Abstract: A noninvasive method and system are provided for assessing the performance of implanted actuators of semi or fully-implantable hearing aid systems. The invention utilizes an externally positioned test measurement device to obtain measurements of the electrical impedance of an implanted actuator when driven by a test signal of predetermined characteristics. In one embodiment, the test measurement device may comprise a signal generator for generating the test signal for the actuator, a signal processing unit to compute the electrical impedance from voltage and current measurements, and a user interface to provide an output that is usable to asses the performance of the actuator. The electrical impedance is computable from the voltage and current of the signal passing through the actuator. The electrical impedance is directly related to the mechanical impedance present at the interface between the actuator and middle ear of a patient.

Abstract: A hearing aid and method for stimulating the tympanic membrane of a patient via an input of acoustic signals into the middle ear cavity. The hearing aid includes an acoustic signal receiver, a signal processor, and an implantable transducer. In one aspect of the invention, the impedance of the implantable transducer is matched to a characteristic frequency range of the human tympanic membrane to acoustically couple the transducer with the tympanic membrane. In another aspect of the invention, the impedance of the implantable transducer is matched to a measured impedance of a patient's tympanic membrane to achieve the acoustic coupling. In either case, the acoustic signal receiver receives acoustic sounds and generates frequency response signals for the signal processor. The signal processor, in turn, processes the frequency response signals to generate transducer drive signals for the implanted transducer. The acoustically coupled transducer receives the drive signals to generate acoustic signals, e.g.

Abstract: An electrosurgical electrode having a distal end for transferring the energy to the tissue and a thermal reservoir spaced apart from the distal end. The materials and shape of the electrode promote the flow of heat away from the distal tip so as to reduce the temperature of the tip during electrosurgery, to reduce tissue damage and to prevent the tissue from sticking to the electrode tip. The electrode is composed of a bio-compatible and highly thermally conductive metal, such as silver or gold of high purity, or alloy of those two metals. The shape provides a cross-sectional area that is constant or increasing as the distance from the tip increases. The rounded distal end transitions into a cylindrical section which then transitions into the thermal reservoir. The thermal reservoir is also cylindrical, having a cross-sectional area that is larger than the cross-sectional area of the first cylindrical section.

Abstract: An electrosurgical system is disclosed that applies electrical energy to obtain a predetermined surgical effect, while also reducing eschar deposits on a working surface of an electrosurgical instrument, producing an eschar deposit which is easily removed from the working surface and/or facilitating removal of eschar deposits during a cleaning procedure. Such benefits may be realized by providing a negative bias on the working surface relative to a return path to source during electrosurgical procedures and/or during a cleaning procedure which may include contacting the working surface with an electrically conductive liquid.