a contact electrode, the contact electrode including a contact surface, wherein at least a portion of the contact surface has a width that gradually increases as the contact surface progresses in a lateral direction.

Abstract: An implantable neurostimulation electrode interface and related system arrangements and methods are provided. The implantable interface may include at least a first stimulation signal channel for receiving a first electrode stimulation signal and a plurality of electrode signal channels electrically interconnected or interconnectable to a plurality of electrodes for neurostimulation. The interface may further include a router electrically interconnected to the first stimulation signal channel and to the plurality of electrode signal channels. The router is controllable to directly route the first electrode stimulation signal to different first successive sets of one or more of the plurality of electrode signal channels. The router may be adapted for routing the first electrode stimulation signal as an electrical current signal, without modification of the signal. Stimulation signal generation componentry and power source componentry may be located remotely from the implantable interface.

Abstract: An improved implantable auditory stimulation system includes two or more implanted microphones for transcutaneous detection of acoustic signals. Each of the implanted microphones provides an output signal. The microphone output signals may be combinatively utilized by an implanted processor to generate a signal for driving an implanted auditory stimulation device. The implanted microphones may be located at offset subcutaneous locations and/or may be provided with different design sensitivities, wherein combinative processing of the microphone output signals may yield an improved drive signal. In one embodiment, the microphone signal may be processed for beamforming and/or directionality purposes.

Abstract: An implantable neurostimulation electrode array may include a flexible, electrically non-conductive carrier, and a plurality of electrodes supportably interconnected to and spaced along a length of a carrier. In various embodiments, different ones of at least some of the plurality of electrodes may comprise corresponding contact surfaces having different areas. The different surface areas may be achieved by defining a different area per unit length of the carrier and/or by defining a different total length (e.g. as measured along a length of the carrier). In some embodiments, insulator portions having different corresponding lengths may be disposed between different adjacent ones of the electrodes. The insulated portions may be integrally defined with the carrier. Electrical connection lines may be embedded within the carrier. In a manufacturing method, a plurality of electrodes may be supportably interconnected to a first side of a sacrificial substrate and a carrier may be interconnected to the electrodes.

Abstract: An implantable apparatus and method are provided for use in conjunction with an implantable neurostimulation signal generator that provides an electrical stimulation signal to an active electrode. In auditory stimulation applications, the apparatus includes at least one anchor member having a distal end portion for directly contacting a patient's cranial bone and an electrically conductive portion extending from the distal end portion to a contact location proximal to the distal end portion. An electrical connection line may be electrically interconnected at a first end to the contact location of the anchor member and electrically interconnected at a second end to an implantable auditory neurostimulation signal generator to define a reference electrode. A bracket member may be mounted to a patient's cranial bone utilizing the anchor member, wherein an electrically conductive pathway extends from a first contact location to a second contact location of the bracket member.

Abstract: A system for reducing subcutaneous migration of an implantable device or housing relative to surrounding soft tissue. For instance, the implantable housing may support a microphone diaphragm. The system includes at least one securement member having at least one aperture extending therethrough that may selectively receive one of a soft tissue securement device (e.g., soft tissue suture) and soft tissue growth therethrough. The securement member is at least one of interconnected to and disposable over at least a portion of the housing and at least one of extends away from and is selectively extendable away from a periphery of the housing. In one arrangement, at least one mesh member may be optionally included with the system that may allow for tissue growth to enhance securement of the implanted device relative to the soft tissue.

Abstract: An implantable neurostimulation electrode interface and related system arrangements and methods are provided. The implantable interface may include at least a first stimulation signal channel for receiving a first electrode stimulation signal and a plurality of electrode signal channels electrically interconnected or interconnectable to a plurality of electrodes for neurostimulation. The interface may further include a router electrically interconnected to the first stimulation signal channel and to the plurality of electrode signal channels. The router is controllable to directly route the first electrode stimulation signal to different first successive sets of one or more of the plurality of electrode signal channels. The router may be adapted for routing the first electrode stimulation signal as an electrical current signal, without modification of the signal. Stimulation signal generation componentry and power source componentry may be located remotely from the implantable interface.

Abstract: An improved implantable hearing instrument and associated method utilize a transducer to mechanically stimulate a patient's cochlea (e.g. via the round window or oval window) in response to a first electrical drive signal, and a supply electrode to electrically stimulate the patient's cochlea in response to a second drive signal. The first and second drive signals may be provided to affect mechanical stimulation across a first predetermined frequency range and electrical stimulation across a second predetermined frequency range, respectively, wherein the predetermined frequency ranges are at least partially non-overlapping. In one embodiment an electromechanical transducer, having the supply member supportably interconnect thereto, may be selectively positioned via a mounting member fixedly interconnected to a patient's skull. The supply electrode may define a distal tip that is supportably interconnected to a vibratory member of the electromechanical transducer.

Abstract: Method for obtaining diagnostic information utilizing an electrical signal output from an implantable transducer. According to one aspect of the invention, a method includes the steps of vibrating an ossicular bone of a patient having an implanted transducer using an input provided over a biological conduction path. The method further includes sensing in the implanted transducer an initial movement of the ossicular bone caused by the input and obtaining an electrical signal output from the implanted transducer generated in response to sensing the initial movement. The electrical signal output is then utilized to determine the diagnostic information.

Abstract: An improved implantable medical device and junction between a blood conduit and a blood vessel are disclosed. The device of the present invention provides a connection to a blood vessel that is resistant to occlusion. Resistance to occlusion is achieved by providing an implantable medical junction with: improved and consistent anastomotic geometry and hemodynamics to minimize turbulence and inappropriate shear stresses on the native blood vessels; intraluminal configuration that does not require penetration through to the luminal surface of the blood vessel or the device for anchoring; protection of the native blood vessel from the forces of blood flow in the impact zone and beyond the impact zone; and isolation of injured and traumatized tissues from the lumen of the blood vessel and the device. A cuff is also provided at the junction to reduce blood leakage from the native blood vessel, and to provide additional device anchoring.