NERVE CUFF ELECTRODES FABRICATED USING OVER-MOLDED LCP SUBSTRATES
An electrode lead may comprise a flexible circuit that includes a planar dielectric substrate including an elongated lead substrate portion having opposing ends, an electrode carrying substrate portion disposed on one end of the lead substrate portion, and a connector substrate portion disposed on the other end of the lead substrate portion, wherein the lead substrate portion is pre-shaped into a three-dimensional structure. The flexible circuit may further include an electrically conductive trace extending from the connector substrate portion to the electrode carrying substrate portion, a first window formed in the connector substrate portion to expose the electrically conductive trace to form a connector pad, and a second window formed in the electrode carrying substrate portion to expose the electrically conductive trace to form an electrode pad. The electrode lead may further comprise a lead connector that incorporates the connector substrate portion.
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This application is a continuation of co-pending U.S. Provisional Patent Application Ser. No. 62/415,028, filed Oct. 31, 2016, which is expressly incorporated herein by reference.
FIELD OF THE INVENTIONThe present invention generally relates to implantable neurostimulation leads, and specifically relates to implantable nerve cuff electrodes that can be used to stimulate nerves.
BACKGROUND OF THE INVENTIONNerve cuff electrodes are conventionally manufactured using implantable grade silicone or, in some cases, polyurethane. Nerve cuff electrodes generally comprise a lead body, a connector proximally located on the lead body, a cuff body distally located on the lead body, electrode contacts placed on the inner surface of the cuff body, and electrical conductors extending from the cuff body through the lead body to the connector. The method of making these nerve cuffs electrodes is typically time consuming, since the conductors and electrode contacts in the cuff body are overmolded using molds. The electrode contacts must be connected to the ends of the conductors using a mechanical crimp or welded together. The cuff body is conventionally formed by injection molding the silicone over the conductors and part of the electrode contact. The lead body that contains the conductors is overmolded with insulative material such as silicone or polyurethane. This entire process for making a nerve cuff electrode is time and labor intensive and therefore adds to the final cost of the finished lead with nerve cuff electrode.
It is desirable to make nerve cuff electrodes that would be less labor intensive and easier to make. The substrate material used to make the nerve cuff electrode should be inert in biological environments, and mechanically flexible, substantially impermeable to moisture, oxygen, and other gases and liquids, be relatively low cost, and have suitable dielectric properties. A new class of material, known as thermoplastic liquid crystal polymers (LCP), satisfies these unique combination of properties, and is well suited for cuff electrodes as a substrate on which the electrical circuitry is disposed. LCPs offer the additional advantage of precision molding and being amenable to photolithography and thin-film deposition of electrical circuitry, which can greatly reduce the time and labor to manufacture the cuff electrode.
The planarity of the LCP substrates provides various opportunities for incorporating beneficial features that are not otherwise available to conventional lead structures. However, due to its planar nature, the use of LCP as a substrate in nerve cuff electrodes, and medical leads in general, provides several challenges. First, as discussed above, it is important that medical leads be flexible in all planes, especially when implanted in regions of the body prone to extensive movement, such as the neck region, of a patient. Although an LCP substrate may be flexible in one plane perpendicular to its surface, the same LCP substrate may be somewhat rigid in the plane along its surface. Second, the lead ports for conventional neurostimulation devices are generally cylindrical, thereby making the mechanical and electrical transition from planar LCP-based leads to such neurostimulation devices particularly challenging. Third, because the edges of LCP substrates tend to be sharp, such LCP substrates may need to be over-molded with a softer material, such as silicone. However, because there are only two sides of the LCP substrate on which the silicone can be adhered to, the silicone may be prone to delamination from the LCP substrate. Additionally, for the same reason, electrodes disposed on one of these planar surfaces of the LCP substrate may also be prone to delamination from the LCP substrate.
There, thus, remains a need for providing improvements to medical leads, such as nerve cuff electrodes, that utilize planar dielectric substrates, such as LCP, on which electrical circuitry is disposed.
SUMMARY OF THE INVENTIONIn accordance with the present inventions, electrode leads are provided. Such electrode leads may comprise an elongated lead body, a lead connector disposed at a proximal end of the lead body (e.g., one that can be inserted into a corresponding connector of a neurostimulator), an electrode carrying structure disposed at a distal end of the lead body, at least one connector contact carried by the lead connector, at least one electrode contact (e.g., three electrode contacts in a tripolar electrode arrangement) carried by the electrode carrying structure, and at least one electrical conductor extending through the lead body between the at least one connector contact and the at least one electrode contact.
In one embodiment, the lead body, electrode carrying structure, and/or lead connector are planar. In this case, the lead body, electrode carrying structure, and/or lead connector may comprise a planar dielectric substrate (e.g., liquid crystal polymer (LCP)). As one example, the electrode carrying structure may comprise a biologically compatible, elastic, electrically insulative cuff body affixed to the distal end of the lead body, and being configured for being circumferentially disposed around a nerve. The electrode contact(s) may be configured for being on an inner surface of the cuff body when circumferentially disposed around a nerve. As another example, the electrode carrying structure may comprise a biologically compatible, elastic, electrically insulative paddle body affixed to the distal end of the lead body. Such lead bodies may comprise an outer layer of insulative material composed of one of silicone, polyurethane, polyether polyurethane, polycarbonate polyurethane, parylene, perfluoroalkoxy alkanes (PFA), and polytetrafluoroethylene (PTFE).
In accordance with the present inventions, flexible circuits are also provided. Such flexible circuits may comprise a planar dielectric substrate (e.g., liquid crystal polymer (LCP)) including an elongated lead substrate portion having opposing ends, an electrode carrying substrate portion disposed on one end of the lead substrate portion, and a connector substrate portion disposed on the other end of the lead substrate portion. Such flexible circuits may also comprise an electrically conductive trace extending from the connector substrate portion to the electrode carrying substrate portion, at least a first window is formed in the connector substrate portion to expose the electrically conductive trace to form a connector pad, and at least a second window is formed in the electrode carrying substrate portion to expose the electrically conductive trace to form an electrode pad.
In one embodiment, the electrode carrying substrate portion is an enlarged cuff substrate portion pre-shaped into a cuff sized for being circumferentially disposed around a nerve. The cuff substrate portion may be, e.g., rectangular. The electrode pad may, e.g., be configured for facing a nerve when the cuff substrate portion is circumferentially disposed around a nerve. In another embodiment, the electrode carrying substrate portion is an enlarged paddle substrate portion. Such flexible circuits may further comprise an outer layer of insulative material (e.g., one of silicone, polyurethane, polyether polyurethane, polycarbonate polyurethane, parylene, perfluoroalkoxy alkanes (PFA), and polytetrafluoroethylene (PTFE)) disposed over the planar dielectric substrate.
In accordance with the present inventions, lead connectors (e.g., those that can be inserted into corresponding connectors of neurostimulators) are also provided. Such lead connectors may comprise a planar dielectric connector substrate (e.g., one composed of liquid crystal polymer (LCP)), and at least one connector pad carried by the connector substrate. Such lead connectors may further comprise at least one electrically conductive trace disposed within the connector substrate, and at least one window formed in the connector substrate to expose the electrically conductive trace(s) to form the connector pad(s).
In accordance with a first aspect of the present inventions, the elongated planar lead body of an electrode lead or the lead substrate portion of a flexible circuit is pre-shaped into a three-dimensional structure (e.g., a helical structure or a sigmoid structure).
In accordance with a second aspect of the present inventions, the elongated planar lead body of an electrode lead has at least one slit to form a plurality of planar strands, in which case, electrical conductors will extend within the plurality of strands between the connector contact(s) and the electrode contact(s). In one embodiment, the slit(s) may extend through the distal end of the lead body, such that the planar strands have loose ends. The planar strands may be pre-shaped into three-dimensional structures (e.g., helical structures, which may form a co-helical structure, or sigmoid structures). Electrode contacts may be respectively affixed to the loose ends of the planar strands. In another embodiment, the slit(s) may not extend through either the proximal end or the distal end of the lead body, such that both ends of the lead body are intact. The slit(s) may comprise a plurality of collinear slits, such that the lead body is intact between the collinear slits.
Similarly, the lead substrate portion of a flexible circuit has at least one slit to form a plurality of planar strands, in which case, the electrically conductive traces respectively extend through the planar strands. In one embodiment, the slit(s) may extend through one end of the lead substrate portion, such that the planar strands have loose ends. In this case, a plurality of electrode carrying substrate portions may be respectively disposed on the loose ends of the planar strands, with the second plurality of windows being respectively formed in the electrode carrying substrate portions. The planar strands may be pre-shaped into three-dimensional structures (e.g., helical structures, which may form a co-helical structure, or sigmoid structures). In another embodiment, the slit(s) may not extend through either of the opposing ends of the lead substrate portion, such that both ends of the lead substrate portion are intact. In this case, a single electrode carrying substrate portion may be disposed at the one end of the lead substrate portion. The slit(s) may comprise a plurality of collinear slits, such that the lead substrate portion is intact between the collinear slits.
In accordance with a third aspect of the present inventions, a plurality of first windows are formed in one of the connector substrate portion and the electrode carrying substrate portion to expose the electrically conductive trace to form a respective connector pad or electrode pad, such that the respective connector pad or electrode pad has a peripheral region and an interior region embedded within the planar dielectric substrate. In one embodiment, the interior region is smaller than the size of each of the first windows.
In accordance with a fourth aspect of the present inventions, the periphery of the planar electrode carrying structure of an electrode lead has a plurality of open slots (e.g., a slotted hole, a rounded slot, or a slotted “T”), and an outer layer of insulative material covers the electrode carrying structure over the open slots. Similarly, periphery of the electrode carrying structure of a flexible circuit has a plurality of open slots (e.g., a slotted hole, a rounded slot, or a slotted “T”), and an outer layer of insulative material covering the electrode carrying substrate portion over the open slots.
In accordance with a fifth aspect of the present inventions, an electrode lead comprises an elongated planar main lead body having a proximal end and a distal end, and an elongated planar branch lead body extending from the main lead body between the proximal end and distal end. In this case, the lead connector disposed at the proximal end of the main lead body, the electrode carrying structure is disposed at the distal end of the main lead body, a plurality of connector contacts are carried by the lead connector, at least one first electrode contact is carried by the electrode carrying structure, at least one second electrode contact is carried by the branch lead body, and a plurality of electrical conductors extend through the main lead body between the plurality of connector contacts and the plurality of electrode contacts. In embodiment, the branch lead body has a barb.
Similarly, the planar dielectric substrate of a flexible circuit includes an elongated main lead substrate portion having opposing ends, at least one electrode carrying substrate portion disposed on one end of the main lead substrate portion, a connector substrate portion disposed on the other end of the main lead substrate portion, and an elongated branch lead substrate portion extending from the main lead substrate portion between the opposing ends. In this case, the flexible circuit may comprise a first electrically conductive trace extending from the connector substrate portion to the electrode carrying substrate portion, a second electrically conductive trace extending from the connector substrate portion to the branch lead substrate portion, first and second windows formed in the connector substrate portion to expose the first and second electrically conductive traces to respectively form first and second connector pads, a third window formed in the electrode carrying portion to expose the first electrically conductive trace to form a first electrode pad, and a fourth window formed in the branch lead substrate portion to expose the second electrically conductive trace to form a second electrode pad. In one embodiment, the elongated branch lead substrate portion has a barb.
In accordance with a sixth aspect of the present inventions, an electrode lead comprises a plurality of biologically compatible, elastic, electrically insulative cuff bodies affixed to the distal end of the lead body. In this case, the electrode lead comprises a plurality of connector contacts carried by the lead connector, a plurality of electrode contacts respectively carried by the plurality of cuff bodies, and a plurality of electrical conductors extending within the lead body between the plurality of connector contacts and the plurality of electrode contacts. The lead body may be divided into proximal lead body portion and a distal lead body portion, the cuff bodies may comprise a proximal cuff body and a distal cuff body, the proximal lead body portion may extend between the lead connector and the proximal cuff body, and the distal lead body portion may extend between the proximal cuff body and the distal cuff body.
Similarly, a flexible circuit comprises first and second enlarged cuff substrate portions disposed on one end of the lead substrate portion. In this case, the flexible circuit comprise first and second electrically conductive traces respectively extending from the connector substrate portion to the first and second cuff substrate portions, first and second windows formed in the connector substrate portion to expose the first and second electrically conductive traces to respectively form first and second connector pads, and third and fourth windows formed in the first and second cuff substrate portions to expose the first and second electrically conductive traces to respectively form first and second electrode pads. The lead substrate portion may be divided into a first lead substrate portion and a second lead substrate portion, the first lead substrate portion may extend between the connector substrate portion and first cuff substrate portion, and the second lead substrate portion may extend between the first cuff substrate portion and the second cuff substrate portion.
In accordance with an eighth aspect of the present inventions, the cuff body is pre-shaped to curve in two orthogonal directions, such that the cuff body has a bi-stable structure. The cuff body may be configured between an unfurled stable state and a furled stable state. Similarly, the enlarged cuff substrate portion of a flexible circuit is pre-shaped to curve in two orthogonal directions, such that the cuff substrate portion has a bi-stable structure. The cuff substrate portion may be configured for being configured between an unfurled stable state and a furled stable state.
In accordance with an eighth aspect of the present inventions, the lead connector of an electrode lead includes a rigid cylindrical rod having an outer surface on which the connector substrate is affixed, such that connector contact(s) faces outward away from the cylindrical rod. The connector substrate may be pre-shaped to conform to the outer surface of the cylindrical rod. Similarly, an electrode lead may include the flexible circuit, and the rigid cylindrical rod on which the connector substrate portion of the flexible circuit is affixed, such that the connector pad faces outward away from the cylindrical rod to form a lead connector contact. The connector substrate may be pre-shaped to conform to the outer surface of the cylindrical rod. Similarly, a lead connector may comprise a rigid cylindrical rod on which the connector substrate is affixed, such that the connector pad(s) faces outward away from the cylindrical rod to form the lead connector contact. The connector substrate may be pre-shaped to conform to the outer surface of the cylindrical rod.
In accordance with a ninth aspect of the present invention, the lead connector of an electrode lead comprises at least one rigid connector contact having an arcuate surface affixed to the connector substrate and electrically coupled respectively to the connector pad(s), and a cylindrical, rigid, electrical insulator at least partially encapsulating the connector substrate and the connector contact(s), such that only the arcuate surface of each of the connector contact(s) is exposed. Similarly, the electrode lead may comprise a connector contact having an arcuate surface affixed to the connector substrate portion of the flexible circuit and electrically coupled respectively to the connector pad, and a cylindrical, rigid, electrical insulator at least partially encapsulating the connector substrate portion and the connector contact, such that only the arcuate surface of the connector contact is exposed. Similarly, a lead connector may comprise at least one rigid connector contact having an arcuate surface affixed to the connector substrate and electrically coupled respectively to the at least one connector pad, and a cylindrical, rigid, electrical insulator at least partially encapsulating the connector substrate and the at least one connector contact, such that only the arcuate surface of each of the at least one connector contact is exposed.
The electrical insulator may be composed of, e.g., epoxy or polyurethane. The arcuate surface of each of the connector contact(s) may conform with an outer surface of the electrical insulator. In one embodiment, each of the connector contact(s) has an arc length of 180 degrees or less. In another embodiment, each of the connector contact(s) has an arc length greater than 180 degrees. Each of the connector contact(s) may be, e.g., disk-shaped or half-moon shaped. Each of the connector contact(s) may have a notch in which the connector substrate is disposed.
In accordance with a tenth aspect of the present invention, the lead connector of an electrode lead comprises a cylindrical connector portion having at least one connector contact, at least one wire respectively coupled between the connector pad(s) and the connector contact(s), and a cylindrical, rigid, electrical insulator encapsulating the connector substrate. Similarly, an electrode lead may comprise a cylindrical connector portion having a connector contact, at least one wire coupled between the connector pad and the connector contact, and a cylindrical, rigid, electrical insulator encapsulating the connector substrate portion of a flexible circuit. Similarly, a lead connector may comprise a cylindrical connector portion having at least one connector contact, at least one wire respectively coupled between the connector pad(s) and the connector contact(s), and a cylindrical, rigid, electrical insulator encapsulating the connector substrate portion. The electrical insulator may be composed of, e.g., epoxy or polyurethane. In one embodiment, each of the connector contact(s) is a ring contact. In another embodiment, the wire(s) extends longitudinally along the cylindrical connector portion from the connector contact(s) out of a distal face of the cylindrical connector portion.
Other and further aspects and features of the invention will be evident from reading the following detailed description of the preferred embodiments, which are intended to illustrate, not limit, the invention.
The drawings illustrate the design and utility of preferred embodiments of the present invention, in which similar elements are referred to by common reference numerals. In order to better appreciate how the above-recited and other advantages and objects of the present inventions are obtained, a more particular description of the present inventions briefly described above will be rendered by reference to specific embodiments thereof, which are illustrated in the accompanying drawings. Understanding that these drawings depict only typical embodiments of the invention and are not therefore to be considered limiting of its scope, the invention will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Referring first to
The electrode lead 10 generally comprises an elongated planar lead body 12 having a proximal end 14 and a distal end 16, a lead connector 18 affixed to the proximal end 14 of the lead body 12, at least one lead connector contact 20 (two shown) disposed on the lead connector 18, a planar electrode carrying structure 22 affixed to the distal end 16 of the lead body 12, at least one electrode contact 24 (three shown in phantom in
In the illustrated embodiment, the electrode carrying structure 22 takes the form of a cuff body 22 that can be circumferentially disposed around tissue, e.g., a nerve 28, such that the electrode contacts 24 are disposed on an inner surface of the cuff body 22 in contact with the nerve 28. In alternative embodiments, the electrode carrying structure 22 can be any structure suitable for carrying the electrode contacts 24, e.g., a paddle or even the distal end of the lead body 12.
In the illustrated embodiment, the electrode contacts 24 can be in the form of a guarded tripolar electrode arrangement (e.g., anode-cathode-anode) that can be used for purposes of stimulating the nerve 28. Two of the outer electrode contacts 24 (the anodes) can be ganged together and coupled to one of the lead connector contacts 18 via an electrical conductor 26, and the remaining electrode contact 24 (the middle cathode) may be coupled to the other lead connector contact 18 via the other electrical conductor 26. It should be appreciated that, alternatively, the number of electrode contacts 24, lead connector contacts 18, and electrical conductors 26 can be identical, such that electrode contacts 24 may be energized independently of each other.
The cuff body 22 is relatively thin, e.g., having a thickness less than 1 mm, and preferably less than 0.5 mm, so that the cuff body 22 may be easily disposed around in conformance with the nerve 28. The cuff body 22 takes the form of a planar sheet (as best shown in
To this end, the lead connector 18 (which is a male connector in the illustrated embodiment) can be inserted into a corresponding female connector 32 of a neurostimulation device 30, which supplies electrical pulses to the electrode contacts 24 of the electrode lead 10 in accordance with a stimulation regimen. In embodiments described herein, the female connector 32 of the neurostimulation device 30 is conventional in nature. For example, the female connector 32 may take the form of an in-line connector, such as a Bal Seal® connector.
Recording electrode contacts can also be connected to the neurostimulation device 30 to provide sensed physiological signals (e.g., electromyogram (EMG) signals) to the neurostimulation device 30, and thus, in an alternative embodiment, the electrode contacts 24 of the electrode lead 10 may serve as recording electrodes. Alternatively, the recording electrode may be on a separate lead body, which is connected to the neurostimulation device 30.
In the illustrated embodiment, the electrode lead 10 is formed, at least partially, from an easily manufacturable flexible circuit 34, as best illustrated in
The planar dielectric substrate 36 generally includes an elongated lead substrate portion 38 that forms the lead body 12 of the electrode lead 10. The lead substrate portion 38 has one end 40 corresponding to the proximal end 14 of the lead body 12, and an opposing end 42 corresponding to the distal end 16 of the lead body 12. The planar dielectric substrate 36 further includes a connector substrate portion 44 disposed at the one end 40 of the lead substrate portion 38, and an enlarged cuff substrate portion 46 disposed at the other end 42 of the lead substrate portion 38. The connector substrate portion 44 forms at least a portion of the connector 18 of the electrode lead 10 (shown in
The flexible circuit 34 further comprises electrically conductive traces 48 embedded within the planar dielectric substrate 36, and extend from the connector substrate portion 44 to the enlarged cuff substrate portion 46. The electrically conductive traces 48 may be composed of a suitable electrically conductive and biocompatible material, such as gold, or 90/10 or 80/20 Platinum-Iridium alloy.
The flexible circuit 34 further comprises windows 50 formed in the planar dielectric substrate 36, and in particular, in the connector substrate portion 44 and the cuff substrate portion 46, that respectively exposes portions of the electrically conductive traces 48 to form connector pads 52 and electrode pads 54. As will be described in further detail below, the connector pads 52 may be used as the lead connector contacts 20 themselves or may be used to connect the electrically conductive traces 48 to the lead connector contacts 20. In the illustrated embodiments described herein, the electrode pads 54 are used as the electrode contacts 24 themselves, although in alternative embodiments, the electrode contacts 24 may be separate and distinct from the electrode pads 54 and may, thus, be coupled to the electrode pads 54. The unexposed portions of the electrically conductive traces 48 form the electrical conductors 26 of the electrode lead 10 (shown in
The electrically conductive traces 48 may be disposed in the planar dielectric substrate 36 side-by-side in a single layer, as illustrated in
In one embodiment illustrated in
In another embodiment illustrated in
In still another embodiment illustrated in
As best illustrated in
The electrode lead 10 may further comprise a plurality of open slots 68 disposed along the periphery of the cuff body 22 to facilitate the anchoring of the elastic layer 64 to the cuff substrate portion 46 of the planar dielectric substrate 36. That is, the elastic layers 64 on both sides of the cuff substrate portion 46 interlocks with each other through the open slots 68. Furthermore, the shape and size of the open slots 68 can be selected to influence the rigidity (i.e., the curling stiffness) of the cuff body 22. That is, as the number of open slots 68 or the size of the open slots increases, the rigidity of the cuff body 22 will decrease. As examples, the open slots 68 may take the form of slotted holes 68a (
Referring now to
Although the connector substrate portion 44 and the cuff substrate portion 46 are illustrated in
In the embodiment of the electrode lead 10 illustrated in
In another alternative embodiment of an electrode lead 10b, as illustrated in
Referring to
The electrode lead 10c further comprises a barb 70 formed at the end of the branch lead body 12′, which can be used to anchor the branch lead body 12′ and the corresponding electrode contacts 24′ to muscle remotely located from the nerve 28. Notably, anchoring of the branch lead body 12′ to the muscle will occur as tissue grows and envelopes around the barb 70, and thus, the barb 70 need not be rigid. The electrode contacts 24′ may be used as sensors to detect physiological signals, such as EMG signals, in the muscle in which the branch lead body 12′ is anchored via the barb 70.
In this embodiment, the electrode lead 10c will be formed, at least partially, from a flexible circuit 34b that is similar to the flexible circuit 34, with the exception that the planar dielectric substrate 26 includes an additional elongated branch lead substrate portion 38′ extending from the lead substrate portion 38 (as the main lead substrate portion), as illustrated in
As will be described in further detail below, the connector pads 52′ may be used as the lead connector contacts 20′ themselves or may be used to connect the electrically conductive traces 48′ to the lead connector contacts 20′. In the illustrated embodiments described herein, the electrode pads 54′ are used as the electrode contacts 24′ themselves, although in alternative embodiments, the electrode contacts 24′ are distinct from the electrode pads 54′ and may be coupled to the electrode pads 54′. The unexposed portions of the electrically conductive traces 48′ form the electrical conductors 26′. The distal end of the branch lead substrate portion 68 will be shaped into the form of the barb 70.
Referring to
The lead body 12 may be divided into a proximal lead body portion 12(1) extending between the lead connector 18 and the proximal cuff body 22a, and a distal lead body portion 12(2) extending between the proximal cuff body 22a and the distal cuff body 22b. The lengths of the lead body portions 12(1), 12(2) may be configured for allowing the cuff bodies 22a, 22b to be placed around bilateral sections of the same nerve, such as, e.g., the hypoglossal nerve in the neck, and the branch lead body 12′ may be anchored into muscle, such that the electrode contacts 24′ can detect the patency of the upper airway. Specifically, the electrode contacts 24′ may be positioned, such that it can detect EMG signals on the genioglossus muscle or other upper airway muscles.
In the illustrated embodiment, the branch lead body 12′ is located between the lead connector 18 and the proximal cuff body 22a, although in alternative embodiments, the branch lead body 12′ may be located between the proximal cuff body 22a and the distal cuff body 22b. In still another embodiment, the electrode lead 10c may not have the branch lead body 12′. Although the electrode lead 10c is illustrated with only two cuff bodies 22a, 22b, the electrode lead 10c may alternatively include more than two cuff bodies. In alternative embodiments, the lead body 12 may be split into plurality distal ends on which cuff bodies 22 may be disposed.
In this embodiment, the lead body 12c will be formed, at least partially, from a flexible circuit 34c that is similar to the flexible circuit 34b, with the exception that the planar dielectric substrate 26 includes a first enlarged cuff substrate portion 46a in addition to the second cuff substrate portion 46b, as illustrated in
The flexible circuit 34c comprises electrically conductive traces 48 embedded within the planar dielectric substrate 36 and extending from the connector substrate portion 44 to the first and second cuff substrate portions 46a, 46b. The flexible circuit 34c further comprises windows 50 formed through the planar dielectric substrate 36, and in particular, in the connector substrate portion 44 and the first and second cuff substrate portions 46a, 46b, that respectively expose portions of the electrically conductive traces 48 to form four connector pads 52 and four additional electrode pads 54.
As will be described in further detail below, the connector pads 52 may be used as the lead connector contacts 20 themselves or may be used to connect the electrically conductive traces 48 to the lead connector contacts 20. In the illustrated embodiments described herein, the electrode pads 54 are used as the electrode contacts 24 themselves, although in alternative embodiments, the electrode contacts 24 are distinct from the electrode pads 54 and may be coupled to the electrode pads 54. The unexposed portions of the electrically conductive traces 48 form the electrical conductors 26.
The lead bodies 12 in the electrodes leads 10 described above may be variously configured, depending on the flexibility requirements of the particular application of the electrode lead 10. If minimal lateral flexibility is required, a lead body 12a, which is planar by virtue of the lead substrate portion 38 of the planar dielectric substrate 36 from which it is composed, may remain flat and straight, as illustrated in
If additional lateral flexibility is required, the lead substrate portion 38 of the planar dielectric substrate 36 can be pre-shaped into a three-dimensional structure that increases the flexibility of the lead substrate portion 38 in the plane of the dielectric substrate 36. As one example, the three-dimensional structure may be a helical structure that forms a lead body 12b, as illustrated in
Alternatively, if additional lateral flexibility is required, the lead substrate portion 38 of the planar dielectric substrate 36 may have at least one slit 74 (only one shown) formed between the electrically conductive traces 48, thereby forming a lead body 12c having a plurality of planar strands 76 (only two shown), as illustrated in
Because the widths of the planar strands 76 in the lead bodies 12c, 12d of
Alternatively, if additional lateral flexibility is required, the lead substrate portion 38 of the planar dielectric substrate 36 may be pre-shaped into a sigmoid structure to form a lead body 12f, as illustrated in
As briefly discussed above, the female connector 32 of the neurostimulation device 30 (shown in
To this end, one embodiment of a lead connector 18a comprises the connector substrate portion 44 and connector pads 52 of the flexible circuit 34 described above, and a rigid cylindrical rod 80 having an outer surface on which the connector substrate portion 44 is affixed, as illustrated in
The connector substrate portion 44 may be thermoformed into the shape of the outer surface of the cylindrical rod 80 and affixed to the outer surface of the cylindrical rod 80 using suitable means, such as bonding, although in alternative embodiments, the connector substrate portion 44 may be affixed to the outer surface of the cylindrical rod 80 without thermoforming. The connector pads 52 of the flexible circuit 34 face outward away from the cylindrical rod 80 when the connector substrate portion 44 is affixed to the outer surface of the cylindrical rod 80. In this manner, the connector pads 52 will be exposed and will serve as the connector contacts 20 when the lead connector 18a is inserted into the connector 32 of the neurostimulation device 30.
Referring to
Each of the connector contacts 82a has an arc length that is greater than 180 degrees, and in the illustrated case, has an arc length nearly 360 degrees, resulting in disk-shaped connector contacts 82a. Each connector contact 82a comprises a notch 86 in which the connector substrate portion 44 is disposed. Preferably, the dimension of the notch 86 is roughly the same thickness of the connector substrate portion 44, so that the connector contacts 82a are firmly in contact with the respective connector pads 52. Thus, the connector contacts 82a can be slipped onto the connector substrate portion 44 into firm engagement with the respective connector pads 52, as illustrated in
Referring to
The connector contacts 82b can be bonded to the respective connector pads 52 using an electrically conductive adhesive, as illustrated in
Referring to
The wires 92, which may be included as part of the conventional cylindrical portion 88 may extend longitudinally along the cylindrical connector portion 88 from the respective connector contacts 90 out of the distal face of the cylindrical connector portion 88. The wires 92 extending from the cylindrical connector portion 88 can be wire-bonded to the respective connector pads 52 of the connector substrate portion 44, e.g., via soldering, welding, or otherwise an electrically conductive adhesive. As with the electrical insulator 84 described above with respect to the lead connector 18a, the electrical insulator 94 may be composed of a suitable material that can be over-molded over the connector substrate portion 44, such as, e.g., epoxy, silicone, or polyurethane, after the wires 92 from the cylindrical connector portion 88 have been wire-bonded to the respective connector pads 52. The outer surface of the electrical insulator 86 preferably conforms to the outer surface of the cylindrical connector portion 88, such that the lead connector 18d has a smooth continuous outer surface that facilitates its insertion into the connector 32 of the neurostimulation device 30.
Having described the structure and function of various embodiments of electrode leads 10, one method 100 of manufacturing electrode leads 10 will now be described with respect to
Next, sets of electrically conductive traces 48 for the multiple electrode leads 10 are disposed on the top surface of the bottom LCP sheets using a suitable process, such as semiconductor etching (step 104). For example, the sets of electrically conductive traces 48 can be disposed on the top surface of the bottom LCP sheet in a side-by-side relationship. The ends of these electrically conductive traces 48 will be enlarged to accommodate the formation of the connector pads 52 and electrode pads 54.
Next, windows 50 for the multiple electrode leads 10 are formed through the top LCP sheet (e.g., via cutting) at select locations (step 106), and LCP sheets are laminated together by, e.g., fusion bonding with heat and pressure, thereby forming the planar dielectric substrate 36 with embedded electrically conductive traces 48 (step 108). The windows 50 formed through the top LCP sheet expose portions of the embedded electrically conductive traces 48 to form connector pads 52 and electrode pads 54. The windows 50 may be cut, such that the connector pads 52 and electrode pads 54 are not embedded in the planar dielectric substrate 36, as illustrated in
Next, the laminated LCP sheets are cut into the shapes of multiple planar dielectric substrates 36, each having a lead substrate portion 38, a connector substrate portion 44, a cuff substrate portion 46, and if existing, a branch lead substrate portion 38′ (step 110). For example, the laminated LCP sheets may be in the shape of the flexible circuit 34 illustrated in
Then, each of the planar dielectric substrates 36 is thermoformed into an appropriate three-dimensional shape (step 112). For example, the cuff substrate portion 46 of each dielectric plane substrate 36 may be thermoformed into a generally cylindrical shape with a desired diameter. In the case where the lead substrate portion 38 of the planar dielectric substrate 36 is helically-shaped, as illustrated in
Next, a pre-molded thin silicone sacrificial layer is disposed over the windows 50 (step 114). A colored pigment, such as a black pigment, can be used to highlight the molded silicone sacrificial layer. Then, elastic layers 64 are entirely disposed over top and bottom surfaces of the cuff substrate portion 46s of the planar dielectric substrates 36, e.g., by laminating or over-molding (step 116). Alternatively, the elastic layer 64 may be only disposed on the peripheral region of the cuff substrate portion, leaving the windows 50 inward from the peripheral region exposed.
Soft polymer tubings 70 may then be slid over the lead substrate portions 38 of the planar dielectric substrates 36 (step 118). A silicone tube of the appropriate dimensions can, for example, be immersed in heptane, which will cause the silicone tube 72 to swell and increase its diameter, making it possible to slide the expanding silicone tube 72 onto the lead substrate portion 38.
At this stage, the flexible circuit 34 (34a, 34b, or 34c) is complete. Lastly, lead connectors 18 are formed onto the connector substrate portions 44 of this flexible circuits 34 using suitable means to complete the lead electrode 10 (step 120). For example, in the case where the lead connector 18a illustrated in
Lastly, optional anti-inflammatory coatings 66 may be disposed over or within the elastic layers 64 on the cuff substrate portions 46 of the planar dielectric substrates 36 (step 122). It is desirable that the elastic layer 64 and optional anti-inflammatory coating 66 not cover the windows 50 that expose the connector pads 52 and electrode pads 54. Thus, the silicone sacrificial layer in the windows 50, along with the thin overmolded elastic layer 64 and optional inflammatory costing 66 directly over the windows 50, may then be removed (step 124). For example, under a microscope, using a scalpel blade and the pigmented color as a visual aid, the silicone sacrificial layer may be carefully removed out of the windows 50. Notably, since the silicone sacrificial layer is not bonded to the LCP, it can be easily peeled off.
Although particular embodiments of the present inventions have been shown and described, it will be understood that it is not intended to limit the present inventions to the preferred embodiments, and it will be obvious to those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the present inventions. Thus, the present inventions are intended to cover alternatives, modifications, and equivalents, which may be included within the spirit and scope of the present inventions as defined by the claims.
Claims
1. An electrode lead, comprising:
- an elongated planar lead body pre-shaped into a three-dimensional structure;
- a lead connector disposed at a proximal end of the lead body;
- an electrode carrying structure disposed at a distal end of the lead body;
- at least one connector contact carried by the lead connector;
- at least one electrode contact carried by the electrode carrying structure; and
- at least one electrical conductor extending through the lead body between the at least one connector contact and the at least one electrode contact.
2. The electrode lead of claim 1, wherein the three-dimensional structure is a helical structure.
3. The electrode lead of claim 1, wherein the three-dimensional structure is a sigmoid structure.
4. The electrode lead of claim 1, wherein the electrode carrying structure is planar.
5. The electrode lead of claim 4, wherein the electrode carrying structure comprises a biologically compatible, elastic, electrically insulative cuff body affixed to the distal end of the lead body, the cuff body configured for being circumferentially disposed around a nerve, wherein the at least one electrode contact is affixed to the cuff body.
6. The electrode lead of claim 5, wherein the at least one electrode contact is configured for being on an inner surface of the cuff body when circumferentially disposed around a nerve.
7. The electrode lead of claim 4, wherein the electrode carrying structure comprises a biologically compatible, elastic, electrically insulative paddle body affixed to the distal end of the lead body.
8. The electrode lead of claim 1, wherein the lead body comprises an outer layer of insulative material composed of one of silicone, polyurethane, polyether polyurethane, polycarbonate polyurethane, parylene, perfluoroalkoxy alkanes (PFA), and polytetrafluoroethylene (PTFE).
9. The electrode lead of claim 1, wherein the lead body comprises a planar dielectric substrate.
10. The electrode lead of claim 9, wherein the planar dielectric substrate is composed of liquid crystal polymer (LCP).
11. The electrode lead of claim 9, wherein each of the at least one electrical conductor is an electrically conductive trace embedded within the planar dielectric substrate.
12. The electrode lead of claim 1, wherein the at least one electrode contact comprises three electrode contacts in a tripolar electrode arrangement.
13. The electrode lead of claim 1, wherein the lead connector is configured for being inserted into a corresponding connector of a neurostimulator.
14. A flexible circuit, comprising:
- a planar dielectric substrate including an elongated lead substrate portion having opposing ends, an electrode carrying substrate portion disposed on one end of the lead substrate portion, and a connector substrate portion disposed on the other end of the lead substrate portion, wherein the lead substrate portion is pre-shaped into a three-dimensional structure;
- an electrically conductive trace extending from the connector substrate portion to the electrode carrying substrate portion;
- a first window formed in the connector substrate portion to expose the electrically conductive trace to form a connector pad; and
- a second window formed in the electrode carrying substrate portion to expose the electrically conductive trace to form an electrode pad.
15. The flexible circuit of claim 14, wherein the three-dimensional structure is a helical structure.
16. The flexible circuit of claim 14, wherein the three-dimensional structure is a sigmoid structure.
17. The flexible circuit of claim 14, wherein the electrode carrying substrate portion is an enlarged cuff substrate portion pre-shaped into a cuff sized for being circumferentially disposed around a nerve.
18. The flexible circuit of claim 17, wherein the cuff substrate portion is rectangular.
19. The flexible circuit of claim 17, wherein the electrode pad is configured for facing a nerve when the cuff substrate portion is circumferentially disposed around a nerve.
20. The flexible circuit of claim 14, wherein the electrode carrying substrate portion is an enlarged paddle substrate portion.
21. The flexible circuit of claim 14, further comprising an outer layer of insulative material disposed over the planar dielectric substrate, the insulative material composed of one of silicone, polyurethane, polyether polyurethane, polycarbonate polyurethane, parylene, perfluoroalkoxy alkanes (PFA), and polytetrafluoroethylene (PTFE).
22. The flexible circuit of claim 14, wherein the planar dielectric substrate is composed of liquid crystal polymer (LCP).
23.-256. (canceled)
Type: Application
Filed: Jun 27, 2017
Publication Date: May 3, 2018
Applicant: THE ALFRED E. MANN FOUNDATION FOR SCIENTIFIC RESEARCH (Valencia, CA)
Inventors: Siegmar Schmidt (Simi Valley, CA), Boon Khai Ng (La Crescenta, CA), Brian R. Dearden (Pasadena, CA), Morten Hansen (Welwyn)
Application Number: 15/634,057