Implantable pulse generators using rechargeable zero-volt technology lithium-ion batteries
First Claim
1. An implantable pulse generator (IPG) system for use with a spinal cord stimulation system, the IPG system comprising an implantable pulse generator and an external portable charger, wherein the IPG comprises:
- an hermetically sealed case;
electronically circuitry including memory circuits, housed within said hermetically sealed case, said electronic circuitry including a multiplicity of independent bidirectional output current sources, each output current source being connected to an electrode node;
a multiplicity of coupling capacitors, each coupling capacitor being connected to a respective one of said electrode nodes;
a header connecter attached to said sealed case, the header connecter having a multiplicity of feedthrough pins that pass therethrough, wherein each of said multiplicity of coupling capacitors is connected on the sealed side of said case to one of said feedthrough pins;
an electrode array having a multiplicity of electrodes thereon external to said sealed case, wherein each electrode of the multiplicity of electrodes is detachably electrically connected to one of said feedthrough pins on a nonsealed side of said sealed case;
wherein each output current source generates an output stimulus current having a selected amplitude and polarity that, when the output current source is enabled, is directed to the electrode connected thereto through its respective feedthrough pin and coupling capacitor;
a rechargeable lithium-ion battery adapted to operate over a wide range of voltages ranging from zero volts to a fully-charged voltage, said rechargeable battery having an anode electrode having a substrate made from titanium, said rechargeable battery providing operating power for the electronic circuitry;
a secondary coil;
a rectifier circuit; and
battery charger and protection circuitry that receives externally generated energy through the secondary coil and rectifier circuit, and uses the externally generated energy to charge the rechargeable lithium-ion battery.
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Accused Products
Abstract
An implantable medical device, such as an implantable pulse generator (IPG) used with a spinal cord stimulation (SCS) system, includes a rechargeable lithiumion 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. A multi-rate charge algorithm is employed that minimizes charging time while ensuring the battery cell is safely charged. Fast charging occurs at safer lower battery voltages (e.g., battery voltage above about 2.5 V), and slower charging occurs when the battery nears full charge higher battery voltages (e.g., above about 4.0 V). When potentially less-than-safe very low voltages are encountered (e.g., less than 2.5 V), then very slow (trickle) charging occurs to bring the battery voltage back up to the safer voltage levels where more rapid charging can safely occur. The battery charging and protection circuitry also continuously monitors the battery voltage and current. If the battery operates outside of a predetermined range of voltage or current, the battery protection circuitry disconnects the battery from the particular fault, i.e. charging circuitry or load circuits.
165 Citations
5 Claims
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1. An implantable pulse generator (IPG) system for use with a spinal cord stimulation system, the IPG system comprising an implantable pulse generator and an external portable charger, wherein the IPG comprises:
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an hermetically sealed case;
electronically circuitry including memory circuits, housed within said hermetically sealed case, said electronic circuitry including a multiplicity of independent bidirectional output current sources, each output current source being connected to an electrode node;
a multiplicity of coupling capacitors, each coupling capacitor being connected to a respective one of said electrode nodes;
a header connecter attached to said sealed case, the header connecter having a multiplicity of feedthrough pins that pass therethrough, wherein each of said multiplicity of coupling capacitors is connected on the sealed side of said case to one of said feedthrough pins;
an electrode array having a multiplicity of electrodes thereon external to said sealed case, wherein each electrode of the multiplicity of electrodes is detachably electrically connected to one of said feedthrough pins on a nonsealed side of said sealed case;
wherein each output current source generates an output stimulus current having a selected amplitude and polarity that, when the output current source is enabled, is directed to the electrode connected thereto through its respective feedthrough pin and coupling capacitor;
a rechargeable lithium-ion battery adapted to operate over a wide range of voltages ranging from zero volts to a fully-charged voltage, said rechargeable battery having an anode electrode having a substrate made from titanium, said rechargeable battery providing operating power for the electronic circuitry;
a secondary coil;
a rectifier circuit; and
battery charger and protection circuitry that receives externally generated energy through the secondary coil and rectifier circuit, and uses the externally generated energy to charge the rechargeable lithium-ion battery. - View Dependent Claims (2, 3, 4, 5)
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Specification