Abstract: A process for identifying and treating cells in a living organism. The cells are labeled, circulated within the organism, detected with an implanted detector, and then either isolated or ablated.

Abstract: An electromagnetic immune tissue invasive system includes a primary device housing. The primary device housing having a control circuit therein. A shielding is formed around the primary device housing to shield the primary device housing and any circuits therein from electromagnetic interference. A lead system transmits and receives signals between the primary device housing. The lead system is either a fiber optic system or an electrically shielded electrical lead system.

Abstract: An electromagnetic shield has a first patterned or apertured layer having non-conductive materials and conductive material and a second patterned or apertured layer having non-conductive materials and conductive material. The conductive material may be a metal, a carbon composite, or a polymer composite. The non-conductive materials in the first patterned or apertured layer may be randomly located or located in a predetermined segmented pattern such that the non-conductive materials in the first patterned or apertured layer are located in a predetermined segmented pattern with respect to locations of the non-conductive materials in the second patterned or apertured layer.

Abstract: An electromagnetic shield has a first patterned or apertured layer having non-conductive materials and conductive material and a second patterned or apertured layer having non-conductive materials and conductive material. The conductive material may be a metal, a carbon composite, or a polymer composite. The non-conductive materials in the first patterned or apertured layer may be randomly located or located in a predetermined segmented pattern such that the non-conductive materials in the first patterned or apertured layer are located in a predetermined segmented pattern with respect to locations of the non-conductive materials in the second patterned or apertured layer.

Abstract: An electromagnetic shield has a first patterned or apertured layer having non-conductive materials and conductive material and a second patterned or apertured layer having non-conductive materials and conductive material. The conductive material may be a metal, a carbon composite, or a polymer composite. The non-conductive materials in the first patterned or apertured layer may be randomly located or located in a predetermined segmented pattern such that the non-conductive materials in the first patterned or apertured layer are located in a predetermined segmented pattern with respect to locations of the non-conductive materials in the second patterned or apertured layer.

Abstract: An electromagnetic shield has a first patterned or apertured layer having non-conductive materials and conductive material and a second patterned or apertured layer having non-conductive materials and conductive material. The conductive material may be a metal, a carbon composite, or a polymer composite. The non-conductive materials in the first patterned or apertured layer may be randomly located or located in a predetermined segmented pattern such that the non-conductive materials in the first patterned or apertured layer are located in a predetermined segmented pattern with respect to locations of the non-conductive materials in the second patterned or apertured layer.

Abstract: An electromagnetic shield has a first patterned or apertured layer having non-conductive materials and conductive material and a second patterned or apertured layer having non-conductive materials and conductive material. The conductive material may be a metal, a carbon composite, or a polymer composite. The non-conductive materials in the first patterned or apertured layer may be randomly located or located in a predetermined segmented pattern such that the non-conductive materials in the first patterned or apertured layer are located in a predetermined segmented pattern with respect to locations of the non-conductive materials in the second patterned or apertured layer.

Abstract: Disclosed is an artificial organ comprised of a conduit adapted to be connected to a blood pool, the blood pool comprising a first analyte and a second analyte; a cell culture media comprised of a first cell culture and a second cell culture, each of which are capable of producing the first analyte and said second analyte respectively; and a controller that is capable of measuring a concentration of the first and second analyte in the blood pool, and delivering a specified amount of the first and second analyte from the cell culture media to the blood pool, and delivering a specified amount of the second analyte from the cell culture media to the blood pool.

Abstract: A medical device having electrically conductive properties includes an electrically conductive member. The electrically conductive member has an anti-antenna geometrical shape. The anti-antenna geometrical shaped electrically conductive member is shaped such that currents induced in the anti-antenna geometrical shaped electrically conductive member, by radio frequency fields, offset currents induced in the medical device by the radio frequency fields.

Abstract: A medical device containing a device for connecting the medical device to a substrate, for furnishing electrical impulses from the medical device to the substrate, for ceasing the furnishing of electrical impulses to the substrate, for receiving pulsed radio frequency fields, for transmitting and receiving optical signals, and for protecting the substrate and the medical device from currents induced by the pulsed radio frequency fields. The medical device contains a control circuit comprised of a parallel resonant frequency circuit.

Abstract: An MRI-compatible, fixed-rate (VOO) pacemaker includes a self-contained power source housed at the proximal end of a photonic catheter in a first enclosure. Low energy continuous electrical power is delivered from the power source. This electrical power is converted into light energy and directed into the proximal end of the photonic catheter. The photonic catheter includes an optical conduction pathway over which is formed a covering of biocompatible material. Light entering the proximal end of the photonic catheter is transmitted through the optical conduction pathway, where it is collected and converted back to electrical energy at a second enclosure located at the distal end of the photonic catheter. The second enclosure houses a pulse generator that stores electrical energy and periodically releases that energy to deliver electrical pulses to bipolar heart electrodes.

Abstract: A controllable, wearable MRI-compatible, fixed-rate (VOO) pacemaker includes a self-contained steady state power source and an oscillator housed at the proximal end of a photonic catheter in a first enclosure. Continuous electrical energy is delivered from the power source and electrical pulses are delivered from the oscillator. The continuous electrical energy and electrical pulses are converted into respective continuous and pulsing light energy and directed into the proximal end of the photonic catheter. The photonic catheter includes optical conduction pathways and a covering of biocompatible material. Light entering the proximal end of the photonic catheter is transmitted through the optical conduction pathways, where it is collected and converted back to electrical energy at a second enclosure located at the distal end of the photonic catheter.

Abstract: A controllable, wearable MRI-compatible, fixed-rate (VOO) pacemaker includes a self-contained power source and a pulse generator housed at the proximal end of a photonic catheter in a first enclosure designed to operate externally of a patient's body. Electrical pulses output by the pulse generator are converted into light energy and directed into the proximal end of the photonic catheter. The photonic catheter includes an optical conduction pathway over which is formed a covering of biocompatible material. Light entering the proximal end of the photonic catheter is transmitted through the optical conduction pathway, where it is collected and converted back to electrical energy at a second enclosure located at the distal end of the photonic catheter. The second enclosure houses an opto-electrical transducer that converts the optical pulses to electrical pulses and delivers them to bipolar heart electrodes.

Abstract: An MRI-compatible, fixed-rate (VOO) pacemaker includes a self-contained power source and a pulse generator housed at the proximal end of a photonic catheter in a first enclosure. Electrical pulses output by the pulse generator are converted into light energy and directed into the proximal end of the photonic catheter. The photonic catheter includes an optical conduction pathway over which is formed a covering of biocompatible material. Light entering the proximal end of the photonic catheter is transmitted through the optical conduction pathway, where it is collected and converted back to electrical energy at a second enclosure located at the distal end of the photonic catheter. The second enclosure houses an opto-electrical transducer that converts the optical pulses to electrical pulses and delivers them to bipolar heart electrodes.

Abstract: A fire fighting trainer for use in training fire fighters about a ceiling rollover fire. This trainer includes a chamber with a ceiling and includes a burner head subassembly and includes a burner control subassembly. The burner head subassembly has a fuel gas inlet pipe and an adjacent combustion air inlet pipe to produce an air/gas mixture which creates a flame at the ceiling. The burner control subassembly selectively increases the fuel gas flow to make the produced flame have a ceiling rollover effect.