Patent Application
20230181261
Various embodiments described and disclosed herein relate to the field of neurostimulation, and more particularly to delivering electrical stimulation therapy to peripheral nerves of a patient, including, but not limited to, for the purpose of stimulating muscles and alleviating pain.
Chronic low back pain (LBP) is the number one total cost burden to the U.S. healthcare system at approximately $600,000,000 per year according to ScienceDaily and a Johns Hopkins University health economics study published in September, 2012 in the Journal of Pain. LBP treatments can span the gamut from low cost over-the-counter pharmaceuticals and opioids all the way to costly spinal interventions. Frequently, marginal clinical results and/or unwanted drug dependencies result from these strategies.
Chronic LBP sufferers frequently have pain resulting from unidentified causes, and are referred to as Non-Specific Chronic Low Back Pain (NSCLBP) patients, of whom there are some 60 million such patients annually in the U.S. NSCLBP is a sub-category of LBP. NSCLBP is clinically determined by exclusion, and is defined as unmitigated chronic low back pain lasting longer than 120 days that is not attributable to a recognizable known specific pathology (e.g., infection, tumor, osteoporosis, lumbar spine fracture, disk deterioration, congenital or structural deformities, inflammatory disorders, radicular syndromes, nerve diseases or cauda equina syndrome).
NSCLBP patients suffer from a recurrent cycle of intense unidentified chronic low back pain and muscle atrophy, creating long-term spinal instability. What is needed are improved means and methods of treating NSCLB patients, such as an acute, low cost, least invasive, Peripheral Nerve Stimulation (PNS) system that can provide relief, rehabilitation and restoration early in the patient treatment continuum.
The present disclosure is directed to devices, systems, and methods that address one or more deficiencies in the prior art.
In some embodiments, there is provided a method of rehabilitating or strengthening one or more muscles in a patient, and reducing pain sensed by the patient, though electrical stimulation of one or more peripheral nerves, comprising positioning one or more medical electrical leads comprising one or more electrodes adjacent to, in contact with, or in operative positional relationship to, one or more target peripheral nerves of the patient, the one or more target peripheral nerves comprising motor and sensory nerves; delivering first stimulation signals having a first range of frequencies through the one or more electrodes of the one or more medical electrical leads to the one or more target peripheral nerves; delivering second stimulation signals having a second range of frequencies through the one or more electrodes of the one or more medical electrical leads to the one or more target nerves; wherein the first range of frequencies is lower than the second range of frequencies, the first stimulation signals are configured to stimulate one or more motor nerves in the one or more target peripheral nerves to rehabilitate or strengthen the one or more muscles, the second stimulation signals are configured to stimulate one or more sensory nerves in the one or more target peripheral nerves to reduce pain sensed by the patient.
In other embodiments, there is a provided a system for rehabilitating or strengthening one or more muscles in a patient, and reducing pain sensed by the patient, though electrical stimulation of one or more peripheral nerves, comprising one or more percutaneous medical electrical leads comprising distal portions or ends comprising one or more electrodes configured for implantation adjacent to, in contact with, or in operative positional relationship to, one or more target peripheral nerves of the patient, where the one or more bundles of target peripheral nerves comprising motor and sensory nerves, and an external pulse generator (EPG) configured for operable connection to the one or more medical electrical leads, and further being configured to deliver first stimulation signals having a first range of frequencies through the one or more electrodes of the one or more medical electrical leads to the one or more bundles of target peripheral nerves, the EPG still further being configured to deliver second stimulation signals having a second range of frequencies through the one or more electrodes of the one or more medical electrical leads to the one or more bundles of target nerves; wherein the first range of frequencies is lower than the second range of frequencies, the first stimulation signals are configured to stimulate one or more motor nerves in the one or more bundles of target peripheral nerves to disrupt arthrogenic inhibition of the one or more muscles and to rehabilitate or strengthen the one or more muscles, the second stimulation signals are configured to stimulate one or more sensory nerves in the one or more bundles of target peripheral nerves to engage gate mechanisms associated therewith thereby to reduce pain sensed by the patient.
Further embodiments are disclosed herein or will become apparent to those skilled in the art after having read and understood the claims, specification and drawings hereof.
Different aspects of the various embodiments will become apparent from the following specification, drawings and claims in which:
The drawings are not necessarily to scale. Like numbers refer to like parts or steps throughout the drawings.
Described herein are various embodiments of systems, devices, components and methods for treating pain and muscle disorders in a patient's body using neurostimulation techniques.
One emphasis of the present disclosure relates to various embodiments of systems, devices, components, methods and therapies directed to a dual electrical stimulation regime delivered from an external pulse generator (EPG) through percutaneous medical electrical leads to a patient's dorsal rami nerves for the purpose of both rehabilitating and strengthening the patient's multifidus muscles and reducing the patient's lower back pain. Other applications and embodiments for stimulating other nerves and muscles are contemplated, however, such as those employing fully implantable IPGs and/or leads, or those which stimulate muscles and sensory nerves other than the multifidus muscles and the dorsal rami nerves, more about which is said below.
Other non-limiting examples of medical electrical leads 18 and/or 20 suitable for use in some embodiments include leads used in conjunction with one or more ground electrodes, leads having arrays of cathodes employed in various configurations respecting corresponding anodes (all serving as electrodes 39), wire electrodes 39, hook-shaped electrodes 39, and barb-shaped electrodes 39. In a case where a lead 18 or 20 comprises three or more electrodes 39, EPG 12 can be configured to controllably switch and control one or more specific pairs or other groupings of electrodes 39 to which electrical stimulation is delivered in various combinations as anodes and/or cathodes. Likewise, pairs or other groups of electrodes 39 in different leads 18 and 20 (by way of non-limiting example) can be controllably switched or controlled so that the electrical fields emitted by electrodes 39 extend at least some distance between the different leads 18 and 20. In such a manner, optimum electrode pairings or groupings tailored to the specific patient 22, lead(s) placement, nerve location, etc., can be achieved to deliver the best therapy to patient 22.
In some embodiments, each of leads 18 and 20 comprises at least one cathode (electrode 39) that can be placed near a portion of the dorsal ramus nerve that contains motor and sensory components, allowing both pain blocking and muscle stimulation. Alternatively, more than one cathode (electrode 39) can be utilized, placing one cathode near a sensory component and one cathode near a motor component of the dorsal ramus nerve. Pain reduction stimulation signals are then delivered via the sensory-placed electrode, while motor stimulation of the multifidus muscle is effected via the other cathode. Both such electrodes can be mounted on a single lead, or on separate leads. As one of the electrodes is being used as a cathode for stimulation, the other electrode can be used as an anode for a return path to complete the electrical circuit. Alternatively, both stimulation electrodes could utilize a(n) additional electrode(s) as the anode. This anode could be on the one or more leads described above, a separate lead, or an external ground pad or other grounding device.
The lead examples and embodiments shown in
For purposes of rehabilitating a multifidus muscle and also of suppressing or reducing lower back pain using the dual stimulation regime described above, it has been discovered that in some embodiments one or more stimulation electrodes 39 are most beneficially positioned such that the one or more electrodes 39 are positioned proximal or just proximal from the bifurcation of medial and distal branches of the dorsal rami nerves at locations 49 (i.e., proximal from locations 48 shown in
Nevertheless, and depending upon where electrodes 39 are positioned and programmed for stimulation, other locations close to or adjoining one or more of nerves 52, 44 and 46 may also be employed beneficially and efficaciously to rehabilitate or strengthen a multifidus muscle and suppress or reduced lower back pain. As shown in
Once one or both needle(s) 130 and/or 132 have been guided to a desired location near the one or more mixed target nerves of interest, at step 104 the target nerve(s) are electrically stimulated by operably attaching the proximal ends of needles 130 and 32 to EPG 12 and activating a desired output stimulation pattern or regime for delivery to needles 130 and/or 132. Different stimulation parameters can be tested at this time by varying any one or more of the voltage, current, frequency, pulse width, amplitude, overlap, interleaving, and separate delivery of the first and second stimulation signals, as well as other electrical stimulation parameters.
In addition to experimenting with different stimulation parameters, needles 130 and/or 132 can be repositioned or their locations changed as required or desired at step 106 so that optimum stimulation results are obtained (e.g., maximum, sufficient, or acceptable multifidus muscle movement in response to the first signals, and a reduction, lowering, blocking or paresthesia as regards pain in the lower back in response to the second signal). Once step 106 has been completed, at step 108 an introducer is inserted over each needle, and at step 110 needle(s) 130 and/or 132 are withdrawn from the patient. Distal ends 47 of lead(s) 18 and/or 20 are then inserted through the introducers to their respective target nerve locations at step 112. Alternatively, needles 130 and 132 are hollow needles having inner diameters sufficiently large (e.g., 2 mm or more) to accept therein percutaneous leads 18 and 20 having diameters less than the inner diameters of needles 130 and 132. Other techniques for implanting percutaneous leads 18 and 20 near dorsal rami 52 are also contemplated.
At step 114, the proximal ends of leads 18 and/or 20 are operably connected to EPG 12. Further refinement and adjustment of electrical stimulation and EPG programming instructions may then be carried out at step 116.
As an example, patient 22 with chronic lower back pain is implanted with a lead or leads 18 and/or 20 to be situated near the dorsal rami for blocking both pain and stimulating the stabilizing muscles 68 and 70 of spine 42. An appropriate nerve target is identified using a percutaneous needle stick and demonstrating activation of the target muscle as viewed using an ultrasound apparatus. Once the target nerve and location have been established, percutaneous lead(s) 18 and/or 20 are inserted using standard techniques. Lead(s) 18 and/or 20 are operably connected to EPG 12. System 10 and EPG 12 are then programmed using a clinician programmer app in CP 14 to determine appropriate stimulation parameters (e.g., amplitude, frequency, pulse width, time between delivery of the first and second signals, etc.) for patient 22.
In addition, an MRI can be used to image one or more multifidus muscles in the patient to assess the strength or degree of atrophy of the multifidus muscles 68 and 70 before the leads 18 and/or 20 are implanted in patient 22. An MRI may also be used to image one or more multifidus muscles 68 and 70 in patient 22 after therapy has been delivered to patient 22 by the first and second stimulation signals 140 and 142, and after the leads 18 and/or 20 have been implanted in patient 22.
Referring now to
In all such potential combinations of waveform parameters in the various embodiments, however: (a) the first stimulation signals have a first range of frequencies; (b) the second stimulation signals have a second range of frequencies; (c) the average or median of the first range of frequencies is lower than the average or median of the second range of frequencies; (d) the first and second stimulation signals are delivered to the same or nearby one or more target peripheral nerves; (e) the first and second stimulation signals may be delivered at the same time, overlap one another, and/or be delivered separately but sequentially through the same, separate or multiple lead(s).
To avoid potential confusion, note that the terms “first stimulation signal” and “second stimulation signal” are not intended to mean, for example, limiting delivery of the first stimulation signal to be first in time with respect to the second stimulation signal; either signal can be delivered first, second or at some other point in time. Additionally, the generation and delivery of signals that could be classified according to their frequency as first or second stimulation signals, but that are modified or different in some respect with respect thereto (e.g., frequency, pulse width, amplitude, phase, etc.), which have been or will be generated and/or delivered at some previous or later point(s) in time, are also contemplated. Thus, the generation and delivery of more than first and signal stimulation signals is contemplated.
Continuing to refer to
In one embodiment, and as discussed above, the first stimulation signals are configured to stimulate one or more motor nerves in the one or more bundles of target peripheral nerves to disrupt arthrogenic inhibition of the one or more muscles and to rehabilitate or strengthen the one or more muscles, and the second range of stimulation signals is configured to stimulate one or more sensory nerves in the one or more bundles of target peripheral nerves to engage gate mechanisms associated therewith thereby to reduce the pain sensed by the patient.
Continuing to refer to the example first and second stimulation signals of
Also note that in
Referring now to
In still further embodiments, stimulation signals can be generated and delivered that comprise more than first and second stimulation signals, such as third, fourth, fifth, sixth and/or more stimulation signals, where each such combined and/or overlapping stimulation signal is characterized by a different combination or modification of stimulation parameters (e.g., frequency, pulse width, amplitude, phase, etc.). For example, a second pain stimulation signal having a first set of stimulation parameters associated therewith can be generated and delivered, followed by the generation and delivery of a first muscle stimulation signal having a second set of stimulation parameters associated therewith, followed by the generation and delivery of a second pain stimulation signal having a third set of stimulation parameters associated therewith, followed by the generation and delivery of a first muscle stimulation signal having a fourth set of stimulation parameters associated therewith, and so on. Pain stimulation signals can follow one after the other, and likewise muscle stimulation signals can follow one after the other. Single or multiple pain and muscle stimulation signals can be provided in any order or sequence that provides beneficial results to the patient.
In some embodiments, one or more stimulation parameters of the first muscle stimulation signals comprise one or more of: (a) frequencies ranging between about 2 Hz and about 100 Hz; (b) frequencies ranging between about 2 Hz and about 75 Hz; (c) frequencies ranging between about 4 Hz and about 50 Hz; (d) frequencies ranging between about 5 Hz and about 25 Hz; (e) frequencies ranging between about 7 Hz and about 100 Hz; (f) voltage ranging between about 0.1 mV and about 30 V; (g) current ranging between about 0.1 mA and about 30 mA; pulse width ranging between about 20 μsec and about 1000 μsec. The first stimulation signal may also be provided as a constant voltage signal or a constant current signal.
In various embodiments, one or more stimulation parameters of the second pain reduction stimulation signals comprise one or more of: (a) frequencies ranging between about 100 Hz and about 10,000 Hz; (b) frequencies ranging between about 100 Hz and about 5,000 Hz; (c) frequencies ranging between about 100 Hz and about 2,000 Hz; (d) frequencies ranging between about 100 Hz and about 1,000 Hz; (e) frequencies ranging between about 200 Hz and about 750 Hz; (f) voltage ranging between about 0.1 mV and about 30 V; (g) current ranging between about 0.1 mA and about 30 mA; pulse width ranging between about 20 μmsec and about 1,000 μsec. The first and second stimulation signals may also be provided as constant voltage signals, constant current signals, triangular signals, biphasic signals, triphasic signals, chirp or swept signals, standard rectangular pulse signals, burst signals, and so on. Tapering of signals using, for example, Hanning, Hamming, and/or Blackman windowing techniques, may also be employed.
In selected embodiments, the first stimulation signals are one or more of: (a) interleaved or alternate with the second and/or other stimulation signals; (b) overlap with the second and/or other stimulation signals; (c) are at least partially superimposed upon and delivered simultaneously with the second and/or other stimulation signals; (d) delivered to the one or more target nerves at different times than when the second and/or other stimulation signals are delivered to the one or more target nerves; and/or (e) delivered to the one or more target nerves for periods of time ranging between about 60 seconds and about 180 minutes.
In further embodiments, the second stimulation and/or other signals are one or more of: (a) delivered to the one or more target nerves for periods of time ranging between about 60 seconds and about 180 minutes.
In various embodiments, the first and/or other stimulation signals are delivered to the one or more target nerves in bursts ranging between about 20 seconds and about 60 seconds in duration, and/or the second and/or other stimulation signals are delivered to the one or more bundles of target nerves in bursts ranging between about 20 seconds and about 120 seconds in duration. Such bursts can be delivered sequentially.
In selected embodiments, delivery of the first and/or other stimulation signals is separated from delivery of the second and/or other stimulation signals by a period of time ranging between: (a) about 0 seconds and about 60 seconds; (a) about 2 minutes and about 120 minutes; (a) about 1 hours and about 3 hours.
Some illustrative embodiments of generating and delivering first pain therapy stimulation signals and second muscle therapy stimulation signals are now described, where leads 18 and/or 20 have been deployed to appropriate locations near the dorsal rami nerves, and where lower back pain and multifidus muscle rehabilitation and/or strengthening therapies (e.g., the second and first stimulation signals) are delivered to patient 22.
In one embodiment, a first muscle therapy session is delivered to the patient using a first muscle rehabilitation therapy stimulation signal having a frequency of about 10-12 Hz for about 2 hours. In a subsequent pain therapy session, a second pain therapy stimulation signal having a frequency of about 100 Hz is delivered to the patient for about 30 minutes. A second muscle rehabilitation therapy session is then delivered to the patient using the first muscle rehabilitation stimulation signal having a frequency of about 10-12 Hz for about 1 hour. A break in the delivery of the first and second stimulation signals (e.g., 2- to 4-hours) is then taken, followed by repeating the first muscle rehabilitation therapy session, the second paint therapy session, and the second muscle rehabilitation therapy session. During an average waking day for a patient, two or three of the foregoing muscle rehabilitation and pain therapy sessions can be delivered to the patient. Such therapy is typically delivered over a 45-60 day time period (or longer)
Therapy sessions can be adjusted or modified as required over the multi-day or multi-month time period over which the first and second stimulation signals are delivered to the patient. For example, the stimulation parameters of pain and/or muscle rehabilitation therapy sessions can be changed or modified as a day, or the multi-day or multi-month time period, progresses. Pain therapy sessions can be shortened as the patient's pain is reduced and the multifidus muscles become stronger. In some embodiments, the initial focus on treatment and therapy is to reduce the patient's lower back pain first so that the patient can resume or increase physical activity, which in turn permits subsequent therapy to focus increasingly on multifidus muscle strengthening, thereby breaking the cycle so (as described in further detail below). Many different modifications, combinations, and permutations of pain and muscle rehabilitation therapy sessions are contemplated, as those skilled in the art will understand after having read and understood the present specification and claims.
In another embodiment, at least some of the pain therapy sessions can include second stimulation signals having frequencies ranging between about 1,000 Hz and about 10,000 Hz. Such high frequency pain stimulation signals can provide patients with reduced-impedance signals (which in some cases can penetrate tissue and nerves deeper and further than lower-frequency signals), as well as paresthesia-free pain relief.
In still further embodiments, electrodes 39 on leads 18 and/or 20 may also be employed not only to stimulate targeted nerve bundles or nerves, but also to sense depolarization and repolarization signals originating from the targeted nerve bundles or tissue in proximity thereto. These sensed signals may in turn be employed by programming instruction loaded and circuitry disposed in EPG 12 to process the sensed signals, and then determine whether or not the stimulation parameters of the first and/or second stimulation signals should be adjusted, thereby forming a feedback control loop for peripheral nerve stimulation.
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Some articles and technical papers describing and disclosing certain selected aspects of multifidus muscle rehabilitation and lower back pain systems, devices, methods, and therapies described and disclosed herein include the following publications: (a) Peripheral Nerve Stimulation for Chronic Low Back Pain: Prospective Case Series With 1 Year of Sustained Relief Following Short-Term Implant, Gilmore Calif. et al, Pain Practice 2020 Mar;20(3):310-320; (b) Gilmore Calif., et al., Percutaneous Peripheral Nerve Stimulation for Chronic Low Back Pain: Prospective Case Series with 1 Year of Sustained Relief following Short-term Implant., Neuromodulation, vol. 22, issue 5, Jul., 2019; (c) Muscle Control for Non-specific Chronic Low Back Pain, Russo et al., Neuromodulation 2018: vol. 21, pp. 1-9; (d) Deckers, K et al, New Therapy for Refractory Chronic Mechanical Low Back Pain-Restorative Neurostimulation to Activate the Lumbar Multifidus: One Year Results of a Prospective Multicenter Clinical Trial. Neuromodulation, 2018 Jan;21(1):48-55; (e) Gilmore, C, et al., Reduction in Opioid Consumption Reported among Chronic Low Back Pain Patients Following Percutaneous Peripheral Nerve Stimulation (PNS) of the Medial Branch Nerve for up to 60 days, ASRA November 2019; (f) Gilmore Calif., et al., Percutaneous 60-day Peripheral Nerve Stimulation Implant Provides Sustained Relief of Chronic Pain Following Amputation: 12-month Follow-up of a Randomized, Double-Blind, Placebo-Controlled Trial, Regional Anesthesia and Pain Medicine, 2019; (g) Deyo, Low Back Pain, N Engl J Med, 2001 Vol 344, No. 5. 363-370; (h) Burton et al., European Guidelines for Prevention in Back Pain, 2004, Eur Spine J (2006) 15 (Suppl. 2): S136—S168 (i) Hestbaek, Low back pain: what is the long-term course? A review of studies of general patient populations, Eur Spine J 2003, 12: 149-165; (j) Chou, Diagnosis and Treatment of Low Back Pain: A joint clinical practice guideline from the American College of Physicians and the American Pain Society., Ann Intern Med. 2007. 147: 478-491; (k) Hall et al., The role of radiofrequency facet denervation in chronic back pain, Jacksonville Medicine, October, 1998; (I) U.S. Pat. No. 4,026,301 to Friedman entitled “Apparatus and method for optimum electrode placement in the treatment of disease syndromes such as spinal curvature;” (m) U.S. Pat. No. 6,505,075 to Weiner entitled “Peripheral nerve stimulation method;” (n) U.S. Pat. No. 7,167,756 to Torgerson et al. entitled “Battery recharge management for an implantable medical device;” (o) U.S. Pat. No. 8,606,358 to Sachs entitled “Muscle stimulator;” (p) U.S. Pat. No. 8,700,177 to Strother et al. entitled “Systems and methods for providing percutaneous electrical stimulation;” (q) U.S. Patent Publication No. 2004/0122482 to Tung et al. entitled “Nerve Proximity Method and Device;” (r) U.S. Patent Publication No. 2010/0036454 to Bennett et al. entitled “Systems and methods to place one or more leads in muscle for providing electrical stimulation to treat pain,” and (s) U.S. Patent Publication No. 2013/0296966 to Wongsarnpigoon et al. entitled “Systems and methods related to the treatment of back pain.” Each of the foregoing publications is hereby incorporated by reference herein, each in its respective entirety pursuant to an Information Disclosure Statement filed on even date herewith containing citations or complete copies, as the case may be, of such publications.
Referring now to
Continuing to refer to
It will now be seen that the various systems, devices, components and methods disclosed and described herein are capable of rehabilitating and strengthening atrophied muscles, and reducing or eliminating pain sensed by a patient.
What have been described above are examples and embodiments of the devices and methods described and disclosed herein. It is, of course, not possible to describe every conceivable combination of components or methodologies for purposes of describing the invention, but one of ordinary skill in the art will recognize that many further combinations and permutations of the devices and methods described and disclosed herein are possible. Accordingly, the devices and methods described and disclosed herein are intended to embrace all such alterations, modifications and variations that fall within the scope of the appended claims. In the claims, unless otherwise indicated, the article “a” is to refer to “one or more than one.”
The foregoing description and disclosure outline features of several embodiments so that those skilled in the art may better understand the detailed description set forth herein. Those skilled in the art will now understand that many different permutations, combinations and variations of hearing aid 10 fall within the scope of the various embodiments. Those skilled in the art should appreciate that they may readily use the present disclosure as a basis for designing or modifying other processes and structures for carrying out the same purposes and/or achieving the same advantages of the embodiments introduced herein. Those skilled in the art should also realize that such equivalent constructions do not depart from the spirit and scope of the present disclosure, and that they may make various changes, substitutions and alterations herein without departing from the spirit and scope of the present disclosure.
After having read and understood the present specification, those skilled in the art will now understand and appreciate that the various embodiments described herein provide solutions to long-standing problems in the effective use of neurostimulation systems.
| Number | Date | Country | |
|---|---|---|---|
| Parent | 16917326 | Jun 2020 | US |
| Child | 17974403 | US |
