The present application relates to remote programming of neurostimulation treatment systems and associated devices, methods and system setups.
Treatments with implantable neurostimulation systems have become increasingly common in recent years. While such systems have shown promise in treating a number of conditions, effectiveness of treatment may vary considerably between patients. A number of factors may lead to the very different patient outcomes; and, viability of treatment may be difficult to determine before implantation. Current stimulation electrode placement/implantation techniques and known treatment setting techniques suffer from significant disadvantages. The nerve tissue structures of different patients may be quite different, with the locations and branching of nerves that perform specific functions and/or enervate specific organs being challenging to accurately predict or identify. The electrical properties of the tissue structures surrounding a target nerve structure may also be quite different among different patients, and the neural response to stimulation may be markedly dissimilar, with an electrical stimulation pulse pattern, pulse width, frequency, and/or amplitude that is effective to affect a body function of one patient and potentially imposing significant discomfort or pain, or having limited effect, on another patient. Even in patients where implantation of a neurostimulation system provides effective treatment, frequent adjustments and changes to the stimulation protocol are often required before a suitable treatment program may be determined, often involving repeated office visits and significant discomfort for the patient before efficacy is achieved. While more recently developed systems have improved upon lead placement and stimulation efficiency to improve consistency in treatment, many patients still require occasional adjustments or changes to the treatment program. Such reprogramming often requires an in-person office visit, and sometimes repeat offices visits. Given that implanted neurostimulation systems utilize specialized local communication (e.g. MedRadio) to communicate with accessory components within the system and the patient lacks the expertise or permissions to adjust or modify therapy, this presents significant barriers to programming an implanted system without requiring in-person visit with a clinician or system technician. The design of current therapy systems simply do not lend themselves to control or programming remotely. These challenges present significant obstacles to maintaining long-term efficacious treatment of patients that live in remote locations or those patients that are elderly or in vulnerable patient populations.
Therefore, it would be desirable to provide improved systems, devices and methods by which an implanted neurostimulation system may be adjusted or reprogrammed remotely by a clinician or technical expert without requiring an in-person visit. It would be further helpful for such methods to facilitate interaction between the patient and clinician to provide the benefits of an in-person visit while still allowing remote programming of the system.
The present application generally relates to remote programming of neurostimulation treatment systems and associated devices and methods. The application has particular application to sacral nerve stimulation treatment systems configured to treat bladder and bowel related dysfunctions. It will be appreciated however that the various exemplary embodiments disclosed herein may also be utilized for the treatment of pain or other indications, such as movement or affective disorders, or various other implanted medical devices, as will be appreciated by one of skill in the art.
Disclosed embodiments relate to methods, user devices, intermediary communication devices and specialized application software that facilitates remote programming of an implanted by a remote device. As discussed above, there is an increasing need for remote programming of implanted medical devices, which allows healthcare workers to remotely connect with patients over a phone or tablet device and to reprogram or troubleshoot their implanted medical device in their body. By use of a specialized intermediary communication devices utilizing various types of communication (e.g. Bluetooth (BT), MedRadio (MR), cellular/WiFi, or any combination thereof), and specialized software applications, a user can utilize existing equipment as well as their personal computing devices to establish a live communication session for programming of their implanted device or troubleshoot their device remotely in manner that is convenient as well as safe and secure for all parties. In some exemplary embodiments, the user can utilize custom devices and/or accessory devices to streamline the system setup and/or to provide additional functionality beyond the capabilities of existing devices or personal devices. In addition, the application discloses various options and system setups that can accommodate a range of available IPG designs (rechargeable and non-rechargeable) with varied communication capabilities. In some exemplary embodiments, the remote programing setup system is designed so as to be backwards compatible with existing device/systems (non-BT enabled IPGs). In other embodiments, the system setup is designed to be forward compatible with next generation remote programming functionality (e.g. IPGs or patient remotes designed with both MR and BT functionality). In still another aspect, the system setup may include a patient database portal by which therapy information may be periodically updated, and can inform the remote programing by the remote device or inform self-programming with the patient device. The patient portal may be web-based and hosted on a secure server and may be accessed by the patient device or the remote programming device. In another aspect, the remote programming system setups described herein may be integrated into a telehealth platform (e.g., Teledoc, VSee, Doxy.me, OhMD, Whereby, Mend, Updox, NextGen Healthcare EHR, etc.). Generally, telehealth platforms encompass the technology infrastructure, services, and support that allows private, secure, HIPAA-compliant, and high-quality virtual medical consultations and treatments remotely. Such telehealth systems may include phone, videoconferences, or text-based communication, typically through a remote communication system, often using the personal device of the patient. Accordingly, the remote programing features described herein may be incorporated into these telehealth platforms so as to leverage existing functionality of these platforms for the purpose of remote programming.
A typical implanted medical device communicates with its peripheral devices (e.g. clinician programmer, patient remote control etc.) through specific frequencies, that are dedicated to medical devices use, such as the Medical Device Radio communications Service (MedRadio) band (e.g. 401-406 MHz, 413-419 MHz, 426-432 MHz, 438-444 MHz, and 451-457 MHz range). In addition, Medical Body Area Networks (MBANs), which are low power networks of sensors worn on the body controlled by a hub device that is located either on the body or in close proximity, operate in the 2360-2400 MHz band. Standard smartphones or tablets are not suited for communication with or programming of implanted medical devices. By use of specialized intermediary devices or updates to existing accessory devices, a live communication session may be established remotely between the implanted medical device, a patient device and a remote device to allow programming.
The intermediary device may communicate with an implanted medical device on one end through the MedRadio band and to a patient's phone or a tablet device, either an iOS or android device, through Bluetooth or low energy Bluetooth on the other end. In some exemplary embodiments, the system utilizes an existing accessory, such as the Patient Remote or Charger, as the intermediary device. In some exemplary embodiments, the specialized intermediary device may be configured to plug into a user's device (e.g., smartphone, tablet, laptop) through its charging port or other ports (e.g., USB-C, USB, etc.). The intermediary device may then be powered and recognized by the user's phone or tablet device. A specialized application (“App”) may be developed and pre-downloaded to the user's device. The user may be the patient, a clinician or patient advocate. The App may be used to make changes to program settings of the implanted device or troubleshoot, by commanding the implanted device to run a diagnosis on its own and report back to the user device. In other embodiments, the specialized device may be a separate device that communicates with the patient device, such as a smartphone or tablet, by radio communications, for example, by Bluetooth or near field communication (“NFC”), and that communicates with the implanted device by MedRadio. In this embodiment, the intermediary device contains a power source and is self-powered. As noted above, a specific App may be developed and pre-downloaded to the user's device to allow changes to program settings or troubleshooting of the implanted device.
A method of remotely programming an implanted neurostimulation system is disclosed herein. The method may include the steps of: receiving, with a remote device, a patient request for programming of an implantable pulse generator of a neurostimulation system implanted in the patient; establishing a communication session between the implantable pulse generator of the neurostimulation system and a remote device associated with a remote support entity through one or more intermediary local devices; receiving program information and patient information with the remote device; determining or receiving, with the remote device, a program update regarding updating of one or more parameters of the current program or a new program to be applied by the implanted neurostimulation system; and programming the implantable pulse generator, with the remote device through the one or more intermediary devices, with the program update. In some exemplary embodiments, the program information includes a current therapy program applied by the implanted neurostimulation system. In some exemplary embodiments, the patient information comprises patient identifying information, objective information and/or subjective information regarding treatment. The objective information may include, but is not limited to, any of: numbers of voids, volume of each void, number of pads, a Visual Analogue Scale (VAS) pain score, a Quality of Life (QoL) score, hours of sleep, and current stimulation therapy parameters. The subjective information may include, but is not limited to, any of: what the patient is feeling, mood changes, and sleep quality.
In some exemplary embodiments, the one or more intermediary local devices includes any of: a charger device, a patient remote, a personal computing device of the patient, a specialized dedicated communication device. In some exemplary embodiments, the one or more intermediary devices includes a first and second intermediary device, the first intermediary device communicates with the implantable pulse generator and the second intermediary device, and the second intermediary device communicates with the first intermediary device and the remote device of the remote support entity. In some exemplary embodiments, the first intermediary device is any of a: charger, a patient remote, a specialized communicator device, and a plug-in accessory into a personal computing device of the patient. The first intermediary device communicates with the implantable pulse generator by a first communication scheme (e.g. MedRadio). The second intermediary device communicates with the first intermediary device by a second communication scheme (e.g. Bluetooth) and can communicate with the remote device by another communication scheme (e.g. through Wifi, cellular, wire connection or any combination thereof).
In some exemplary embodiments, the second intermediary device includes a specialized Patient App specifically configured for facilitating programming. The Patient App may be configured to access or store the program information and communicate to the remote device for programming. In some exemplary embodiments, the Patient App may be configured to access the program information from a data center associated with a first party developer of the implantable pulse generator. In some exemplary embodiments, the Patient App may be configured to access the program information from the implantable pulse generator via the first intermediary device. In some exemplary embodiments, the Patient App is further configured to receive a patient input via a user interface regarding the current therapy program and/or the patient information. The Patient App can further include a bladder and/or voiding diary that stores subjective information regarding efficacy of the current therapy program and which may be accessed by the remote entity during programming. The subjective information may be collected and/or logged periodically within the Patient App over a duration of at least multiple days. In some exemplary embodiments, the Patient App may be configured to conduct a live communication session, such as a live video call, between the patient and a remote device of a remote support entity. The communication between the remote device and the one or more local intermediary devices can utilize any of: a cloud-based server, a local server of the remote entity, a hosted server hosted by a third party. In some exemplary embodiments, the remote entity is associated with a first party developer of the implantable pulse generator and/or a specialized Patient App on the one or more local intermediary devices. In some exemplary embodiments, the remote entity is a third party that is technical consultant, a treating physician, a clinician or a health care provider personnel. In some exemplary embodiments, the Patient App may be configured to be installed on the user's personal portable computing device and is not accessible by an internet browser.
In another aspect, the remote device may include a specialized Remote Programming App operating thereon. The Remote Programming App may be configured to be served to an internet browser and accessed by the remote device. The remote device may be any of a smartphone, tablet, laptop and a desktop computing device. In some exemplary embodiments, the Remote Programming App may be configured for installation and access on a portable computing device associated with the treating clinician or associated health care provider. In some exemplary embodiments, the Remote Programming App may be configured to establish communication with the patient through a back-end associated with a first party developer of the implantable pulse generator. The communication session may include accessing of the patient information and/or the program information from a data center associated with the first party developer of the implantable pulse generator that is accessed through the back-end. In some exemplary embodiments the back-end is cloud based, a local server of the first party, or a hosted server. In some exemplary embodiments, the initial communication is established in response to the remote entity or associated entity receiving a request, initiated by the patient with the second intermediary device, for programming. In some exemplary embodiments, establishing communication comprises exchanging identification information as to the implantable pulse generator, the patient and the remote entity between the second intermediary device and the remote device to ensure secure authenticated communication during the session. In some exemplary embodiments, the remote device has administrative control of the implantable pulse generator during at least part of the communication session that exceeds that of the patient. In some exemplary embodiments, the method includes accessing, with the remote device, multiple recommended neurostimulation programs that includes the current therapy program; and selecting, with the remote device, another of the multiple recommended neurostimulation programs for application as the new updated program. Multiple recommended neurostimulation programs may be stored on any of the implantable pulse generator or in a separate data center and accessed by the remote device using the patient information.
Methods of programming an implanted neurostimulation system remotely by use of a patient device are disclosed herein. The methods may include steps of: establishing, with the patient device, a communication session with a remote device associated with the remote support entity; sending, with the patient device, patient information to the remote device and/or program information regarding a current therapy program applied by the implantable pulse generator of the implanted neurostimulation system; receiving, with the patient device, a program update from the remote device regarding updating of one or more parameters of the current program or a new program; and outputting, with the patient device, the program update to the implanted neurostimulation system, thereby programming the implantable pulse generator from the remote device via the patient device, with the program update of the one or more parameters of the current program or the new program.
Various methods of programming an implanted neurostimulation system remotely with a remote device are disclosed herein. The methods may include steps of: establishing a communication session between an implantable pulse generator of the neurostimulation system implanted in a patient and a remote device associated with a remote support entity through one or more intermediary local devices for programming and/or reprogramming of the implantable pulse generator by the remote entity; receiving program information, with the remote device, wherein the program information includes a current therapy program on the implanted neurostimulation system; receiving patient information regarding the current therapy program, with the remote device via the one or more local intermediary devices, wherein the patient information includes patient identifying information and/or subjective information regarding therapy; determining or receiving, with the remote device, a program update regarding updating of one or more parameters of the current program or a new program for the implanted neurostimulation system based on the current based on the therapy program information and the patient information; and programming the implantable pulse generator, with the remote device through the one or more intermediary devices, with the program update.
A system for programming an implanted neurostimulation system remotely is also disclosed. The system may include an implantable pulse generator, a first and second intermediary device, and a remote device of a remote support entity. The implantable pulse generator of the neurostimulation system is implanted in a patient and includes one or more antennas for communicating wirelessly with one or more external devices by a first communication. The first intermediary device may be configured to communicate with the implantable pulse generator and one or more additional devices by local communication. The second intermediary device, associated with the patient, may be configured to communicate with the first intermediary device by local communication and one or more additional devices by remote communication. The second intermediary device includes a user interface for receiving a patient input from the patient. The remote device associated with a remote support entity may be configured to communicate with the second intermediary device by remote communication, wherein the remote device includes a user interface for receiving an input from the remote support entity. In some exemplary embodiments, the system may be configured to establish a communication session between the implantable pulse generator of the neurostimulation system and the remote device through the first and second intermediary local devices through which program information and/or patient information is received by the remote device for programming and/or reprogramming of the implantable pulse generator by the remote entity.
An embodiment of a patient device configured to facilitate programming of an implanted neurostimulation system remotely is disclosed herein. The patient device may include a portable housing, a communication module, a user interface and a processor module disposed within the housing. The communication module has one or more antennas with a remote communication antenna for communicating with one or more remote devices through a network, and a local communication antenna for locally communicating with one or more intermediary devices and/or an implantable pulse generator. The processor module includes a processor and a memory having stored thereon computer executable instructions configured for programming the implantable pulse generator by the remote device through the patient device. In some exemplary embodiments, the patient device may be a portable computing device, such as a laptop or smartphone, or a specialized device, and may include a specialized Patient App to facilitate programming according to any of the aspects described herein.
Further areas of applicability of the present disclosure will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating various embodiments, are intended for purposes of illustration only and are not intended to necessarily limit the scope of the disclosure.
The disclosed embodiments relate to remote programming of implanted neurostimulation treatment systems and associated devices, as well as associated devices to facilitate remote programming. Particular embodiments relate to sacral nerve stimulation treatment systems configured to treat bladder dysfunctions, including overactive bladder (“OAB”), as well as fecal dysfunctions and relieve symptoms associated therewith. For ease of description, the embodiments may be described in its use for OAB, it will be appreciated however that the disclosed embodiments may also be utilized for any variety of neuromodulation uses, such as bowel disorders (e.g., fecal incontinence, fecal frequency, fecal urgency, and/or fecal retention), the treatment of pain or other indications, such as movement or affective disorders, as will be appreciated by one of skill in the art.
Neurostimulation (or neuromodulation as may be used interchangeably hereunder) treatment systems, such as any of those described herein, may be used to treat a variety of ailments and associated symptoms, such as acute pain disorders, movement disorders, affective disorders, as well as bladder related dysfunction and fecal dysfunction. Examples of pain disorders that may be treated by neurostimulation include failed back surgery syndrome, reflex sympathetic dystrophy or complex regional pain syndrome, causalgia, arachnoiditis, and peripheral neuropathy. Movement orders include muscle paralysis, tremor, dystonia and Parkinson's disease. Affective disorders include depressions, obsessive-compulsive disorder, cluster headache, Tourette syndrome and certain types of chronic pain. Bladder related dysfunctions include but are not limited to OAB, urge incontinence, urgency-frequency, and urinary retention. OAB may include urge incontinence and urgency-frequency alone or in combination. Urge incontinence is the involuntary loss or urine associated with a sudden, strong desire to void (urgency). Urgency-frequency is the frequent, often uncontrollable urges to urinate (urgency) that often result in voiding in very small amounts (frequency). Urinary retention is the inability to empty the bladder. Neurostimulation treatments may be configured to address a particular condition by effecting neurostimulation of targeted nerve tissues relating to the sensory and/or motor control associated with that condition or associated symptom. Bowel disorders may include any of the variety of inflammatory, motility, and incontinence conditions.
In one aspect, the methods and systems described herein are particularly suited for treatment of urinary and fecal dysfunctions. These conditions have been historically under-recognized and significantly underserved by the medical community. OAB is one of the most common urinary dysfunctions. It is a complex condition characterized by the presence of bothersome urinary symptoms, including urgency, frequency, nocturia and urge incontinence. It is estimated that about 40 million Americans suffer from OAB. Of the adult population, about 16% of all men and women live with OAB symptoms.
OAB symptoms can have a significant negative impact on the psychosocial functioning and the quality of life of patients. People with OAB often restrict activities and/or develop coping strategies. Furthermore, OAB imposes a significant financial burden on individuals, their families, and healthcare organizations. The prevalence of co-morbid conditions is also significantly higher for patients with OAB than in the general population. Co-morbidities may include falls and fractures, urinary tract infections, skin infections, vulvovaginitis, cardiovascular, and central nervous system pathologies. Chronic constipation, fecal incontinence, and overlapping chronic constipation occur more frequently in patients with OAB.
SNM is an established therapy that provides a safe, effective, reversible, and long-lasting treatment option for the management of urge incontinence, urgency-frequency, and non-obstructive urinary retention. SNM therapy involves the use of mild electrical pulses to stimulate the sacral nerves located in the lower back. Electrodes are placed next to a sacral nerve, usually at the S3 level, by inserting the electrode leads into the corresponding foramen of the sacrum. The electrodes are inserted subcutaneously and are subsequently attached to an implantable pulse generator (IPG). The safety and effectiveness of SNM for the treatment of OAB, including durability at five years for both urge incontinence and urgency-frequency patients, is supported by multiple studies and is well-documented. SNM has also been approved to treat chronic fecal incontinence in patients who have failed or are not candidates for more conservative treatments.
Currently, SNM qualification has a trial phase, and is followed if successful by a permanent implant. The trial phase is a test stimulation period where the patient is allowed to evaluate whether the therapy is effective. Typically, there are two techniques that are utilized to perform the test stimulation. The first is an office-based procedure termed the Percutaneous Nerve Evaluation (PNE) and the other is a staged trial.
In the PNE, a foramen needle is typically used first to identify the optimal stimulation location, usually at the S3 level, and to evaluate the integrity of the sacral nerves. Motor and sensory responses are used to verify correct needle placement. A temporary stimulation lead (a unipolar electrode) is then placed near the sacral nerve under local anesthesia. This procedure may be performed in an office setting without fluoroscopy. The temporary lead is then connected to an external pulse generator (EPG) taped onto the skin of the patient during the trial phase. The stimulation level may be adjusted to provide an optimal comfort level for the particular patient. The patient will monitor his or her voiding for 3 to 7 days to see if there is any symptom improvement. The advantage of the PNE is that it is an incision free procedure that may be performed in the physician's office using local anesthesia. If a patient fails this trial test, the physician may still recommend the staged trial as described below. If the PNE trial is positive, the temporary trial lead is removed and a permanent quadri-polar tined lead is implanted along with an IPG under general anesthesia.
A staged trial involves the implantation of the permanent quadri-polar tined stimulation lead into the patient from the start. It also requires the use of a foramen needle to identify the nerve and optimal stimulation location. The lead is implanted near the S3 sacral nerve and is connected to an EPG via a lead extension. This procedure is performed under fluoroscopic guidance in an operating room and under local or general anesthesia. The EPG is adjusted to provide an optimal comfort level for the patient and the patient monitors his or her voiding for up to two weeks. If the patient obtains meaningful symptom improvement, he or she is considered a suitable candidate for permanent implantation of the IPG under general anesthesia, typically in the upper buttock area, as shown in
In regard to measuring outcomes for SNM treatment of voiding dysfunction, the voiding dysfunction indications (e.g., urge incontinence, urgency-frequency, and non-obstructive urinary retention) may be evaluated by unique primary voiding diary variables. The therapy outcomes are measured using these same variables. SNM therapy is considered successful if a minimum of 50% improvement occurs in any of primary voiding diary variables compared with the baseline. For urge incontinence patients, these voiding diary variables may include: number of leaking episodes per day, number of heavy leaking episodes per day, and number of pads used per day. For patients with urgency-frequency, primary voiding diary variables may include: number of voids per day, volume voided per void and degree of urgency experienced before each void. For patients with retention, primary voiding diary variables may include: catheterized volume per catheterization and number of catheterizations per day. For fecal incontinence patients, the outcome measures captured by the voiding diary include: number of leaking episodes per week, number of leaking days per week, and degree of urgency experienced before each leak.
The disclosed embodiments relate to remote programming of a neurostimulation system adapted to deliver neurostimulation to targeted nerve tissues in a manner that results in partial or complete activation of the target nerve fibers, causes the augmentation or inhibition of neural activity in nerves, potentially the same or different than the stimulation target, that control the organs and structures associated with bladder and bowel function.
Neurostimulation relies on consistently delivering therapeutic stimulation from a pulse generator, via one or more neurostimulation electrodes, to particular nerves or targeted regions. The neurostimulation electrodes are provided on a distal end of an implantable lead that may be advanced through a tunnel formed in patient tissue. Implantable neurostimulation systems provide patients with great freedom and mobility, but it may be easier to adjust the neurostimulation electrodes of such systems before they are surgically implanted. It is desirable for the physician to confirm that the patient has desired motor and/or sensory responses before implanting an IPG. For at least some treatments (including treatments of at least some forms of urinary and/or fecal dysfunction), demonstrating appropriate motor responses may be highly beneficial for accurate and objective lead placement while the sensory response may not be required or not available (e.g., patient is under general anesthesia).
Placement and calibration of the neurostimulation electrodes and implantable leads sufficiently close to specific nerves may be beneficial for the efficacy of treatment. Accordingly, aspects and embodiments of the present disclosure are directed to aiding and refining the accuracy and precision of neurostimulation electrode placement. Further, aspects and embodiments of the present disclosure are directed to aiding and refining protocols for setting therapeutic treatment signal parameters for a stimulation program implemented through implanted neurostimulation electrodes.
In exemplary embodiments, determination of whether or not an implantable lead and neurostimulation electrode is located in a desired or correct location may be accomplished by utilizing the neuromuscular responses to test stimulations, for example, by observed responses or through use of electromyography (“EMG”), also known as surface electromyography. EMG, is a technique that uses an EMG system or module to evaluate and record electrical activity produced by muscles, producing a record called an electromyogram. EMG detects the electrical potential generated by muscle cells when those cells are electrically or neurologically activated. The signals may be analyzed to detect activation level or recruitment order. EMG may be performed through the skin surface of a patient, intramuscularly or through electrodes disposed within a patient near target muscles, or using a combination of external and internal structures. When a muscle or nerve is stimulated by an electrode, EMG may be used to determine if the related muscle is activated, (i.e. whether the muscle fully contracts, partially contracts, or does not contract) in response to the stimulus. Accordingly, the degree of activation of a muscle can indicate whether an implantable lead or neurostimulation electrode is located in the desired or correct location on a patient. Further, the degree of activation of a muscle can indicate whether a neurostimulation electrode is providing a stimulus of sufficient strength, amplitude, frequency, or duration to affect a treatment regimen on a patient. Thus, use of EMG provides an objective and quantitative means by which to standardize placement of implantable leads and neurostimulation electrodes, reducing the subjective assessment of patient sensory responses. While use of EMG responses is discussed in some of the exemplary programming methods described below, it is appreciated that the remote programming concepts described herein are applicable to any type of programming approaches, including those that do not utilize EMG.
The CP 60 is used by a physician to adjust the settings of the EPG and/or IPG while the lead is implanted within the patient during initial programming. The CP may be a tablet computer used by the clinician to program the IPG, or to control the EPG during the trial period. The CP can also include capability to record stimulation-induced electromyograms to facilitate lead placement and programming. The patient remote 70 can allow the patient to turn the stimulation on or off, or to vary stimulation from the IPG while implanted, or from the EPG during the trial phase. The CP 60 has a control unit which may include a microprocessor and specialized computer-code instructions for implementing methods and systems for use by a physician in deploying the treatment system and setting up treatment parameters. The CP generally includes a graphical user interface to facilitate clinician input for programming. The CP may include a module with hardware and computer-code to execute EMG analysis, where the module may be a component of the control unit microprocessor, a pre-processing unit coupled to or in-line with the stimulation and/or sensory cables, or the like.
In other aspects, the CP 60 allows the clinician to read the impedance of each electrode contact whenever the lead is connected to an EPG, an IPG or a CP to ensure reliable connection is made and the lead is intact. This may be used during positioning the lead and in programming the leads to ensure the electrodes are properly functioning. The CP 60 is also able to save and display previous (e.g., up to the last four) programs that were used by a patient to help facilitate re-programming. Alternatively, the recent programs may be stored on the IPG, the Patient Device, or stored in a profile of the patient and stored in a Data Center accessible by the Patient Device and/or the CP. In some exemplary embodiments, the CP 60 further includes a USB port for saving reports to a USB drive and a charging port. The CP may be configured to operate in combination with an EPG when placing leads in a patient body as well with the IPG during programming. The CP may be electronically coupled to the EPG during test simulation through a specialized cable set or through wireless communication, thereby allowing the CP to configure, modify, or otherwise program the electrodes on the leads connected to the EPG. The CP may also include physical or virtual on/off buttons to turn the CP on and off and/or to turn stimulation on and off
Properties of the electrical pulses may be controlled via a controller of the implanted pulse generator. In some exemplary embodiments, these properties may include, for example, the frequency, amplitude, pattern, duration, or other aspects of the electrical pulses. These properties may include, for example, a voltage, a current, or the like. This control of the electrical pulses may include the creation of one or more electrical pulse programs, plans, or patterns, and in some exemplary embodiments, this may include the selection of one or more pre-existing electrical pulse programs, plans, or patterns. In the embodiment depicted in
The system may further include a patient remote 70 and CP 60, each configured to wirelessly communicate with the implanted IPG, or with the EPG during a trial, as shown in the schematic of the nerve stimulation system in
In one aspect, the IPG is rechargeable wirelessly through inductive coupling by use of a charging device 50 (CD), which is a portable device powered by a rechargeable battery to allow patient mobility while charging. The CD is used for transcutaneous charging of the IPG through RF induction. The CD can either be patched to the patient's skin using an adhesive or may be held in place using a belt 53 or by an adhesive patch 52, such as shown in the schematic of
In one aspect, the CD is equipped with one or more communication antennas that allow communication with the IPG. In this embodiment, this communication means is by shortwave radio wave, typically MedRadio. Typically, this communication means (e.g. MedRadio) has been used to communicate with the IPG during a charging session, however, this communication means can also be used to facilitate reprogramming by the remote support entity as the CD is also equipped with another communication means by which the CD can communicate with one more additional external devices. In some exemplary embodiments, this additional communication may include communication to the Patient Device (e.g. by Bluetooth). This configuration allows the CD to communicate with both the IPG and the Patient Device so that the charger may be utilized to establish communication between the Remote Support and IPG for programming, as detailed further below.
One or more properties of the electrical pulses may be controlled via a controller of the IPG or EPG. In some exemplary embodiments, these properties may include, for example, the frequency, amplitude, pattern, duration, or other aspects of the timing and magnitude of the electrical pulses. These properties can further include, for example, a voltage, a current, or the like. This control of the electrical pulses may include the creation of one or more electrical pulse programs, plans, or patterns, and in some exemplary embodiments, this may include the selection of one or more pre-existing electrical pulse programs, plans, or patterns. In one aspect, the IPG 100 includes a controller having one or more pulse programs, plans, or patterns that may be created and/or pre-programmed. In some exemplary embodiments, the IPG may be programmed to vary stimulation parameters including pulse amplitude in a range from 0 mA to 10 mA, pulse width in a range from 50 μs to 500 μs, pulse frequency in a range from 5 Hz to 250 Hz, stimulation modes (e.g., continuous or cycling), and electrode configuration (e.g., anode, cathode, or off), to achieve the optimal therapeutic outcome specific to the patient. In particular, this allows for an optimal setting to be determined for each patient even though each parameter may vary from person to person.
As shown in
In some embodiment, such as that shown in
In one aspect, the IPG may be programmed according to various stimulation modes, which may be determined by the CP or selected by the physician using the CP during initial programming or during remote programming. In some exemplary embodiments, the IPG/EPG may be configured with two stimulation modes: continuous mode and cycling mode. The cycling mode saves energy in comparison to the continuous mode, thereby extending the recharge interval of the battery and lifetime of the device. The cycling mode may also help reduce the risk of neural adaptation for some patients. Neural adaptation is a change over time in the responsiveness of the neural system to a constant stimulus. Thus, cycling mode may also mitigate neural adaptation so to provide longer-term therapeutic benefit.
To activate an axon of a nerve fiber, one needs to apply an electric field outside of the axon to create a voltage gradient across its membrane. This may be achieved by pumping charge between the electrodes of a stimulator. Action potentials, which transmit information through the nervous system, are generated when the outside of the nerve is depolarized to a certain threshold, which is determined by the amount of current delivered. To generate continuous action potentials in the axon, this extracellular gradient threshold needs to be reached with the delivery of each stimulation pulse. To activate an axon of a nerve fiber, one needs to apply an electric field outside of the axon to create a voltage gradient across its membrane. This may be achieved by pumping charge between the electrodes of a stimulator. Action potentials, which transmit information through the nervous system, are generated when the outside of the nerve is depolarized to a certain threshold, which is determined by the amount of current delivered. To generate continuous action potentials in the axon, this extracellular gradient threshold needs to be reached with the delivery of each stimulation pulse.
In conventional systems, a constant voltage power source is able to maintain the output voltage of the electrodes, so that enough current is delivered to activate the axon at initial implantation. However, during the first several weeks following implantation, tissue encapsulation around electrodes occurs, which results in an impedance (tissue resistance) increase. According to the ohms' law (I=V/R where I is the current, V the voltage and R the tissue impedance of the electrode pair), current delivered by a constant voltage stimulator will therefore decrease, generating a smaller gradient around the nerve. When the impedance reaches a certain value, extracellular depolarization will go down below the threshold value, so that no more action potential may be generated in the axon. Patients typically need to adjust the voltage of their system to re-adjust the current, and restore the efficacy of the therapy.
In contrast, certain exemplary embodiments utilize a constant current power source. In one aspect, the system uses feedback to adjust the voltage in such a way that the current is maintained regardless of what happens to the impedance (until the compliance limit of the device is reached), so that the gradient field around the nerve is maintained overtime. Using a constant current stimulator keeps delivering the same current that is initially selected regardless the impedance change, for a maintained therapeutic efficacy.
D. Workflows for Programming and Reprogramming with CP
After lead placement and nerve localization, the neurostimulation system is programmed. Typically, programming utilizes stimulation thresholds and/or characterizations of the electrodes, which may be performed specifically for programming or may be performed during the lead placement and subsequently used during programming. Previously determined stimulation thresholds or electrode characterizations may be stored on any of the devices of the system shown, or may be stored on a data center of a first party developer of the system and accessed by the Remote Support or Patient Device during programming or reprogramming. While some programming examples herein describe use of EMG measurements to inform electrode characterization, it is appreciated that these EMG measurements may be stored and subsequently utilized in a reprogramming procedure or that various other approaches without use of EMG may be used, as is known in the art.
In some exemplary embodiments, the system stores the last four programs used onboard a memory of the IPG/EPG. This is particularly advantageous for reprogramming as it allows a physician to access the most recent programs used in the neurostimulation with an entirely different CP that may not otherwise have access to the programming information. In another aspect, the programming data may be accessible online or on a cloud server and associated with a unique identifier of a given IPG/EPG such that a different CP could readily access and download programming information as needed for re-programming.
In one aspect, during lead placement, the CP 60 can utilize the thresholds previously recorded in characterizing each electrode as to its suitability for use in neurostimulation. In some exemplary embodiments, the CP 60 may be configured to program the IPG/EPG with an EMG recording from only one muscle, either the anal bellows or the big toe response. Such programming can also utilize a visual observation of the response as well as the recorded maximum response amplitude. In one aspect, the CP 60 performs programming without requiring an anal bellow response observation or EMG waveform measurement of an anal bellows response. In some exemplary embodiments, the CP 60 performs programming using an EMG recording from only the big toe response, such as shown in
In one aspect, the EMG recording may be that obtained during lead placement, or more typically, obtained during programming so that the patient can provide subjective sensory response data concurrent with performing a big toe response with a given electrode during testing. The programming may further include visual observations of the big toe response and/or the maximum response amplitude obtained during programming. Allowing programming of the IPG/EPG without requiring an anal bellow response is advantageous since the patient is not under general anesthesia while programming is performed and the anal bellows response may be uncomfortable and painful for the patient. This also allows the CP to receive subjective sensory data from the patient during programming as to any discomfort, paresthesia or pain associated with stimulation of a particular electrode configuration.
In one aspect, the EMG recording may be that obtained during lead placement, or more typically, obtained during programming so that the patient can provide subjective sensory response data concurrent with performing a big toe response with a given electrode during testing. The programming may further include visual observations of the big toe response and/or the maximum response amplitude obtained during programming. Allowing programming of the IPG/EPG without requiring an anal bellow response is advantageous since the patient is not under general anesthesia while programming is performed and the anal bellows response may be uncomfortable and painful for the patient. This also allows the CP to receive subjective sensory data from the patient during programming as to any discomfort, paresthesia or pain associated with stimulation of a particular electrode configuration.
In one aspect, the system configuration determines multiple electrode configuration recommendations based on using electrode characterization and/or threshold data based in part patient responses to the electrode stimulations previously obtained (e.g. by EMG or visual observations) and provides the recommendations to the clinician.
In one aspect, the electrode configurations are determined based on the threshold data according to the following rules: (1) Assign single cathode configurations for each contact in the “Good” tier, prioritized from farthest pair to closest pair; (2) Assign single cathode configurations for each contact in the “Good” tier, prioritized from lowest to highest threshold; (3) Assign double cathode configurations for each pair of adjacent electrodes in “Good” tier, prioritized by lowest combined threshold; (4) Assign single cathode configurations for each contact in the “OK” tier, prioritized from lowest to highest threshold; and (5) Assign double cathode configurations for each pair of adjacent electrodes from “Good” and “OK” tiers, prioritized by lowest combined threshold. The anodes for the cathode configurations are assigned as follows: for monopolar configuration, the IPG housing or “can” is assigned as the anode; for bipolar configuration, the electrode furthest from the cathode with acceptable impedance is assigned as the anode.
After identification of the electrode configuration recommendations, the system presents the electrode configuration recommendations to the physician, typically on a user interface of the CP such as shown in
In one aspect, in an idealized setting in which each of the electrodes has a “good” impedance, the system simply recommends each of the contacts as a single cathode. Although it is desirable to have four “good” electrodes, it is acceptable to have at least three “good” electrodes for initial programming. The above algorithm recommends the best electrode selection for a given case. While each physician may have their own way to select electrode for programming, providing a set of electrode configuration recommendations that are easily viewed and selected by the physician helps standardize the process, reduce the duration of the procedure and provide improve patient outcomes, particularly for inexperienced implanters or minimally trained personnel.
In one aspect, the above algorithm assumes a single input parameter for the electrode threshold. In some exemplary embodiments, the system allows the physician to select, through the CP, what parameter(s) (sensory or motor responses or in combination) to use to determine the threshold for each electrode. The physician can also select whether to rely on EMG feedback previously obtained for threshold determinations. In another aspect, qualitative sensory feedback will be considered in electrode selection, e.g., if a patient reports unpleasant sensation for any specific electrode, this electrode will be excluded from being used as cathode. In another aspect, the algorithm prioritizes single cathode over double cathodes for all contacts in the “good” tier. In some exemplary embodiments, the electrodes are tiered according to the following tiers: “good”=“1-3 mA”; “ok”=“0.5-1 mA” and “3-4 mA”; “bad”=“<0.5 mA” and “>4 mA.”
In programming the neurostimulation system, an EMG signal may be used to evaluate programming quality by allowing user to see if a motor response is evoked by stimulation. In some exemplary embodiments, the user can manually observe EMG responses and enter the observations into the CP and try to set a stimulation amplitude at a level that evokes a desired motor response.
In the first electrode configuration recommendation in
In one aspect, the graphical user interface allows the user to adjust various parameters associated with each of the recommended electrode configurations being tested. For example, as shown in
In one aspect, after programming of the IPG/EPG in accordance with the above described methods, the patient evaluates the selected program over a pre-determined period of time. Typically, the patient is able to make limited adjustments to the program, such as increasing or decreasing the amplitude or turning the treatment off If after the assessment period, the patient has not experienced relief from the treated condition or if other problems develop, the patient returns to the physician and a re-programming of the IPG/EPG is conducted with the CP in a process similar to the programming methods described above, to select an alternative electrode configuration from the recommended configuration or to develop a new treatment program that provides effective treatment.
In one aspect, the methods and devices detailed throughout facilitate programming of the IPG remotely. As described herein “reprogramming” merely refers to a programming operation that occurs after initial programming and can encompass determining an entirely new program or troubleshooting of a current therapy program by modifying one or more therapy parameters remotely. Reprogramming can utilize some information obtained previously during lead placement or initial programming, or can repeat the programming procedure or utilize an alternative programming procedure. In some exemplary embodiments, the programming procedure may utilize algorithms or rules to determine a suitable therapy program from known parameters. In other embodiments, the programming procedure may include the clinician applying or adjusting parameters accordingly to their preferences. It is appreciated that any aspects of programming procedures described herein are applicable to remote reprogramming as well.
In one scenario, after a patient is implanted with a neurostimulation lead and an implantable pulse generator, the patient may experience unsatisfactory therapy due to lack of efficacy or discomfort with stimulation and desire reprogramming. Various aspects of the process by which reprogramming may be effected or informed are detailed below.
In some exemplary embodiments, the patient completes a bladder or bowel diary included on a “Patient App” installed on a Patient Device (e.g. smartphone) in order to “qualify” or enable the Remote Programming function. The integrated symptom diary (bladder and/or bowel diary) allows the patient to keep a diary of their symptoms for a period of time prior to the initial assessment of suitability of the device and prior to requesting and in the period immediately after a reprogramming session. In some exemplary embodiments, programming technicians can access this information remotely in order to assess programming need. Alternatively, the diary function could be performed on various other devices, such as a tablet, laptop or desktop computer.
In some exemplary embodiments, the patient places the Charger over the IPG and charging communicates with the Patient App on the Patient Device. In some exemplary embodiments, the Charger to IPG communication is MedRadio, while the charger to Patient App communication is Bluetooth. In other embodiments, the system utilizes the Patient Remote, which communicates with IPG via MedRadio and connects to the Patient App of the Patient Device via Bluetooth.
In some exemplary embodiments, the Patient App on the Patient Device (e.g. smartphone) communicates via Wifi to the Remote Programming Service. Typically, the Patient App may be configured to utilize Bluetooth (e.g., to Charger) and Wifi capabilities. In some exemplary embodiments, Voice over Internet Protocol (VoIP) technology may be incorporated into the Patient App in order to avoid the need for a standard voice call, for example by using Skype integration. In other embodiments, the system can utilize a specialized, dedicated intermediary communication device that communicates with IPG via MedRadio and connects via Bluetooth to the Patient Device. In still other embodiments, the system can utilize a specialized Patient Device that communicates with IPG via MedRadio and connects by Wifi to the Remote Programming Service.
In another aspect, the Patient App of the Patient Device may be configured to communicate via Wifi to the Remote Programming “Back-end”. In some exemplary embodiments, the communication includes a data connection plus a Voice or Video chat connection between Patient and Programming Technician. The back-end components may be deployed in a number of ways, including any of cloud based, a local server, or a hosted server. The communication may include any of the following aspects: program information (e.g. current therapy, electrode characterizations, stimulation thresholds) and patient information (e.g. account, profile information, a symptom information diary from the patient).
In another aspect, the reprogramming procedure can utilize a Physician App or a Remote Programming App (these terms are used interchangeable throughout), which may be a mobile/web app that is served to a browser. This approach provides the greatest flexibility and scalability. This approach further provide versatility between several options for the structure of the support team, for example, any of a virtual call center with technicians of the device provider, a team of technicians in a call center, and a virtual call center team of contracted clinicians (e.g., super user, expert nurses, or physicians). In some exemplary embodiments, the application may be configured to provide direct contact from a patient to their own chosen physician/clinician, which may be preferable for those clinicians who want to keep control of the entire process. In some exemplary embodiments, the Patient App is not accessible through a browser and must be installed on the patient's portable device (e.g. smartphone, tablet).
In another aspect, the Remote Programming App syncs to additional databases as necessary. These additional database may include a Patient Care Manager (PCM), which allows a support technician to see relevant patient therapy history. In some exemplary embodiments, the patient's recent therapy history may be pulled from the IPG by the Charger or Patient Remote and shared via the Patient App connection to the Remote Programming App. Thus, the Patient App and Remote Programming App create an application framework by which the patient and remote support can interact, as well as communicate information access through any of the subject devices. In one aspect, this framework allows the remote support authorization and permissions over the implanted pulse generator beyond those of the patient in order to enable the remote support to control and/or adjust the implanted pulse generator for purposes of programming.
The system applications are configured so that a technician receives a communication (e.g. “call”), typically initiated via the Patient App, from a patient who wishes to have their device settings adjusted remotely. In some exemplary embodiments, the remote support can then access the patient's history stored in the patient database (e.g., Patient Care Manager), and can discuss the patient's needs live with them by voice or video call conducted through the application framework. In some exemplary embodiments, the technician sends new settings to the patient's IPG via the patient's own mobile device during the call session. In some exemplary embodiments, any setting, except amplitude, may be adjusted remotely. In some exemplary embodiments, patient must increase amplitude on their Patient Remote, which minimizes the risk of unintended stimulation/discomfort.
In another aspect, the patient gives explicit permission via the Patient App user interface for settings changes to be transferred to the stimulator, or grants permission to the remote support to make changes to the IPG in real-time. In some exemplary embodiments, the patient increases amplitude using their Patient Remote and describes any resulting change in sensation or discomfort to the technician, who adjusts settings in response. In some exemplary embodiments, the Patient Remote has access to the full amplitude range (just as when programming with the CP) and, if using the Charger as the communication bridge from the IPG to the Smartphone, communicates with the IPG while the Charger is also connected. In some exemplary embodiments, upon completion of programming activity, either the technician or patient can disconnect programming connection via the Patient App or Remote Programming App.
In another aspect, the system utilizes a remote device, which may be a CP as well as a standard computing device (e.g. smartphone, tablet, laptop, desktop). A standard computing device may be configured to facilitate remote programming by use of a Remote Programming App. In some exemplary embodiments, the Remote Programming App may be a web app accessed using a standard browser. In some exemplary embodiments, physicians can access a report of Remote Programming activities to see logs/reports on Remote Programming sessions for their patients. In some exemplary embodiments, the Patient App can only be installed on the patient's personal computing device and is not accessible through a browser.
The above-noted aspect of the remote reprogramming process may be further understood by referring to
In one aspect, local communication between local devices can utilize shortwave radio communication, for example MedRadio or Bluetooth. In this embodiment, the communication between the IPG 401 and Remote Support 430 may be effected through a number of alternative communication paths and differing types of communication (as indicated by the dashed and solid lines). The IPG 401 communicates by MedRadio, typically to comply with regulatory requirements, such that the Patient Remote 412 and Charger 411 are well suited for use as intermediary devices since each is already equipped to communicate with the IPG by MedRadio. Each of the Patient Remote and Charger can also be configured to communicate by Bluetooth such that either may be used to facilitate interaction with the patient through Patient Device 420. In this approach, the patient's personal computing device may be configured for remote programming by use of a Patient App, which is a specialized executable application program stored on a memory of the patient device. The Patient App establishes a framework by which the patient can input subjective information regarding their treatment and interact with the Remote Support entity to facilitate reprogramming and securely send program information for purposes of remote programming. In some exemplary embodiments, the system can utilize a specialized dedicated device 422 that is developed specifically for reprogramming. Such a device could be configured to communicate with the first intermediary device through Bluetooth, as described above, or by MedRadio. In some exemplary embodiments, the dedicated device could be configured to communicate by MedRadio directly with the IPG so that only a single intermediary local device is needed. Remote support 430 communicates with the Patient Device through a network (e.g. through Wifi, cellular, wired connections or any combination thereof). Remote support 430 may be cloud-based, or can utilize a first party server, or a hosted server.
In some exemplary embodiments, the first intermediary device may be an existing Charger or Patient Remote, in which the software is updated to allow functionality as the first intermediary device. For example, the software is updated to enable the Charger or Patient Remote to act as an interpreter between the implanted medical device and another external device (e.g. the second intermediary device) which utilize different communication schemes. Specifically, the first intermediary device passes any commands or requests received from the second intermediary device in one communication scheme (e.g. Bluetooth), translates the commands or requests into another communication scheme (e.g. MedRadio), and sends the translated command or request to the implantable device. In this manner, the second intermediary device requests information from the implanted medical device, and the request is passed on to the implanted medical device by the first intermediary device in the appropriate communication scheme. In response to receiving this request, the implanted medical device then outputs a communication of the requested information, which is received by the first intermediary device and communicated to the second intermediary device according to the appropriate communication scheme. In this manner, the first intermediary device is merely relaying any commands and requests received between the implanted medical device and the second intermediary device. In some exemplary embodiments, the first intermediary device is not substantively modifying the content of the request or commands, nor is it responding to the content of the request or command, nor even responding to the device from which the command or request is received.
In some exemplary embodiments, the implanted medical device stores any information pertaining to therapy (e.g. current programming parameters, alternative programs, electrode information, patient information, etc.). During the programing procedure, to the extent this information is request by the remote entity, it is obtained from the memory of the implanted medical device. In some exemplary embodiments, some of this information may be obtained from the second intermediary device (e.g. smartphone, laptop), or a remote server in communication with the remote support entity, although typically it is stored on the implanted medical device and requested from the implanted medical device during reprogramming. In some exemplary embodiments, a request for information is received by the first intermediary device. In response to the request, the first intermediary device passes the request on the implanted medical device in the appropriate communication scheme. In response to receiving the request, the implanted medical device accesses the stored information requested, then outputs the information to the second intermediary device via the first intermediary device, as described previously. Thus, in the embodiment described, the software configuration of the first intermediary device limits the role of the first intermediary device to passing a request from one device to another device according to the appropriate communication scheme. In some exemplary embodiments, any commands, requests or information passed between devices may be temporarily stored on the first intermediary device only to the extent needed to relay the command, request or information between devices. In some exemplary embodiments of the remote programming procedure, the implanted medical device is the single source for the information regarding the current therapy program and parameters, which is advantageous as it avoids any potential conflicting information as to the current therapy being applied.
In system setup 600, the first intermediary device is a specialized patient remote 610 that is capable of a first type of communication (e.g. MedRadio) with either IPG 601 having a rechargeable battery or IPG 602 having a non-rechargeable battery. The patient remote 610 is specially configured with a second type of communication (e.g. Bluetooth) for communication with a second intermediary device of the patient device 620 (e.g. laptop, tablet, smartphone of the patient), which in turn communicates wirelessly with the programming device 630 and/or a remote database portal 640 connected to database 650 containing various types of data pertaining to the patient's treatment, for example, 1) the patient program history, 2) a device event log, and 3) a patient bladder diary. The communication between the patient device 620 and the remote programming device 630 may be a third type of communication (e.g. cellular, 4G, 5G, Wifi or any combination thereof) and can further include a phone call, video call or text-type exchange between clinician and patient. Optionally, the patient device 620 can further communicate with a patient database portal 640, which may be accessed through a specialized application on the smartphone or alternatively, accessed through a standard web browser on the patient device. The patient device 620 can exchange information (e.g. upload and download) from the patient database portal 640 as needed for reprogramming. In another aspect, the remote programming device 630 can exchange information directly with the patient database portal to inform remote programming. The remote programing device 630 may be a standard computing device (e.g. commercial tablet or smartphone) with a specialized application software or may be a specialized device. Similarly, the patient device 620 may be a standard computing device (e.g. commercial tablet or smartphone) with specialized application software or may be a specialized device.
In the foregoing specification, various embodiments are described, but those skilled in the art will recognize that the invention is not limited thereto. Various disclosed features, embodiments and aspects may be used individually or jointly. Further, the described embodiments may be utilized in any number of environments and applications beyond those described herein without departing from the broader spirit and scope of the specification. The specification and drawings are, accordingly, to be regarded as illustrative rather than restrictive. It will be recognized that the terms “comprising,” “including,” and “having,” as used herein, are specifically intended to be read as open-ended terms of art. Any references to publication, patents, or patent applications are incorporated herein by reference in their entirety for all purposes.
The present application claims priority to and the benefit of U.S. Provisional Patent Application No. 63/338,403. The foregoing provisional application is incorporated by reference herein. The present application is generally related to U.S. Non-Provisional application Ser. No. 17/513,790, entitled “Devices and Methods for Remote Programming of Implanted Neurostimulation Systems,” filed on Oct. 28, 2021; U.S. Non-Provisional application Ser. No. 16/871,738, entitled “Attachment Devices and Associated Methods of Use With a Nerve Stimulation Charging Device” filed on May 11, 2020; U.S. Non-Provisional patent application Ser. No. 14/827,067 entitled “Systems and Methods for Neurostimulation Electrode Configurations Based on Neural Localization,” filed on Aug. 14, 2015 (now U.S. Pat. No. 9,855,423); U.S. Non-Provisional application Ser. No. 14/992,777, entitled “Patient Remote and Associated Methods of Use With a Nerve Stimulation System” filed on Jan. 11, 2016 (now U.S. Pat. No. 9,895,546); and U.S. Non-Provisional application Ser. No. 14/993,009, entitled “Improved Antenna and Methods of Use For an Implantable Nerve Stimulator” filed on Jan. 11, 2016 (now U.S. Pat. No. 9,700,731); each of which is assigned to the same assignee and incorporated herein by reference in its entirety for all purposes.
Number | Date | Country | |
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63338403 | May 2022 | US |