The present invention relates to controlling a neural response to a stimulus, and in particular relates to measurement of a compound action potential by using one or more electrodes implanted proximal to the neural pathway, in order to provide feedback to control subsequently applied stimuli.
There are a range of situations in which it is desirable to apply neural stimuli in order to give rise to a compound action potential (CAP). For example, neuromodulation is used to treat a variety of disorders including chronic pain, Parkinson's disease, and migraine. A neuromodulation system applies an electrical pulse to tissue in order to generate a therapeutic effect. When used to relieve chronic pain, the electrical pulse is applied to the dorsal column (DC) of the spinal cord. Such a system typically comprises an implanted electrical pulse generator, and a power source such as a battery that may be rechargeable by transcutaneous inductive transfer. An electrode array is connected to the pulse generator, and is positioned in the dorsal epidural space above the dorsal column. An electrical pulse applied to the dorsal column by an electrode causes the depolarisation of neurons, and generation of propagating action potentials. The fibres being stimulated in this way inhibit the transmission of pain from that segment in the spinal cord to the brain. To sustain the pain relief effects, stimuli are applied substantially continuously, for example at a frequency in the range of 30 Hz-100 Hz.
Neuromodulation may also be used to stimulate efferent fibres, for example to induce motor functions. In general, the electrical stimulus generated in a neuromodulation system triggers a neural action potential which then has either an inhibitory or excitatory effect. Inhibitory effects can be used to modulate an undesired process such as the transmission of pain, or to cause a desired effect such as the contraction of a muscle.
The action potentials generated among a large number of fibres sum to form a compound action potential (CAP). The CAP is the sum of responses from a large number of single fibre action potentials. The CAP recorded is the result of a large number of different fibres depolarising. The propagation velocity is determined largely by the fibre diameter and for large myelinated fibres as found in the dorsal root entry zone (DREZ) and nearby dorsal column the velocity can be over 60 ms−1. The CAP generated from the firing of a group of similar fibres is measured as a positive peak potential P1, then a negative peak N1, followed by a second positive peak P2. Depending on the polarity of sense electrodes the CAP equivalently may present in the measurement with the opposite polarity, in which case the nomenclature N1-P1-N2 is used. In either case this is caused by the region of activation passing the recording electrode as the action potentials propagate along the individual fibres. An observed CAP signal will typically have a maximum amplitude in the range of microvolts, whereas a stimulus applied to evoke the CAP is typically several volts.
Conventionally, spinal cord stimulation (SCS) delivers stimulation to the dorsal column at a fixed current. When a subject moves or changes posture the distance between the spinal cord and the implanted lead varies, resulting in an increase or decrease in the amount of current received by the dorsal columns. These changes in current result in changes to recruitment and paresthesia, which can reduce the therapeutic effect of SCS and can create side effects including over-stimulation.
If a stimulus is of an amplitude and/or peak width and/or has other parameter settings which put it below the recruitment threshold, delivery of such a stimulus will fail to recruit any neural response. Thus, for effective and comfortable operation, it is necessary to maintain stimuli amplitude or delivered charge above the recruitment threshold. It is also necessary to apply stimuli which are below a comfort threshold, above which uncomfortable or painful percepts arise due to increasing recruitment of Aδ fibres which are thinly myelinated sensory nerve fibres associated with joint position, cold and pressure sensation. In almost all neuromodulation applications, a single class of fibre response is desired, but the stimulus waveforms employed can recruit action potentials on other classes of fibres which cause unwanted side effects, such as muscle contraction if motor fibres are recruited. The task of maintaining appropriate stimulus amplitude is made more difficult by electrode migration and/or postural changes of the implant recipient, either of which can significantly alter the neural recruitment arising from a given stimulus, depending on whether the stimulus is applied before or after the change in electrode position or user posture. Postural changes alone can cause a comfortable and effective stimulus regime to become either ineffectual or painful.
Another control problem, facing neuromodulation systems of all types, is achieving neural recruitment at a sufficient level required for therapeutic effect, but at minimal expenditure of energy. The power consumption of the stimulation paradigm has a direct effect on battery requirements which in turn affects the device's physical size and lifetime. For rechargeable systems, increased power consumption results in more frequent charging and, given that batteries only permit a limited number of charging cycles, ultimately this reduces the implanted lifetime of the device.
Any discussion of documents, acts, materials, devices, articles or the like which has been included in the present specification is solely for the purpose of providing a context for the present invention. It is not to be taken as an admission that any or all of these matters form part of the prior art base or were common general knowledge in the field relevant to the present invention as it existed before the priority date of each claim of this application.
Throughout this specification the word “comprise”, or variations such as “comprises” or “comprising”, will be understood to imply the inclusion of a stated element, integer or step, or group of elements, integers or steps, but not the exclusion of any other element, integer or step, or group of elements, integers or steps.
In this specification, a statement that an element may be “at least one of” a list of options is to be understood that the element may be any one of the listed options, or may be any combination of two or more of the listed options.
According to a first aspect the present invention provides an automated method of controlling a neural stimulus, the method comprising:
applying the neural stimulus to a neural pathway in order to give rise to an evoked action potential on the neural pathway, the stimulus being defined by at least one stimulus parameter;
measuring a neural compound action potential response evoked by the stimulus, and deriving from the measured evoked response a feedback variable;
completing a feedback loop by using the feedback variable to control the at least one stimulus parameter value; and
adaptively compensating for changes in a gain of the feedback loop caused by electrode movement relative to the neural pathway.
According to a second aspect the present invention provides an implantable device for controllably applying a neural stimulus, the device comprising:
a plurality of electrodes including one or more nominal stimulus electrodes and one or more nominal sense electrodes;
a stimulus source for providing a stimulus to be delivered from the one or more stimulus electrodes to a neural pathway in order to give rise to an evoked action potential on the neural pathway;
measurement circuitry for recording a neural compound action potential signal sensed at the one or more sense electrodes; and
a control unit configured to:
According to a third aspect the present invention provides a non-transitory computer readable medium for controllably applying a neural stimulus, comprising the following instructions for execution by one or more processors:
computer program code means for applying the neural stimulus to a neural pathway in order to give rise to an evoked action potential on the neural pathway, the stimulus being applied as defined by at least one stimulus parameter;
computer program code means for measuring a neural compound action potential response evoked by the stimulus and deriving from the measured evoked response a feedback variable;
computer program code means for completing a feedback loop by using the feedback variable to control the at least one stimulus parameter value; and
computer program code means for adaptively compensating for changes in a gain of the feedback loop caused by electrode movement relative to the neural pathway.
The present invention recognises that (i) recruitment of evoked compound action potentials upon the neural pathway by a given stimulus will vary based on the distance of the stimulus electrode(s) from the neural pathway, and (ii) the observed amplitude of a given ECAP upon the neural pathway will vary based on the distance of the sense electrode(s) from the neural pathway, so that electrode movement as may be caused by patient movement, postural changes, heartbeat or the like will affect the feedback loop gain of a system using feedback control of the stimulus.
In some embodiments of the invention, adaptively compensating for changes in the feedback loop may comprise maintaining a corner frequency of the feedback loop at a desired value or within a desired range. For example the desired value or range of the corner frequency may be selected to suitably attenuate low frequency noise such as heartbeat as well as high frequency noise such as electrical amplifier noise. Moreover, in some embodiments, the desired value or range of the corner frequency may be selected to bias attenuation of heartbeat and noise while the recipient is in a more or most sensitive posture, as compared to when the recipient is in a less sensitive posture, sensitive postures being those with a steeper slope of an ECAP growth curve.
In some embodiments of the invention the feedback loop could be a first order feedback loop. Alternatively, the feedback loop could be a second order feedback loop, or higher order feedback loop.
In some embodiments the feedback loop is further configured to adaptively compensate for electrical noise, such as amplifier noise, EMG noise, and neural activity not evoked by the implant.
Some embodiments of the present invention recognise that a slope P of the ECAP growth curve varies with the distance d of the electrode array from the nerve fibre or fibres, so that P is some function of d. Such embodiments of the present invention also recognise that the stimulus threshold T, being the minimum stimulus current at which a neural response will be evoked, also varies with d, so that T is some function of d.
In such embodiments, the slope P can be expressed as a function of T. While d is difficult to determine precisely and is thus often an unknown, T and P can be regularly or substantially continuously measured or estimated by applying stimuli of varying amplitude to explore the slope P of the ECAP amplitude growth and determine a zero intercept, i.e., the threshold T, at any given time.
In some such embodiments, an estimation unit may be provided which produces an estimate P′ of the slope P. The estimation P′ may in some embodiments be produced by the estimation unit from an empirical relationship of stimulus current to measured ECAP amplitude, and for example may be estimated as P′=(V+K)/I, where V is ECAP amplitude, K is a constant or function which relates P to a stimulus threshold T, for example K=P·T, and I is stimulus current amplitude. In such embodiments, the estimate P′ may then be introduced into the feedback loop to counteract the effect of P. For example, an error signal of the feedback loop may be scaled by 1/P′.
The feedback variable could in some embodiments be any one of: an amplitude; an energy; a power; an integral; a signal strength; or a derivative, of any one of: the whole evoked compound action potential; the fast neural response for example in the measurement window 0-2 ms after stimulus; the slow neural response for example in the measurement window 2-6 ms after stimulus; or of a filtered version of the response. The feedback variable could in some embodiments be an average of any such variable determined over multiple stimulus/measurement cycles. The feedback variable may in some embodiments be the zero intercept, or the slope, of a linear portion of the response of Aβ amplitude to varying stimulus current. In some embodiments the feedback variable may be derived from more than one of the preceding measures.
The control variable, or stimulus parameter, could in some embodiments be one or more of the total stimulus charge, stimulus current, pulse amplitude, phase duration, interphase gap duration or pulse shape, or a combination of these.
The present invention thus recognises that using a feedback loop to maintain a constant ECAP is a difficult task as changes in patient posture both create signal inputs and change the loop characteristics. Choosing an optimum corner frequency for the loop is a tradeoff between obtaining optimum noise rejection and optimum loop speed. This tradeoff is made more challenging with variations in loop gain.
The set point of the feedback loop may be configured so as to seek a constant value of ECAP amplitude, or may be configured to seek a target ECAP amplitude which changes over time, for example as defined by a therapy map as described in International Patent Application Publication No. WO2012155188 by the present applicant, the content of which is incorporated herein by reference.
An example of the invention will now be described with reference to the accompanying drawings, in which:
Module controller 116 has an associated memory 118 storing patient settings 120, control programs 122 and the like. Controller 116 controls a pulse generator 124 to generate stimuli in the form of current pulses in accordance with the patient settings 120 and control programs 122. Electrode selection module 126 switches the generated pulses to the appropriate electrode(s) of electrode array 150, for delivery of the current pulse to the tissue surrounding the selected electrode. Measurement circuitry 128 is configured to capture measurements of neural responses sensed at sense electrode(s) of the electrode array as selected by electrode selection module 126.
Delivery of an appropriate stimulus to the nerve 180 evokes a neural response comprising a compound action potential which will propagate along the nerve 180 as illustrated, for therapeutic purposes which in the case of spinal cord stimulator for chronic pain might be to create paraesthesia at a desired location.
The device 100 is further configured to sense the existence and intensity of compound action potentials (CAPs) propagating along nerve 180, whether such CAPs are evoked by the stimulus from electrodes 2 and 4, or otherwise evoked. To this end, any electrodes of the array 150 may be selected by the electrode selection module 126 to serve as measurement electrode 6 and measurement reference electrode 8. Signals sensed by the measurement electrodes 6 and 8 are passed to measurement circuitry 128, which for example may operate in accordance with the teachings of International Patent Application Publication No. WO2012155183 by the present applicant, the content of which is incorporated herein by reference.
Described below are a number of embodiments of the present invention for optimizing the tradeoff between noise and loop response in the presence of variations in loop gain due to mechanical changes in the electrode-to-nerve distance d.
Referring to
The stimulus crosses from the electrodes 2,4 to the spinal cord 180. However the neural recruitment arising from this is affected by mechanical changes in d, including posture changes, walking, breathing, heartbeat and so on. The stimulus also generates an evoked response y which may be approximated by the equation y=P(m−T) where T is the stimulus threshold and P is the slope of the response function. Various sources of noise n add to the evoked response y before it is measured, including (a) artifact, which is dependent on both stimulus current and posture; (b) electrical noise from external sources such as 50 Hz mains power; (c) electrical disturbances produced by the body such as neural responses evoked not by the device but by other causes such as peripheral sensory input, ECG, EMG; and (d) electrical noise from amplifiers 128.
The evoked response is amplified in the hardware sensor H then detected by the detector F. The measured evoked response amplitude f is then used as the feedback term for the loop 400, being compared to the setpoint s to produce an error e which is fed to the loop controller E. The feedback term can only be provided to the next stimulus, so there is a net delay of one sample round the loop.
Two clocks (not shown) are used in this embodiment, being a stimulus clock operating at ˜60 Hz and a sample clock for measuring the evoked response y operating at ˜10 KHz. As the detector is linear, only the stimulus clock affects the dynamics of the feedback loop 400.
The ECAP amplitude f can be used in feedback loop 400 to maintain constant paraesthesia and/or to maintain ECAP amplitude upon a predefined locus configured to allow subjects to receive consistent comfortable stimulation in every posture.
In a first embodiment a first order loop transfer function can be formulated in order to provide suitable feedback control in this scenario.
The requirements of the loop can be summarized as: 1. The gain from c toy must be 1 at DC, i.e. the loop should target its set-point. 2. Minimize y/v. i.e. keep y constant in the presence of mechanical variations. 3. Minimize n/v. i.e. keep the ECAP constant in the presence of electrical noise. For this analysis, artifact is ignored.
The description starts using Laplace transforms as it is easier to predict the behaviour, though the various implementations use the Z transform.
y=P(d)(m−T(d))
The present invention recognises that a perturbation via the input v injects a signal. The injected signal can be estimated from the differential:
Even though d is unknown this equation is enlightening as, when (m−T)>0 both changes in P and changes in T create an apparent input signal at the patient transfer element.
The present invention recognises that a perturbation via the input v, i.e. the changes in P, also affect the loop in a second way, by changing the loop gain.
For the remainder of this analysis the inputs via the patient transfer element are treated from the point of view of the two separate effects: the input v, which directly affects the output, and the input P, which affects the loop gain but does not form a signal input.
For this analysis, assume A=1, so the transfer function between the target and the ECAP is given by:
And the transfer function between the input v and the ECAP is given by:
The transfer function can be shown as the Bode plot of
y/v=fH/fC
The noise from the amplifier and from non-evoked responses is assumed to be white and is attenuated by:
y/n=fC/fN
Configuring the loop to have a corner frequency between fH and fN thus attenuates both noise and heartbeat. The loop is adjusted to have a 3 Hz corner frequency at the most sensitive posture, which typically is when the patient is lying supine. At a sample rate of 60 Hz, this provides around 11 dB of noise and movement attenuation at the heartbeat frequency of one beat per second.
Since P can vary by as much as 10:1, the corner frequency can vary by a similar amount, around 10:1. If P falls sufficiently, a point is reached where the heartbeat is not attenuated. If P rises sufficiently, it reaches a point where noise is not attenuated.
Thus, in this embodiment a fitting procedure to fit the operation of the device 100 to the recipient involves choosing the loop corner frequency at the middle of the range of P values shown in
The loop of
In another embodiment, the loop gain may be set while the recipient is in the most sensitive posture, but biased somewhat to the right in
The present invention further recognises that a figure of merit for such feedback loops can be defined, by referring to
Both the first order and second order sampled data loops amplify noise for P>sqrt(10). The first order loop becomes unstable at P>˜5. The second order loop is unstable at P>sqrt(10).
The details of implementation of an embodiment comprising a second order loop are now described. In this embodiment a second order filter is designed in the s-domain to aid understanding, then transferred to the z-domain for implementation.
The gain from the patient disturbance to the ECAP:
These are a low-pass and high-pass response respectively. Considering the equation for a second order filter:
the corner (resonant) frequency is ω0=2πf0 (in radians per second or Hz), so comparing to the equation for the gain from patient disturbance to ECAP, This is critically damped when ωB=1.414 ω0. So given P, we can choose G such that:
and
The loop was then transformed to the sampled data domain using the bilinear transform to implement each integrator. The bilinear transform approximates a continuous time integrator in the z-domain using the following transfer function, where T is the sample interval.
Some embodiments may further provide for estimation and compensation for P, as follows. This method estimates P and then using the estimate (P′) adjusts the loop gain as shown in
The compensation 1/P′ is added to the loop at a point where the average signal is zero, so as to perturb the loop as little as possible.
Since both P and T vary with distance to the cord, there must exist a relationship between them. The initial estimation of P uses the empirical relationship, for some K: PT=K. Taking the model of the current growth curve:
V=P(I−T)
eliminating T and inverting, gives the estimate P′:
To give examples of the method for estimation of K, consider the three patients shown in the following tables.
Thus, tables 2 to 5 show that the P estimator halves the variation in loop gain with P.
The present invention thus recognises that a system using a feedback loop to maintain a constant ECAP is unusual in that the changes in patient posture create both signal inputs and change the loop characteristics. Choosing an optimum corner frequency for the loop is a tradeoff between obtaining optimum noise rejection and optimum loop speed. This tradeoff is made more challenging with variations in loop gain. Methods have been described above that reduce the extent to which loop gain changes with patient posture, allowing for optimum placement of the loop poles. These methods can be used independently or in conjunction.
A study was conducted to examine the effect of posture changes on pain and on side effects (e.g. over-stimulation and under-stimulation), comparing the use of SCS with feedback (automatic current adjustment) against SCS without feedback (conventional fixed current stimulation). Subjects (n=8) were tested with and without feedback control using the Saluda Medical SCS system on the last day of their commercial system trial (5 to 7 days after lead implantation).
With feedback, stimulation current was adjusted automatically by the Saluda system by maintaining the ECAP at the subject's comfort level. Without feedback, the device delivered a fixed current similar to the commercial devices. SCS control with and without feedback were tested in various postures. Subjects compared the strength of the paraesthesia at each posture to the previous posture with 5-point Likert scales.
Subject pain scores, and stimulation side effects were compared between trial stimulation with the commercial device and Saluda feedback stimulation using 5-point Likert scales.
In contrast, in
Data of the type shown in
In
The study of
The described electronic functionality can be implemented by discrete components mounted on a printed circuit board, or by a combination of integrated circuits, or by an application-specific integrated circuit (ASIC).
It will be appreciated by persons skilled in the art that numerous variations and/or modifications may be made to the invention as shown in the specific embodiments without departing from the spirit or scope of the invention as broadly described. The present embodiments are, therefore, to be considered in all respects as illustrative and not limiting or restrictive.
Number | Date | Country | Kind |
---|---|---|---|
2014905031 | Dec 2014 | AU | national |
This application is a continuation of U.S. patent application Ser. No. 17/532,725, filed Nov. 22, 2021, which is a continuation of U.S. patent application Ser. No. 16/669,393, filed Oct. 30, 2019 and issued on Jan. 11, 2022 as U.S. Pat. No. 11,219,766, which is a continuation of U.S. patent application Ser. No. 15/535,008, filed Jun. 9, 2017 and issued on Dec. 10, 2019 as U.S. Pat. No. 10,500,399, which is a national stage of Application No. PCT/AU2015/050787, filed Dec. 11, 2015, which application claims the benefit of Australian Provisional Patent Application No. 2014905031, filed Dec. 11, 2014, the disclosures of each of which are incorporated herein by reference in their entireties.
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Number | Date | Country | |
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20220249848 A1 | Aug 2022 | US |
Number | Date | Country | |
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Parent | 17532725 | Nov 2021 | US |
Child | 17724652 | US | |
Parent | 16669393 | Oct 2019 | US |
Child | 17532725 | US | |
Parent | 15535008 | US | |
Child | 16669393 | US |