Abstract: Systems, methods, apparatus, computer program code and means are provided for bulk costing using an application server which receives a bulk costing request from a remote user device, the bulk costing request including a list of items to be costed and a set of input variables. A final list of components and assemblies is generated including a scenario for each item to be costed for each combination of input variables. A deep costing analysis is performed of the final list, resulting in an estimated cost for each of the items to be costed for each of the input variables.

Abstract: Systems, methods, apparatus, computer program code and means are provided for bulk costing using an application server which receives a bulk costing request from a remote user device, the bulk costing request including a list of items to be costed and a set of input variables. A final list of components and assemblies is generated including a scenario for each item to be costed for each combination of input variables. A deep costing analysis is performed of the final list, resulting in an estimated cost for each of the items to be costed for each of the input variables.

Abstract: A communication device (CD) exchanges messages with an implantable infusion pump via telemetry such that commands are supplied thereto and operational information is obtained therefrom. The CD is controlled, at least in part, by a processor IC according to a software program operating therein and provides feedback to a user via a visual display, an audio alarm, and a vibrational alarm, and allows input from the user via a touch sensitive keypad. Certain input functions are restricted by password. The visual display includes an icon and fixed element display region and a bitmap display region. The fixed element display region includes time and date displays, battery and drug level displays that decrement, and a moving delivery state display. Various screens allow operational or log information to be displayed and/or user entry of commands. Program features when disabled are removed from a series of screen options that can be scrolled through.

Abstract: An implantable pulse generator includes a current steering capability that allows a clinician or patient to quickly determine a desired electrode stimulation pattern, including which electrodes of a group of electrodes within an electrode array should receive a stimulation current, including the amplitude, width and pulse repetition rate of such current. Movement of the selected group of electrodes is facilitated through the use of remotely generated directional signals, generated by a pointing device, such as a joystick. As movement of the selected group of electrodes occurs, current redistribution amongst the various electrode contacts takes place. The redistribution of stimulus amplitudes utilizes re-normalization of amplitudes so that the perceptual level remains fairly constant. This prevents the resulting paresthesia from falling below the perceptual threshold or above the comfort threshold.

Abstract: An implantable pulse generator includes a current steering capability that allows a clinician or patient to quickly determine a desired electrode stimulation pattern, including which electrodes of a group of electrodes within an electrode array should receive a stimulation current, including the amplitude, width and pulse repetition rate of such current. Movement of the selected group of electrodes is facilitated through the use of remotely generated directional signals, generated by a pointing device, such as a joystick. As movement of the selected group of electrodes occurs, current redistribution amongst the various electrode contacts takes place. The redistribution of stimulus amplitudes utilizes re-normalization of amplitudes so that the perceptual level remains fairly constant. This prevents the resulting paresthesia from falling below the perceptual threshold or above the comfort threshold.

Abstract: Implantable pulse generators and spinal cord stimulation (SCS) systems are provided. The implantable pulse generator comprises telemetry circuitry configured for wirelessly receiving programming signals from an external programmer, and a plurality of bi-directional current sources configured for being respectively coupled to a plurality of electrodes. The implantable pulse generator further comprises control circuitry configured for directing the bi-directional current sources to output current pulses of a selected amplitude and polarity to the electrodes in accordance with the programming signals. The SCS system may comprise a plurality of electrodes, an external programmer configured for transmitting programming signals, and the afore-described implantable pulse generator as described above.

Abstract: A spinal cord stimulation (SCS) system includes multiple electrodes, multiple, independently programmable, stimulation channels within an implantable pulse generator (IPG) which channels can provide concurrent, but unique stimulation fields, permitting virtual electrodes to be realized. The SCS system includes a replenishable power source (e.g., rechargeable battery), that may be recharged using transcutaneous power transmissions between antenna coil pairs. An external charger unit, having its own rechargeable battery can be used to charge the IPG replenishable power source. A real-time clock can provide an auto-run schedule for daily stimulation. An included bi-directional telemetry link in the system informs the patient or clinician the status of the system, including the state of charge of the IPG battery. Other processing circuitry in the IPG allows electrode impedance measurements to be made. Further circuitry in the external battery charger can provide alignment detection for the coil pairs.

Abstract: An implantable medical device, such as an implantable pulse generator (IPG) used with a spinal cord stimulation (SCS) system, includes a rechargeable lithium-ion battery having an anode electrode with a substrate made substantially from titanium. Such battery construction allows the rechargeable battery to be discharged down to zero volts without damage to the battery. The implantable medical device includes battery charging and protection circuitry that controls the charging of the battery so as to assure its reliable and safe operation.

Abstract: A device for brain stimulation includes a lead having a longitudinal surface; at least one stimulation electrode disposed along the longitudinal surface of the lead; at least one recording electrode, separate from the at least one stimulation electrode, disposed on the lead; and an implantable pulse generator coupled to the at least one stimulation electrode. In some instances, the implantable pulse generator can be implanted into a burr hole in the skull made for insertion of the lead into the brain.

Abstract: A device for brain stimulation that includes a lead having a longitudinal surface; at least one stimulation electrode disposed along the longitudinal surface of the lead; and at least one recording electrode, separate from the at least one stimulation electrode, disposed along the longitudinal surface of the lead.

Abstract: A method and system to add functionality to digital video recorders (DVRs). In its various embodiments the present system has multiple functions: Increase response to TV commercials and product placements; selection of the power-on station thus benefiting a network or networks and/or a major marketer, Utilizing the infrastructure of the DVR and DVR hand-held remote to facilitate user response to commercials and product placements on DVD's other non-broadcast electronically transferred content, including but not limited to downloaded shows and movies, print ads, catalogs and other indicators of available products, enhancing interaction with vendor/advertisers. The present invention works with digital video recorders and other devices that process and pass real-time television broadcasts, delayed replays of broadcasts, recorded broadcasts, non-broadcast electronically transferred content and DVD's to television monitors.

Abstract: A method of stacking dice in an electronic circuit includes controlling a size of a hole made in a connection pad on each die of said dice to selectively provide an electrical connection to a particular die in the stack. Additionally, a method of stacking dice in an electronic circuit includes forming holes in each of the dice, and providing electrical connection material selectively at some of the holes to provide for selective electrical connections among the dice. A stack of dice in an electronic circuit includes a number of dice stacked on top of each other, each die in the stack having one or more holes therein, conductive material extending through the holes and making electrical connection between one or more of the dice in the stack and the electronic circuit.

Abstract: A spinal cord stimulation (SCS) system includes multiple electrodes, multiple, independently programmable, stimulation channels within an implantable pulse generator (IPG) which channels can provide concurrent, but unique stimulation fields, permitting virtual electrodes to be realized. The SCS system includes a replenishable power source (e.g., rechargeable battery), that may be recharged using transcutaneous power transmissions between antenna coil pairs. An external charger unit, having its own rechargeable battery can be used to charge the IPG replenishable power source. A real-time clock can provide an auto-run schedule for daily stimulation. An included bi-directional telemetry link in the system informs the patient or clinician the status of the system, including the state of charge of the IPG battery. Other processing circuitry in the IPG allows electrode impedance measurements to be made. Further circuitry in the external battery charger can provide alignment detection for the coil pairs.

Abstract: An adapter is used to convert a stand-alone, percutaneous (axial) lead to a planar lead. The adapter has at least one channel for accepting at least one percutaneous lead within the at least one channel and capturing the lead, thereby transforming the stand-alone, percutaneous lead into a functional planar lead.

Abstract: A deep brain stimulation (DBS) system (10) provides a multiplicity of stimulation channels through which electrical stimuli may be delivered deep within the brain of a patient. The DBS system is powered by a rechargeable battery (27). In one embodiment, the system has four channels driving sixteen electrodes (32). The DBS system is easily programmed for use by a clinician using a clinician programming system (60), and further affords a simple but highly advanced hand held programmer (50) control interface through which the patient may easily change stimulation parameters within acceptable limits. The DBS system (10) includes a small, implantable pulse generator (20) that is small enough to be implanted directly in the cranium of the patient, thereby eliminating the long lead wires and tunneling procedures that have been used in the past. The implantable pulse generator provides electrical stimuli in an open-loop fashion as defined by the stimulation parameters.

Abstract: A spinal cord stimulation (SCS) system provides multiple stimulation channels, each capable of producing up to 10 mA of current into a 1 K&OHgr; load. The SCS system further includes a replenishable power source, e.g., a rechargeable battery, that requires only an occasional recharge, and offers a life of at least 10 years at typical settings. Each of the multiple stimulus channels of the system may be combined with other channels to deliver more than 10 mA of current. Additionally, the SCS system has the capability to stimulate simultaneously on all available channels. Each channel has at least two outputs (one positive and one negative) that can be mapped via a low impedance switching matrix to any electrode contact or the system case, thereby allowing a clinician to provide unique electrical stimulation fields for each current channel. Moreover, this feature, combined with multi-contact electrodes arranged in two or three dimensional arrays, allows “virtual electrodes” to be realized.

Abstract: This invention relates to a strain of Bacillus thuringiensis M200, a sample of which has been deposited under the accession number NCIMB 40385, or a variant, derivative or mutant thereof having entomocidal activity against lepidopterous pests. The invention also relates to the use of the said strain for control of insect pests.

Abstract: This invention relates to a strain of Bacillus thuringiensis M200, a sample of which has been deposited under the accession number NCIMB 40385, or a variant, derivative or mutant thereof having entomocidal activity against lepidopterous pests. The invention also relates to the use of the said strain for control of insect pests.

Abstract: An implantable microminiature stimulator and/or sensor (microdevice) is housed within a sealed housing that includes all the requisite electronic circuitry for inductively receiving power and control signals to sense of biopotential or other biomedical signals and/or to generate electrical stimulation pulse(s) between opposing electrodes. In a preferred embodiment, the housing of the microdevice is tubular, with opposing electrodes extending from each end. The electrodes are self-attaching electrodes that attach to a nerve or muscle without suturing. The electrodes are configured to helically curl around the desired nerve, thereby permitting the microdevice to stimulate the nerve or muscle, or sense signals associated with the nerve or muscle, using a minimal amount of energy.