As medical device technologies continue to evolve, neurostimulator devices have gained much popularity in the medical field. Neurostimulator devices are typically battery-powered devices that are designed to deliver electrical stimulation to a patient. Through proper electrical stimulation, the neurostimulator devices can provide pain relief for patients. In effect, the electrical signals sent by the neurostimulator devices “mask” or modify the pain signals before the pain signals reach the patient's brain. As a result, the patient may feel only a tingling sensation instead of pain in the area that is stimulated.
A typical implantable neurostimulator device may include one or more integrated circuit chips containing the control circuitry and neurostimulation circuitry. The neurostimulator device may also include a plurality of electrodes that are in contact with different areas of a patient's body. The implantable neurostimulator typically includes a battery, either permanent or rechargeable, that is utilized to power the stimulation circuitry and the external communications. Controlled by the control circuitry within the neurostimulator, the electrodes are each capable of delivering electrical stimulation to their respective target contact areas. Thus, the patient can use the neurostimulator device to stimulate areas in a localized manner.
Unfortunately, not all patients receive relief from the electrical stimulation provided by the neurostimulator. In some situations, physicians attempt to trial the electrodes placement by implanting them in the desired location and running the leads through the skin. Such trialing can only be utilized for a short period of time as there is a risk of infection through the open wound. The relatively short trial period greatly increases the chances that the patient might not be able to thoroughly assess the efficacy or lack thereof of the stimulation. This could lead to permanent implantation of a system in patients who did not have adequate pain relief, or explant in patients who might otherwise have benefitted from the stimulation, given a more appropriate trial length. In addition, implantable neurostimulators are complex devices that are very expensive to purchase and implant. Given the uncertainty in the outcome and the high cost of the procedures, patients, physicians and third party payors are less likely to pursue treatment with neurostimulators and many patients do not have access to the beneficial therapeutic effects of neurostimulation.
Peripheral nerve stimulation has been used to treat chronic pain emanating from a patient's extremity, such as in the patient's arm and/or leg. However, a recurring difficulty associated with the treatment of pain within an extremity is the limited placement options available because of the often difficult necessity to place elements of the implantable neurostimulation system on two sides of a joint. This has been due to the size of the IPG (which include the lithium battery) which, in most individuals, makes it unsuitable for placement in a limb. By way of example, an electrode implantation on the tibial nerve in the ankle will require the implantable pulse generator (IPG) to be placed in the thigh, so that the implanted wires will have to cross the knee joint. However, as can be appreciated, repeated motion of the knee can easily cause structural damage to the lead, migration of the electrode, failed electrical connections and the like, thereby necessitating the repair of the lead, replacement of the electrode, or even removal of the neurostimulation system. At a minimum, such problems often result in further pain to the patient.
Therefore, while existing neurostimulator devices and techniques for their placement have been generally adequate for their intended purposes, they have not been entirely satisfactory in every aspect.
One of the broader forms of the present disclosure involves an electrical stimulation apparatus. In one aspect the stimulation system and techniques for implantation provide a bridge to implantation of a more permanent implantable pulse generator. In one embodiment, there is a first stimulation stage utilizing a reduced component stimulation device implantable in the patient. This device utilizes external controls and an external power source to function. External components are usable with the stage one device to control and power the stage one implantable components to provide stimulation. If stage one proves to be successful, one or more of the implanted components of stage one remain in the patient and are connected with an implantable pulse generator. In one form, the stage one device includes a passive receiver that is releasably coupled to a lead with stimulation electrodes. In this form, the lead may be disconnected from the passive receiver of stage one and replaced with an implantable pulse generator to form a stage two stimulation system. In an alternative form, the passive receiver includes one or more expansion connections and one or more additional components are added to the expandable passive receiver of stage one to form a modular implantable pulse generator in stage two.
In one specific embodiment, a method of limb peripheral nerve stimulation for a patient is provided that includes positioning a stimulation electrode adjacent the peripheral nerve, the electrode extending from a lead, the lead releasably coupled to a passive receiver, such that it does not extend across a movable joint. As an additional feature, if stimulation of the electrode provides pain relief to the patient, an additional aspect of the method can include coupling an implantable pulse generator to the lead.
In a further embodiment, a method of peripheral nerve stimulation includes a staged implantation procedure. The first stage includes positioning a stimulation electrode adjacent the peripheral nerve, the electrode extending from a lead coupled to a passive receiver, the passive receiver having a first displacement volume. The passive receiver is implanted in a pocket in the patient's tissue and the pocket closes around the passive receiver. The passive receiver is controlled to the stimulate the patient via an external pulse generator. If the first stage proves successful, a second stage implantation procedure is performed to implant an implantable pulse generator component. The second stage includes accessing the pocket having the passive receiver and coupling an implantable pulse generator to the lead, the implantable pulse generator substantially matching the first displacement volume occupied by the passive receiver and having a power source and a controller to control pulse delivered to the stimulation electrode. In one aspect, the passive receiver is removed from the pocket before the implantable pulse generator is implanted. In another aspect, a portion of the passive receiver is removed from the pocket and one or more modules are added to the passive receiver to form an implantable pulse generator.
In another form, a modular stimulation system for peripheral nerves is provided that includes a plurality of stimulation electrodes connected to a lead having a distal portion and an opposing proximal portion forming a first portion of a detachable coupling assembly. The modular system includes a passive receiver having a distal portion forming a second portion of a detachable coupling assembly complimentary to the first portion to electrically couple the passive receiver to the lead, the passive receiver configured to convert wireless energy to a pulse suitable to energize the plurality of stimulation electrodes. The system also includes an implantable pulse generator having an internal power source and a controller to control delivery of electrical stimulation pulses, the implantable pulse generator having a distal portion forming a third portion of a detachable coupling assembly complimentary with the first portion to electrically couple the implantable pulse generator to the lead. The passive receiver and the implantable pulse generator are configured to be interchangeably coupled to the first portion of the detachable coupling.
In still a further form, a modular stimulation system for peripheral nerves is provided that can be modified after implantation. The system includes a plurality of stimulation electrodes with a lead having a distal portion electrically coupled to the electrodes and an opposing proximal portion forming a first portion of a detachable coupling assembly. A first portion of the system includes a passive receiver having an expansion connection and a distal portion forming a second portion of a detachable coupling assembly complimentary to the first portion to electrically couple the passive receiver to said lead. The passive receiver being configured to convert wireless energy to a pulse suitable to energize the plurality of stimulation electrodes. The modular system also includes an implantable pulse generator having at least an internal power source or a controller to control delivery of electrical stimulation pulses, the implantable pulse generator having a portion forming an expansion coupling assembly complimentary with the expansion connection to electrically couple the implantable pulse generator to the passive receiver.
In yet a further aspect, a method of treating pain is also provided. The method includes implanting a stimulation system adjacent a nerve to relieve nociceptive pain prior to a surgical intervention to correct the injury causing the nociceptive pain, stimulating the nerve to relieve nociceptive pain, and operating on a source of the nociceptive pain while the stimulation system remains implanted in the patient.
In still a further aspect, there is a provided a method of treating phantom limb pain. The method includes implanting a stimulation system adjacent a nerve associated with the intact limb to be amputated and stimulating the nerve with the limb remaining intact. The method continues with amputating the limb while at least a portion of the stimulation system remains implanted in the patient and operating the stimulation system to stimulate at least one nerve associated with the amputated limb.
As a further feature, the present disclosure provides a modular neurostimulation system that can be implanted in a patient in stages. The first neurostimulation stage component is configured to provide electrical stimulation from an implanted device that is entirely implanted under the skin to inhibit the risk of infection. In one aspect, the method includes designing the implantable first stage components to have simplified electrical components that can be manufactured at a relatively low first cost. The implantable first stage can then be offered to a customer at a correspondingly low first sales price. The implantable first stage relies on external components to power and/or control the stimulation signals generated by the first stage. The contemplated staged implant procedure includes designing a second implantable stage component having substantially more complex components sufficient to form a self contained implantable pulse generator. The second stage components being configured to operative engage one or more components of the first stage device previously implanted. The implantable pulse generator being manufactured at a cost substantially greater than the first stage device and being offered to the customer at a sales price that is more than double the sales price of the first stage component. As a result, the low cost first stage may be utilized by the patient to determine efficacy and the much more expensive second stage only being purchased after the first stage proves successful.
Various embodiments of the present inventions are set forth in the attached figures and in the Detailed Description as provided herein and as embodied by the claims. It should be understood, however, that this Summary does not contain all of the aspects and embodiments of the one or more present inventions, is not meant to be limiting or restrictive in any manner, and that the invention(s) as disclosed herein is/are understood by those of ordinary skill in the art to encompass obvious improvements and modifications thereto.
Additional advantages of the present invention will become readily apparent from the following discussion, particularly when taken together with the accompanying drawings.
Aspects of the present disclosure are best understood from the following detailed description when read with the accompanying figures. It is emphasized that, in accordance with the standard practice in the industry, various features are not drawn to scale. In fact, the dimensions of the various features may be arbitrarily increased or reduced for clarity of discussion.
a is a diagrammatic block diagram of a further embodiment of an expandable neurostimulator utilizing an external power supply.
b is a diagrammatic block diagram of the neurostimulator of
a is a diagrammatic top view block diagram of a further neurostimulator according to another aspect of the present invention.
b is a side view of the neurostimulator of
a-c illustrate a further embodiment of a modular neurostimulation system.
a is a top view of a further neurostimulator.
b is a side view of the neurostimulator of
a-c illustrate a staged implantation technique for a modular neurostimulation system according to one aspect of the present invention.
It is to be understood that the following disclosure provides many different embodiments, or examples, for implementing different features of the invention. Specific examples of components and arrangements are described below to simplify the present disclosure. These are, of course, merely examples and are not intended to be limiting. Various features may be arbitrarily drawn in different scales for simplicity and clarity.
The human nervous system includes a complex network of neurological structures that extend throughout the body. As shown in
Referring now to
The passive receiver 100 includes internal electronics to enable the device to receive external power and controls enabling the receiver to energize the stimulation electrodes in at least one stimulation configuration. In the illustrated embodiment, the passive receiver 100 does not include an internal power supply sufficient to perform electrical stimulation. Instead, an external pulse generator (EPG) 120 transcutaneously transmits both power and controls instructions through the patient's skin to the passive receiver 100 to thereby control stimulation in the stimulation electrodes 112. The illustrated EPG 120 includes a socket 122 configured to receive power from a power source, such as for example, from a cord 128 connected to a wall charger. The socket 122 includes electrical connections that deliver power to a rechargeable battery 124 positioned inside the EPG. The EPG may operate on battery power or wall power. The EPG includes a coil 126 to transmit power and/or information to the passive receiver implanted in the patient. It will be appreciated that in a typical application, the EPG will be maintained in a stationary position relative to the PR for an extended period of time to provide the patient with electrical stimulation of nerves adjacent the electrodes 112. In an alternative form, a sending/receiving power and communication coil (such as shown in
In one aspect, the embodiment illustrated in
Referring now to
In one aspect, the passive receiver 100 has a displacement volume that approximates the displacement volume of the IPG 140. It will be appreciated, that as the tissue of pocket 160 heals around the passive receiver it will substantially match the displacement volume of the passive receiver. Thus, having a passive receiver 100 with a displacement volume that substantially matches the displacement volume of the IPG 140 greatly simplifies the surgical procedure of explanting the PR and implanting the IPG. The modular staged implant system of the present disclosure contemplates that the passive receiver displacement volume is greater than 65% of the displacement volume of IPG 140. In one aspect, the displacement volume of the passive receiver is greater than 75% of the displacement volume of the IPG 140. In still another aspect, the displacement volume of the passive receiver is greater than 90%, and preferably greater than 95%, of the displacement volume of the IPG 140. In still a further feature, the displacement volume of the passive receiver is the same as the displacement volume of the IPG 140. Still further, as explained in more detail below, the outer perimeter of the passive receiver may be enhanced to create a displacement volume that substantially matches the displacement volume of the IPG that forms the second stage of the modular implant system.
Referring now to
The EPR 200 includes a hermetically sealed enclosure 201 with three connectors extending through the enclosure. The first connector is the lead wire connector 208 previously described. In addition, a power connector 210 and a data connector 211 also extend through the enclosure to the exterior of the passive receiver on its proximal end. In the embodiment of
The expandable passive receiver 200 is powered and controlled by an external pulse generator (EPG) 230. The EPG includes a connection 232 to a programmer and/or charger to supply programming information to the EPG and/or provide power to the rechargeable battery 234. The EPG also includes a logic controller 236 that controls information and power transmitted/received through coil 238 to and from the passive receiver 200.
Referring now to
A further modular neurostimulation system 300 according to the present disclosure is shown in
The implantable pulse generator controller 350 includes at least a stimulation controller 352 and a memory module 354 operable to generate stimulation pulses in accordance with stored programming parameters. A housing 360 surrounds the electrical components to form a generally flat ovoid shaped device that, as shown in
In a further aspect, the modular neurostimulation system 310 includes a power supply module 370 that can be coupled to the IPG controller 350. The power supply module 370 includes a battery 372, a flexible lead 376 and a coupling assembly 378 configured for releasably mating with coupling recess 362. As discussed above, a flexible material surrounds the battery to form a generally flat ovoid housing 370.
Thus, although the components of
Referring now to
The receiving coil module 640 of the EPR 602 includes only minimal electrical components to reduce its external dimensions and overall size. In the illustrated embodiment, the receiving coil module 640 is generally cylindrical and has a diameter of less than 2.5 centimeters. In a preferred aspect, the coil module diameter would be less than 1.5 centimeters. Still further, in one configuration, the wire 642 has a length of about 10 centimeters or that is approximately four times the diameter of the coil module 640. In another aspect, the wire 642 has a length of less than 7 centimeters. As shown in
Referring now to
Referring now to
Referring now to
1) Duration of stimulation per day. This provides some indication that the patient is in fact using the stimulation device as directed and how long each stimulation session lasts.
2) Stimulation program selected by user, including patient initiated program changes during the day. This provides feedback concerning whether a single simulation program or intensity is providing patient relief, or if the patient must continually make modifications to program setting to attempt to gain relief which may be an indication that the patient is not suitable for a permanent IPG or that changes concerning lead placement or stimulation programming need to be performed in the stage one process before proceeding to the stage two process.
3) Total length of stimulation time during the stage one implantation. There may be extended periods of days when a patient neglects to perform stimulation, likely because the pain is less severe, or the patient receives pain relief using other methods. This provides an indication of whether a patient's pain levels warrant a permanent IPG or if the patient may be best served by intermittent use of the passive receiver implanted in stage one.
4) Patient pain levels. In one aspect, the EPG and/or related computer software may include prompts to the patient to record pain levels during times of stimulation and at times when stimulation is not being applied. In addition to or as an alternative, the patient may be interviewed to evaluate their feedback on the efficacy of the neurostimulation. This information may be overlaid with the information above to help evaluate stimulation efficacy. Still further, the EPG may include an accelerometer to gauge the patient activity levels during periods of stimulation. This data may be used directly as an indicator of patient pain relief. Typically, patients with pain have much less limb movement than those with reduced pain. In a further aspect, the patient may were an accelerometer for a period of time before implantation of a passive receiver. The pre-implantation data can then be compared to the movement information obtained during stimulation.
5) Patient side effects. In one aspect, the EPG and/or related computer software may include prompts to the patient to record side effects during times of stimulation and at times when stimulation is not being applied. In addition to or as an alternative, the patient may be interviewed to evaluate their what, if any, side effects they are experiencing during neurostimulation. This information may be overlaid with the information above to help evaluate stimulation efficacy.
In one aspect, the patient programmer and/or an associated computer are utilized to gather data on one or more of the parameters above. The healthcare provider and/or payor may have a specific range of individual benchmarks within each parameter and/or may incorporate the various parameters into a composite score. The score may be used to indicate if the patient is an acceptable candidate for a permanent IPG. In one aspect, the patient programmer periodically communicates patient data to the physician and/or payor. Based on the collected information the physician may make a determination that an IPG would be beneficial and the payor may determine if coverage is available for an IPG implantation procedure. If the patient efficacy satisfies the benchmark requirements, the method continues to a stage two treatment and method at step 500.
Referring now to
The stage one treatment 400 offers the advantage that use of the EPG 120 is controlled by the patient. The EPG may be set aside for some time, such as for the patient to undertake certain activities, including bathing or swimming. Still further, the EPG may be used when patient pain levels are intense and discontinued when pain levels are bearable. Further, the EPG 120 may even be replaced if it is damaged, lost, becomes inoperable, needs a new battery, or the programming needs to be upgraded. The operation of the EPG continues in loop 420 between steps 412 and 416 for as long as the patient receives a benefit. The use of the EPG in this mode of operation may continue indefinitely.
At optional step 424, the results of the stage one stimulation provided by the EPG 120, passive receiver 100, lead 110 and electrodes 112 are monitored. Follow-up treatment at 424 during the stage one treatment 400 may include adjustment of the programming provided to the EPG 120 and/or adjustment of the location of the electrodes 112. Accordingly, at loop 428, the EPG 120 may be reprogrammed to adjust the stimulation signal sent to the electrodes 112. In addition, as noted above, the treating physician and/or the patient may use optional remote controllers 130 and 132 to adjust one or more tunable parameters associated with the EPG 120.
As mentioned above with respect to
After placement of either a MIPG or a self contained IPG, the implanted pulse generator is programmed in step 512, such as by using an IPG controller that is configured to wirelessly communicate with the IPG. At 516, an IPG recharger 166 is positioned proximate the IPG 154 for externally recharging the IPG 154. That is, in at least one embodiment, the IPG recharger 166 uses induction to recharge the power cell residing within the IPG 154. In a preferred aspect, the stimulation control data gathered from use of the EPG and passive receiver in stage one is used to program the IPG. In still a further aspect, the IPG or power/programming module is programmed outside the body before implantation with one or more stimulation protocols substantially matching the EPG stimulation protocols applied in stage one. In this manner, programming the IPG can be substantially faster than in traditional IPG placements where the system must be customized based on patient feedback after implantation.
Use of the IPG or MIPG continues in a traditional manner. Specifically, at 520, the IPG 140 or MIPG 250 is operated to provide a stimulation signal to the electrodes 112 via lead 110. At loop 524, the IPG recharger 136 is used to again to recharge the IPG 140 or MIPG 250.
As explained above, the MIPG 250 retains the components of the passive receiver 200 in an operable manner such that the passive receiver may be operated by an external pulse generator if desired. In at least one embodiment, although not required for all embodiments, the IPG 140 may optionally incorporate a “back-up” passive receiver. Here, the back-up passive receiver is similar in functionality to the passive receiver 100 of the stage one system elements and as used in the stage one treatment described above. More particularly, the IPG 140 may include a passive receiver enabling the IPG 140 to function as a passive receiver should the IPG 140 cease to function due to either a low battery condition, unavailability of an IPG recharger, or because the power cell in the rechargeable IPG 140 is no longer capable of being recharged. Accordingly, should the IPG 140 or MIPG 250 no longer be capable of recharging or is otherwise temporarily inoperable, an external pulse generator could be positioned adjacent the IPG 140 or MIPG 250. At loop 532, the external pulse generator is then used at 520 to operate the passive receiver built-in to the IPG 140 or MIPG 250, thereby providing stimulation power and a stimulation signal to the electrodes 112 that remain to lead 110. Therefore, at 528, an external pulse generator is optionally positioned near the IPG 140 or MIPG 250 to operate the passive receiver and provide neurostimulation to the patient.
The stage one system elements of
In addition to the foregoing advantages, stage one treatment 400 also enables use of a variety programs and testing associated with one or more EPGs 120. For example, with extended stage one treatment 400, the physician can test a variety of signal strengths, pulse widths and electrode configurations and continue to modify and vary the treatment plan to achieve improved results. In addition, the limited and relatively minimally invasive nature of the stage one implantable elements means that the stage one treatment 400 can be easily suspended if the patient happens to experience an unrelated but sufficiently serious medical condition, such as physical trauma. Such extended testing available from the stage one treatment 400 can help in eliminating false positives resulting from a placebo effect, adaptation, plasticity, and/or secondary gain sometimes observed during shorter-term efficacy testing.
For those situations wherein stage two is indicated, steps are readily undertaken to modify the stage one system to the level of a stage two system as described herein. On the other hand, for those stage one systems that do not appear sufficiently successful (or otherwise do not warrant taking to stage two), three possibilities exist going forward. These include: (a) removing the stage one implantable elements 116 and terminating the stage one treatment 400 in its entirety; (b) modifying the stage one treatment 400 in some manner to improve its effectiveness, and thereafter continuing to evaluate the efficacy of the modified stage one treatment; or (c) simply leaving the stage one implantable elements in place and continue to accept the results as experienced by the patient. Indeed, the stage one treatment 400 may be continued indefinitely. That is, ongoing treatment to the patient using an EPG 120 can continue as a relatively inexpensive solution if the patient chooses to never proceed with stage two treatment 500, or if the patient cannot afford the stage two treatment 500, particularly if the patient cannot obtain insurance approval for coverage for substantial reimbursement of the stage two treatment 500.
Referring now to
At some time after implantation of the stage one implantable elements and operating the stage one system elements in accordance with steps 412-420 of the stage one treatment 400, the treating physician and the patient may decide to move forward with stage two treatment 500. With reference now to
Although shown in
Referring now to
In another aspect, the above described systems may be used to treat temporary nociceptive limb pain. In certain orthopedic indications, such as hip, knee, ankle, shoulder, wrist and elbow problems, the patient is often advised by the attending physician to put off a surgical intervention until the pain is unbearable. In many instances, the patient is prescribed medication to mask the pain for as long as possible. However, systemic painkillers also impact the patient's quality of life making it difficult to work and drive, as well as causing other biologic side effects associated with long term use of pain killers. As an alternative, or to lessen the amount of painkillers need to relieve pain, in one non-limiting example, an electrode array, lead wire and passive receiver according to the present disclosure are implanted to relieve pain associated with the injured limb prior to a surgical intervention. As described above, the passive receiver is energized by an external pulse generator to provide neurostimulation to the related nerve(s). The use of the passive receiver system may continue for months or even years if the patient can still function in their daily lives. In the example of knee pain, the passive receiver system is implanted adjacent the femoral nerve between the hip and knee joints away from the injured site generating the pain. Neurostimulation continues prior to surgical intervention. In one form, the stimulation is generally continuous throughout the day. In another form, the stimulation may be used to relieve pain spikes caused by extensive use of the limb or during the evening to allow the patient to sleep comfortably. Once a decision is made to surgically address the cause of the pain, such as by a knee replacement, the system may be de-energized during the surgical procedure. However, the passive receiver may be reenergized shortly after surgery to mask at least part of the pain associated with the surgery. The neurostimulation system may continue to be used during the patient recovery period, which may last several months. Once the patient is no longer in pain, the passive receiver system may be removed from the patient, or the patient may elect to retain the system in the event they have future knee pain.
In a further example, a passive receiver system such as described above may be implanted in advance of limb amputation. Although the neurostimulator may be positioned to relieve pain prior to implantation, the primary objective will be to identify the nerves associated with phantom limb pain and begin stimulation of those nerves. In one form, it is anticipated that the pre-surgical stimulation would occur for approximately 4 weeks prior to amputation. Once it is determined that the patient is receiving pain blockage from the stimulation, the injured limb is then amputated. The stimulation system continues to operate to provide phantom limb pain relief to the patient after the limb has been amputated. In one form, it is anticipated that the neurostimulator would be operated for approximately 3 months after the amputation.
In a similar manner, the present neurostimulation system may also be temporarily implanted in association with reconstructive surgery. In such situations, it is common for the patient to undergo multiple surgical procedures over a long period of time. A neurostimulation system can be utilized to limit the amount of narcotics necessary to control the patient's pain. In addition to improving the patient's quality of life by limiting the amount of narcotics ingested, the system may also be more cost effective when compared to the total cost of drugs needed to achieve long term pain relief.
Thus, one method of using the limb peripheral nerve system is to implant a stimulation system to relieve chronic nociceptive pain prior to a surgical intervention to correct the injury causing the chronic pain. The method includes stimulating the nerve to relieve pain to delay surgical intervention, to prepare for amputation of a limb, or to provide relief during reconstructive surgeries. With the system implanted, a surgical intervention is performed to address the injured area causing pain. In one aspect, the passive receiver system is re-energized after surgery to assist in relieving post surgical pain.
In still a further aspect, a system and method for staged stimulation as described above can be applied to the vagal nerve, rather than being applied to the peripheral nerves, to provide a staged stimulation therapy. Similarly, a staged stimulation system and method as described above can be applied to other neural tissue such as the brain or spinal cord to provide a staged stimulation therapy.
The present invention, in various embodiments, includes providing devices and processes in the absence of items not depicted and/or described herein or in various embodiments hereof, including in the absence of such items as may have been used in previous devices or processes (e.g., for improving performance, achieving ease and/or reducing cost of implementation).
The foregoing discussion of the invention has been presented for purposes of illustration and description. The foregoing is not intended to limit the invention to the form or forms disclosed herein. In the foregoing Detailed Description for example, various features of the invention are grouped together in one or more embodiments for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claimed invention requires more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus, the following claims are hereby incorporated into this Detailed Description, with each claim standing on its own as a separate preferred embodiment of the invention.
Moreover, though the description of the invention has included description of one or more embodiments and certain variations and modifications, other variations and modifications are within the scope of the invention (e.g., as may be within the skill and knowledge of those in the art, after understanding the present disclosure). It is intended to obtain rights which include alternative embodiments to the extent permitted, including alternate, interchangeable and/or equivalent structures, functions, ranges or steps to those claimed, whether or not such alternate, interchangeable and/or equivalent structures, functions, ranges or steps are disclosed herein, and without intending to publicly dedicate any patentable subject matter.
This application is a nonprovisional application of co-pending U.S. Patent Application No. 61/450,030, filed Mar. 7, 2011, the disclosure of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61450030 | Mar 2011 | US |