Abstract: A surgical cutting blade for use in an electrosurgical scalpel includes a thin flat ceramic substrate having a rounded tip where the edge portion of the substrate on the opposed major surfaces thereof are beveled. A pattern of metallization is provided on the opposed major surfaces of the blade substrate with the metallization extending over the tapered portions. The substrate is then back-ground to form a blunt edge extending between the tapered surfaces at the edge of the substrate. The metallization pattern further includes traces extending from the conductors along the blunt working edge of the blade to the handle receiving portion thereof and provide a means whereby RF energy may be conducted to the metallized working edge of the blade.

Abstract: A reverse number identification system is described which allows the called party in a telephone link to identify the telephone directory number of the calling party. This system includes a first system component located at the customer's premises which includes a display for the calling party's directory number. A second system component includes equipment connected to the calling party's telephone line located in the calling party's central office which transmits upon request the directory number of the calling party to the first system component. Each subscriber's telephone line in the central office has a microprocessor controlled transceiver placed between the incoming subscriber's telephone line and the central office switching equipment. Each subscriber's premises includes a first system component designed to receive and display the calling party's telephone number. In operation, the calling party dials the directory number of the called party and the called party responds by answering.

Abstract: An electrosurgical generator for driving one or more separate electrosurgical implements, e.g., an electrosurgical scalpel and an electrosurgical forceps, over separate output channels. Bipolar electrodes on the scalpel blade are energized by a radio frequency (rf) power source which, by proper manipulation of push-button switches on the scalpel handle, can be made to operate selectively in a CUT and in a COAG (coagulate) mode. In the CUT mode, the rf energy is applied to the tissue, via electrodes which are closely spaced, yielding a high current density. In the COAG mode, the energy is applied to electrodes which are spaced relatively far apart so as to produce heating sufficient to cauterize, but not to the point where the tissue is rent. The generator also provides circuitry for energizing an ultrasonic transducer mechanically coupled to one of the surgical implements whereby vibratory energy is simultaneously applied to the implement along with the rf CUT/COAG energy.

Abstract: A surgical cutting blade for use in an electrosurgical scalpel includes a thin flat ceramic substrate having a rounded tip where the edge portion of the substrate on the opposed major surfaces thereof are beveled. A pattern of metallization is provided on the opposed major surfaces of the blade substrate with the metallization extending over the tapered portions. The substrate is then back-ground to form a blunt edge extending between the tapered surfaces at the edge of the substrate. The metallization pattern further includes traces extending from the conductors along the blunt working edge of the blade to the handle receiving portion thereof and provide a means whereby RF energy may be conducted to the metallized working edge of the blade.

Abstract: An electrosurgical blade having a silicon nitride ceramic substrate having a beveled working edge with first and second conductive metal traces adhered to opposed side surfaces of the substrate along the working edge so as to be closely spaced relative to one another across the thickness dimension of the beveled working edge. Further conductive traces are formed on opposed sides of the substrate along the other edge of the substrate. In use, when a high RF voltage is applied between the traces extending along the working edge and the surgical blade is brought into contact with tissue, the relatively high current density causes relatively high heating to take place, bursting the cells and creating an incision. When a high RF voltage is applied between the traces separated by the width dimension of the substrate, the current density therebetween is significantly lower but sufficient to create enough heat to dehydrate tissue and blood cells whereby coagulation is achieved.