Embodiments of the present disclosure relate generally to systems and methods for implanting medical devices within a patient, and more particularly to delivery systems for implanting one or more leads.
Cardiac pacemakers and implantable cardioverter-defibrillators (ICD) use insulated wires (called leads) to monitor the heart and to also deliver electrical signals or shocks. Various techniques exist for implanting cardiac pacemakers, ICDs, and other medical devices, and each technique may use a set of tools designed for that technique. To position a lead, for example, a number of elongated tools (e.g., needles, guidewires, sheaths, and stylets) are inserted into the body. In many cases, the lead is inserted through the lumen of an introducer sheath. After the lead is positioned relative to the heart, the introducer sheath is removed.
Removing the introducer sheath without inadvertently displacing the lead can be challenging. The leads are thin and, when finally positioned, may have a number of bends or twists along its path. Furthermore, the proximal end of the lead includes a connector that is larger than the diameter of the sheath's lumen. To address this issue, splittable or peelable sheaths are used. The sheaths are split and separated from each other as the sheaths are withdrawn from the body. As such, the sheaths may be removed while avoiding the connector at the proximal end of the lead.
Although these splittable/peelable sheaths are useful, the withdrawal process can still be challenging, especially for certain procedures. More recently, the His-Purkinje system has been proposed as a physiologic substitute for right-ventricle pacing. Recent clinical trials demonstrated an increased risk of hospitalization for heart failure (HF) in patients having a high burden of right-ventricle (RV) pacing and consequently an increased risk of arrhythmias. His-bundle pacing (HBP) uses native conduction pathways and could prevent the negative effects of RV pacing and promote ventricular synchrony.
It remains challenging, however, to locate the His and achieve true selective capture. During this procedure, a slittable introducer sheath with a dilator is advanced over a guide wire until the dilator end reaches the atrium or right ventricle. With the introducer sheath in place, the implanter removes the guidewire and the dilator and advances a pacing lead through the lumen of the introducer sheath. In some cases, the pacing lead accepts a stylet to provide rigidity and push-ability to the lead. After the pacing lead is positioned, the introducer sheath is slit and removed, leaving the lead in place.
As discussed above, the implanter is careful when withdrawing the introducer sheath so that the introducer sheath does not strike the connector at the proximal end and dislodge the lead from its desired position. If the lead is dislodged, the lead-implantation procedure must begin again. Repeating the process increases the risk of infection in addition to other complications that may arise during such medical procedures.
In accordance with embodiments herein, a system is provided. The system includes an implantable lead comprising a lead body having a distal end and a proximal end. The implantable lead has electrodes positioned at the distal end and has a lead connector positioned at the proximal end. The lead connector includes lead contacts that are communicatively coupled to the electrodes positioned at the distal end. The lead body has a body outer envelope configured to fit within a lumen of an introducer sheath and the lead connector has a connector outer envelope configured to fit within the lumen of the introducer sheath. A pulse generator has a connector cavity. The lead adaptor is configured to interconnect the implantable lead and the pulse generator. The lead adaptor has an insertable connector that includes mating contacts and an adaptor cavity that includes cavity contacts. The cavity contacts are positioned to engage the lead contacts of the lead connector when the lead connector is inserted into the adaptor cavity. The insertable connector is configured to be inserted into the connector cavity of the pulse generator.
Optionally, the body outer envelope may be defined by a first dimension and the connector outer envelope may be defined by a second dimension that is not greater than the first dimension. The body outer envelope may be defined by an outer radius extending from a central longitudinal axis to an outer surface of the lead body. The insertable connector may have an insertable outer envelope that may be larger than the lumen of the introducer sheath. The system may comprise the introducer sheath, the lead connector and the distal end of the lead body being slidable within the lumen of the introducer sheath. The system may comprise low-friction material disposed between an interior surface of the introducer sheath and the lead body.
Optionally, the lead adaptor may have an adaptor body and a strain-relief segment coupled to a receiving end of the adaptor body. The adaptor body and the strain-relief segment may define respective portions of the adapter cavity. The strain-relief segment may be configured to at least partially resist bending forces delivered by the implantable lead. The lead body may include a fixation anchor attached to the distal end and may be configured to be implanted within tissue. The system may further comprise a holding stylet configured to engage the lead body when the introducer sheath is withdrawn and diminish withdrawing forces that pull the fixation anchor away from the tissue.
In accordance with embodiments herein, a system is provided. The system includes an introducer sheath having a lumen. The system includes an implantable lead comprising a lead body having a distal end and a proximal end. The implantable lead has electrodes positioned at the distal end and has a lead connector positioned at the proximal end. The lead connector includes lead contacts that are communicatively coupled to the electrodes positioned at the distal end. The lead body has a body outer envelope configured to fit within the lumen of the introducer sheath and the lead connector has a connector outer envelope configured to fit within the lumen of the introducer sheath. A lead adaptor is configured to interconnect the implantable lead and a pulse generator. The lead adaptor has an insertable connector that includes mating contacts and an adaptor cavity that includes cavity contacts. The cavity contacts are positioned to engage the lead contacts of the lead connector when the lead connector is inserted into the adaptor cavity. The insertable connector is configured to be inserted into a connector cavity of the pulse generator.
Optionally, the body outer envelope may be defined by a first dimension and the connector outer envelope may be defined by a second dimension that is not greater than the first dimension. The body outer envelope may be defined by an outer radius extending from a central longitudinal axis to an outer surface of the lead body. The insertable connector may have an insertable outer envelope that may be larger than the lumen of the introducer sheath. The proximal and distal ends of the lead body may be slidable within the lumen of the introducer sheath. The system may comprise low-friction material disposed between an interior surface of the introducer sheath and the lead body.
Optionally, the lead adaptor may have an adaptor body and a strain-relief segment coupled to a receiving end of the adaptor body. The adaptor body and the strain-relief segment may define respective portions of the adapter cavity. The lead body may include a fixation anchor attached to the distal end and may be configured to be implanted within tissue. The system may further comprise a holding stylet configured to engage the lead body when the introducer sheath is withdrawn and diminish withdrawing forces that pull the fixation anchor away from the tissue. The lead body may be a lumen-less lead body. The holding stylet may be configured to engage the proximal end of the lead body. The lead body may have a lumen. The holding stylet may be configured to be inserted through the lumen of the lead body and engage an interior of the lead body at or near the distal end.
In accordance with embodiments herein, a method is provided. The method provides providing an introducer sheath has a proximal sheath end and a distal sheath end. The introducer sheath has a lumen that extends between the proximal and distal sheath ends. The method inserts the introducer sheath into a patient. The method advances an implantable lead through the lumen of the introducer sheath. The implantable lead includes a lead body having a distal lead end and a proximal lead end. The implantable lead has electrodes positioned at the distal lead end and has a lead connector positioned at the proximal lead end. The lead body has a body outer envelope configured to fit within the sheath lumen and the lead connector has a connector outer envelope configured to fit within the sheath lumen. The method positions the distal lead end of the implantable lead at a desired position within the patient. The method engages the lead body with a holding stylet. The method removes the introducer sheath such that an interior surface of the introducer sheath slides along an exterior surface of the implantable lead. The holding stylet engages the lead body when the introducer sheath is withdrawn and diminishes withdrawing forces that pull the distal lead end of the implantable lead away from the desired position. The method slides the distal sheath end over the proximal lead end such that the introducer sheath clears the proximal lead end.
Optionally, the lead body may include a fixation anchor attached to the distal lead end. The positioning the distal lead end may include implanting a fixation anchor within tissue.
Embodiments set forth herein include delivery systems for implantable medical devices (IMDs), assemblies or kits of the delivery systems or IMDs, and methods for making and using the same. Particular embodiments are implemented in connection with a His-bundle pacing (HBP) strategy or system in which cardiac tissue is stimulate at or near the His bundle. Although embodiments may be described in relation to HBP, it should be understood that embodiments may be used in connection with a variety of IMDs and medical procedures delivering or using the IMDs. Such procedures may include implanting or extracting leads.
An IMD is a medical device which is intended to be totally or partially introduced into a body (human or animal) and remain in the human body after the procedure. An IMD may include a single component or a system of components that interact to achieve a desired performance. IMDs typically include at least one active component that perform monitoring and/or therapy functions through electrical energy. Non-limiting examples of IMDs include a cardiac monitoring device, a pacemaker, cardioverter, cardiac rhythm management device, defibrillator, neurostimulator, and the like. Many IMDs may provide multiple functions and include implantable cardioverter defibrillators (ICDs) and implantable cardiac resynchronization therapy/defibrillator devices (CRT-Ds).
IMDs often include a control device (e.g., pulse generator) and one or more other components that coordinate with the control device. For example, cardiac IMDs often include a pulse generator and one or more leads. The pulse generator has a power source and electronic circuitry that is configured to monitor the heart. The pulse generator may include one or more processors that implement programmed instructions (e.g., software or firmware) stored in memory of the pulse generator. For example, the pulse generator may be programmed to provide output stimuli (e.g., signals for pacing or a shock) through the lead or leads.
A lead includes one or more insulated electrical conductors that are intended to transfer electrical energy along a length of the lead. For example, the lead may transfer output stimuli from the pulse generator or transmit depolarization potentials from cardiac tissue to a sensing circuit of the pulse generator. A lead typically includes a lead body having an elongated flexible tube or sleeve comprising, for example, a biocompatible material (e.g., polyurethane, silicone, etc.). The lead (or lead body) has a distal end and a proximal end. As used herein, the terms “proximal” and “distal,” when used in reference to a lead (or other elongated instruments, such as an introducer sheath, catheter, guidewire, or stylet) are to be understood in relation to delivering and implanting a medical device. During an implantation procedure, “proximal” is to be understood as relatively close to the implanter and “distal” is to be understood as relatively far away from the implanter. After the implantation, a proximal end of a lead is coupled to a pulse generator, and a distal end of the lead is positioned adjacent to tissue (e.g., cardiac or nerve tissue).
The lead body may include a single lumen (or passage) or multiple lumen (or passages) within the flexible tube. A lead may have multiple electrical conductors (not shown) that electrically couple electrode(s) of the lead to the pulse generator. The electrical conductors may be cabled conductors coated with PTFE (poly-tetrafluoroethylene) and/or ETFE (ethylenetetrafluoroethylene). The electrical conductors are terminated to the respective electrode. The lead body may be configured for receiving a guide wire or stylet that enable positioning of the lead.
The lead may include one or more electrodes or one or more contacts through which electrical energy may leave or enter the conductors of the lead. Electrodes may be positioned adjacent to tissue for monitoring or providing therapy thereto. The lead connector also includes one or more contacts that are communicatively coupled to the one or more electrodes. The lead adaptor and the pulse generator are also described as including contacts. To more readily distinguish electrodes and contacts, the electrodes can be described as being positioned at the distal end and the contacts can be described as being positioned at the proximal end of the lead or as part of a lead adaptor or a pulse generator.
Various types of electrodes and contacts exist, including tip electrodes or contacts, ring electrodes or contacts, contact pads, patch electrodes, spring electrodes, or porous electrodes. Electrodes and contacts may also have a variety of configurations or patterns (e.g., unipolar, bipolar or multi-polar, array, etc.). In particular embodiments, the electrodes/contacts may be arranged according to international standard 1 (IS-1) that are used for low-voltage applications. The configuration may be unipolar or bipolar. A largest dimension of an IS-1 lead connector is 3.2 mm.
The lead adaptor enables an electrical and mechanical connection between the lead connector and the pulse generator. The lead adaptor may be used to upsize or downsize the lead connector in order to mate with the pulse generator. Optionally, the lead adaptor may also function as a lead extender that effectively increases the length of the lead.
Leads also include a lead connector positioned at the proximal end. The lead connector provides an electrical connection between the one or more electrodes of the lead and the one or more contacts of a control device (e.g., pulse generator). As described herein, the lead connector can also mate with a lead adaptor. The lead adaptor may then mate with the pulse generator to electrically connect the electrodes to the pulse generator and mechanically connect the lead to the pulse generator.
A lead may be delivered and positioned relative to tissue using an introducer sheath. An introducer sheath is a tube or cannula that is introduced into the body (e.g., through the vascular system, for example), typically over another elongated instrument, such as a needle, dilator, or guidewire. The introducer sheath includes a lumen that permits passage of other elongated instruments, such as the lead. The introducer sheath may form part of a delivery system (or kit) that includes one or more other elongated instruments, such as a needle, a guidewire, a syringe, a dilator, and one or more other sheaths. In particular embodiments, the introducer sheath is non-splittable or non-peelable. In particular embodiments, the introducer sheath is an intravascular sheath having at least one lumen.
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In
Although not shown, the IMD 50 may wirelessly communicate with an external device. For example, the external device may initiate the pulse generator 52. The external device and the pulse generator may communicate identification data (e.g., obtain model and serial number) between one another. The external device may generate a chart that correlates to the patient having the pulse generator 52. The external device may instruct the pulse generator 52 to perform an electrode integrity check and measure parameters of the electrodes (e.g., impedance of shock electrode(s)). The external device and/or the pulse generator may determine a sensing configuration for the pulse generator based on cardiac activity. During initiation of the pulse generator 52, therapy parameters may be selected by the user of the external device.
The lead 106 includes a plurality of electrodes 120, 122 positioned at the distal end 110. The electrodes 120, 122 are arranged in a bipolar configuration but other configurations may be used. The lead 106 also has a lead connector 124 positioned at the proximal end 112. The lead connector 124 includes a portion of the lead body 107 and lead contacts 126, 128 that are communicatively coupled to the electrodes 120, 122 through a plurality of conductors (not shown) that are contained within the lead body 107. In the illustrated embodiment, the lead body 107 is iso-diametric such that a diameter of the lead 106 is essentially uniform throughout. The iso-diametric body 107 may permit an introducer sheath (not shown) to slide over the lead connector 124 when the introducer sheath is removed.
Various combinations of the electrodes and contacts may be used in connection with sensing cardiac signals and/or delivering stimulation therapies. For example, the electrodes 120, 122 include a tip electrode 120 and a ring electrode 122, and the lead contacts 126, 128 include a tip contact 126 and a ring contact 128. In other embodiments, however, the electrodes and contacts may include any number of electrodes/contacts and have a variety of types or shapes.
As described herein, the lead body 107 may have a body outer envelope that is configured to fit within a lumen of an introducer sheath and the lead connector 124 has a connector outer envelope configured to fit within the lumen of the introducer sheath. The lead body 107 includes an insulating sheath or housing of a suitable insulative, biocompatible, biostable material such as, for example, silicone rubber or polyurethane, extending substantially the entire length of the lead body and surrounding the conductors.
The lead adaptor 108 is configured to interconnect the implantable lead 106 and the pulse generator 102. As shown, the lead adaptor 108 has an insertable connector 132 that includes mating contacts 134, 136. The lead adaptor 108 also includes and an adaptor cavity 138 that includes cavity contacts. The cavity contacts are positioned to engage the lead contacts 126, 128 of the lead connector 124 when the lead connector 124 is inserted into the adaptor cavity 138 of the lead adaptor 108. The insertable connector 132 is configured to be inserted into the connector cavity 103 of the pulse generator 102.
The connector assembly 206 includes an electrical connector 210 coupled to a trailing end of handle 204. The electrical connector 210 is electrically coupled to one or more electrodes along the introducer sheath 202. In the illustrated embodiment, the electrical connector 210 is communicatively coupled to electrodes 270, 272 (
The handle 204 may include a hemostasis hub 212 for accepting and coupling to (e.g., tethering to) a proximal end of the introducer sheath 202. The introducer sheath 202 has a sheath lumen 250 (
The introducer sheath 202 is configured to introduce a lead into a designated anatomical region (e.g., a patient's heart). To this end, the introducer sheath 202 may include a plurality of sheath segments or portions. For example, the introducer sheath 202 may include a proximal segment 221, a body segment 222, a deflectable segment 223, and a distal end segment 224 having an atraumatic distal tip 225. Based on its intended use, the introducer sheath 202 may be configured to exhibit various properties. For example, the introducer sheath may be maneuverable and have a sufficient columnar strength for being inserted through a tortuous vascular system. The introducer sheath may also have sufficient kink-resistance so as to bend smoothly. Multiple layers of the introducer sheath may be configured to have these and other properties.
Optionally, the inner layer 230 may include at least one rib or wedge 232 that protrudes radially from the outer surface of the inner layer 230. The rib 232 may extend entirely or nearly entirely from the proximal end to the distal end of the introducer sheath 202. In the illustrated embodiment, the inner layer 110 includes two ribs 232 that extend substantially parallel to one another on diametrically opposed surfaces of the inner layer 230. In other embodiments, however, the introducer sheath 202 does not include (or is devoid of) the ribs 232.
As an example, the inner layer 230 may be formed from a free-flowing fine powder form of PTFE mixed with a lubricant, such as a hydrocarbon fluid, including, but not limited to, Naphtha solvents, C9-C15 hydrocarbons or isoparaffinic hydrocarbons, or mineral spirits to create a paste. One or more particulate ingredients may be added to the paste, including radiopaque fillers, such as barium sulfate, inorganic pigments, and/or reinforcing nanoclay particles. The paste may be compression-molded into a preform of an appropriate shape, such as a hollow or solid cylinder. The preform may then be formed into the tubular inner layer 230 using a paste or ram extrusion process. Following extrusion, the inner layer 230 may be subjected to a series of processing ovens at sequentially increasing temperatures to flash off the lubricants and to partially or completely sinter (or thermally fuse) the PTFE powder particles. By ram extruding the PTFE paste at high pressures, the PTFE powder particles will form platelet-like fibrils oriented in the axial or extrusion direction. Optionally, the outer surface of the inner layer 230 is chemically activated through physical and/or chemical surface treatment methods, including chemical plasma treatment or chemical etching processes known in the art.
In some embodiments, the introducer sheath 202 may include a braided layer 234 disposed over the inner layer 230 to enhance its columnar and torsional strengths of the introducer sheath 203. The braided layer 234 may include a plurality of metallic braids impregnated with one or more thermoplastic polymers. Examples of acceptable thermoplastic polymers include polyamides, such as nylon 11, nylon 12, nylon 612, and the like; polyesters, such as poly(butylene terephthalate), poly(ethylene terephthalate), and the like; and thermoplastic elastomers, such as poly(ether-block-amide) copolymer resins, poly(ether-co-ester) block copolymer resins, and various thermoplastic polyurethane block copolymer resins. The thermoplastic polyurethane block copolymer resins can have different hard and soft segment chemistries, including, but not limited to, polyether-based aromatic or aliphatic polyurethanes, polyester-based aromatic or aliphatic polyurethanes, polycarbonate-based aromatic and aliphatic polyurethanes, silicone-containing polyether-based aromatic or aliphatic polyurethanes, silicone-containing polycarbonate-based aromatic or aliphatic polyurethanes, or any combinations thereof.
Optionally, the braided layer 234 may include two C-shaped sections 240 and 242 in which each of the sections 240, 242 is positioned on each side of the two ribs 232. The sections 240, 242 may extend along an entire length of the introducer sheath 202 or may extend only through the proximal segment 221 and the body segment 222. Methods of forming the braided layer 234, as well as other layers of the introducer sheath, are described in greater detail in Attorney Docket No. 13604USO1, filed on Jun. 25, 2019, which is incorporated herein by reference in its entirety.
The introducer sheath 202 also includes an outer layer 238 disposed over the C-shaped sections 240 and 242 of the braided layer 234. The outer layer 238 extends along an entire length of introducer sheath 202 and may provide or enhance the columnar strength in the proximal segment 221 and the body segment 222 and permit the deflectable segment 223 to be flexible. The outer layer 238 may be formed from different polymers capable of being extruded to desired dimensions and capable of providing desired properties.
The sheath lumen 250 extends continuously through introducer sheath 202 along its entire length. The sheath lumen 250 may have a diameter that is slightly larger than the diameter of the implantable lead to be delivered to the heart by delivery system 200. For example, the sheath lumen 250 may have a size of about 7.5 French (a diameter of about 2.5 mm) to accommodate a 7 French implantable lead (having a diameter of about 2.33 mm).
The introducer sheath 202 may also include a pull wire 252 that extends through a wall of the introducer sheath 202. For example, the pull wire 252 may extend through a tube 254 extending along the length of the introducer sheath 202 between the braided layer 234 and the outer layer 238. As another example, the tube 254 may be positioned between the inner layer 230 and the braided layer 234. The tube 254 may be formed from a material that will resist collapsing or kinking during the manufacture of the introducer sheath 202 and the use of the delivery system 200. Optionally, the tube 254 may include metal braids to further enhance its kink resistance.
The pull wire 252 may be welded or otherwise affixed at its distal end to a pull wire retainer 256 and may be connected at its proximal end to an operating mechanism in the handle 204. The pull wire retainer 256 may be axially located in the distal end segment 224 of the introducer sheath 202 and fixed (e.g., embedded) in place between the braided layer 234 and the outer layer 238 or between the inner layer 230 and the braided layer 234. In the illustrated embodiment, the pull wire retainer 256 is a ring embedded within the introducer sheath 202, but the pull wire retainer 256 may have other shapes or configurations (e.g., C-shaped segment).
The distal end segment 224 of the introducer sheath 202 may also include one or more electrodes. For example, the distal end segment 224 includes a pair of split-mapping electrodes 270 and 272. The electrodes 270 and 272 are electrically connected to connector assembly 206 via electrical conductors 280. Any suitable material, such as platinum-iridium, may be used to form the electrodes 270 and 272. In the illustrated embodiment, the electrodes 270, 272 are diametrically opposed to one another on opposite sides of the introducer sheath 202. Optionally, the electrodes 270, 272 may be spaced apart in the circumferential direction by, for example, between about 1 mm and about 3 mm.
The electrical conductor 280 may extend from each of electrodes 270 and 272 through a narrow tube 260 extending along the length of the introducer sheath 202 between the braided layer 234 and the outer layer 238 or between the inner layer 230 and the braided layer 234. The tube 260 may be formed from the same polymer used to form the tube 132 and may optionally include metal braids to enhance kink resistance. Upon exiting the tube 260, the electrical conductors 280 may travel through a lumen (not shown) in the handle 204 and through a conduit 211 to an electrical connector 210 (
In the illustrated embodiment, the electrodes 270 and 272 are split-mapping electrodes and do not fully circumscribe the introducer sheath 202. The electrodes 270, 272 may be secured to the introducer sheath 202 so as to not become detached therefrom upon advancement of the introducer sheath 202 through the patient's vascular system to deliver the implantable lead to the bundle of His 30 or during removal of the introducer sheath from the patient following such procedure. Accordingly, while the electrodes 270 and 272 may be positioned at the tip of the distal end of the introducer sheath 202 to thereby be exposed on the distal end face of the introducer sheath 202, the electrodes 270, 272 may be spaced from the tip so as to be surrounded on all sides by a continuous mass of the sheath polymer.
The electrodes 270 and 272 may be positioned based on the direction in which the distal tip of the introducer sheath deflects. For example, the electrodes may be positioned so that, when the introducer sheath is deflected, the electrodes are generally aligned in the direction in which the fibers of the bundle of His are oriented. A maximum signal will be detected from the bundle of His when both the electrode 270 and the electrode 272 are located directly thereover. More specifically, if the electrodes 270 and 272 are oriented on opposite sides of a deflection plane when the introducer sheath 202 is deflected, only one electrode at a time will be able to be located over the bundle of His 30. As introducer sheath 202 is moved relative to the atrial septal wall in an area in close proximity to the His bundle, one electrode may move closer to the His bundle while the other electrode may move away from the His bundle, such that the maximum possible signal will not be obtained. On the other hand, by positioning both of electrodes 270 and 272 in the deflection plane, both electrodes can lie over the bundle of His 30 at the same time. In fact, as introducer sheath 202 is moved across the atrial septal wall, there will be a distance equal to about the diameter of the introducer sheath within which the maximum His bundle signal can be detected.
The handle 204 may also include a conduit 290 having a connector 292 at a proximal end of the handle 204 for connecting to a source of flushing fluid. The conduit 290 may be connected to a further conduit (not shown) that travels through the handle 204 to hub 212 for supplying the flushing fluid to flush the interior of the introducer sheath 202. The conduit 211, having the electrical conductors 280 extending therethrough, may be connected at one end to the conduit 290 by a Y-splitter, and at the other end may be connected to the electrical connector 210. The electrical conductors 280 travel from the electrodes 270 and 272 through narrow tubes 260 and through the handle 204 and exit therefrom through the conduits 290 and 211, and are then connected by soldering or the like to the electrical connector 210.
In the illustrated embodiment, the insertable connector 132 and the receptacle connector 144 have fixed positions with respect to each other and directly couple to each other. In other embodiments, an intermediate portion (not shown) of the lead adaptor 108 may extend between and join the insertable connector 132 and the receptacle connector 144, thereby increasing a length of the lead assembly 104 (
As shown in
The first conducting portion 150 includes a pin extension 166 and a barrel section 168 that defines a receiving hole 170. The pin extension 166 projects in an axial direction away from the barrel section 168. The receiving hole 170 is an opening or space that is sized to receive the lead contact 126 (
The first insulating portion 152 surrounds the first conducting portion 150 and electrically isolates the first conducting portion 150 and the second conducting portion 154 from each other. The second conducting portion 156 also includes a pin extension 176 and a barrel section 178. However, the second conducting portion 156 includes a bore 174 that extends through the second conducting portion 156. A portion of the bore 174 receives the pin extension 166 of the first conducting portion 150 and the first insulating portion 152 surrounding the pin extension 166. Another portion of the bore 174 receives the barrel section 168 of the first conducting portion 150 and the first insulating portion 152 surrounding the barrel section 168. In the illustrated embodiment, the first insulating portion 152 is a single layer molded around the first conducting portion 150. In other embodiments, however, especially for those in which the first conducting portion 150 has multiple elements, the first insulating portion 152 may have multiple layers or multiple discrete sections.
The second insulating portion 156 is sized to cover a majority of an outer surface of the second conducting portion 154, except for an exposed area 180. The exposed area 180 may represent the second mating contact 136. The first insulating portion 152 may be sized to provide a leading flange 182. The leading flange 182 separates an end of the second conducting portion 154 from the first mating contact 134 of the first conducting portion 150. In the illustrated embodiment, the first and second insulating portions 152, 156 are shaped to include sealing rings 184, 186, respectively. Again, although the first and second insulating portions are each shown as a separate single continuous part, each of the first and second insulating portions may include multiple parts. This may also be characterized as having more insulating portions (e.g., third insulating portion, fourth insulating portion, etc.).
Also shown, the lead adaptor 108 may include one or more fasteners for securing the lead connector 124 (
When fully constructed, the lead adaptor 108 or a portion of the lead adaptor 108 may essentially match a unified or industry standard. For example, the lead adaptor 108 is configured to match the IS-1 standard for bipolar low-voltage/pacing applications. In other embodiments, however, the lead adaptor 108 may be configured to match other unified or industry standards or to have non-standard designs.
In some embodiments, the insertable connector 132 is configured to match a unified or industry standard for being inserted into the connector cavity 103 (
The lead adaptor 108 effectively increases a size of the lead connector 124, which may be referred to as “upsizing.” More specifically, the lead connector 124 is now usable because it can be electrically connected to the pulse generator 102. In other embodiments, the lead adaptor 108 may effectively decrease the size of the lead connector (downsize) or, yet in other embodiments, may not change a size of the lead connector.
The insertable connector 132 of the lead adaptor 108 has an insertable envelope 135. As used herein, an “envelope” represents a three-dimensional space that can be occupied by an element. The insertable envelope 135 of the insertable connector 132 may be larger than the sheath lumen 250 (
The adaptor cavity 138 is defined by multiple elements. For example, the adaptor cavity 138 includes the hole 170 and a portion of the bore 174. Optionally, the receptacle connector 144 may include a strain-relief segment 190 that is attached to the barrel section 178 of the second conducting portion 154. For example, the strain-relief segment 190 surrounds an end of the barrel section 178. A portion of the strain-relief segment 190 extends beyond an end of the second conducting portion 154 such that the adaptor cavity 138 also includes a cavity portion 191 that is defined by the strain-relief segment 190. The strain-relief segment 190 may comprise a material that is more flexible than the second conducting portion 154.
As shown, the implantable lead 306 includes a fixation anchor 350 that is configured to engage a secure the distal end to tissue, such as the bundle of His. The fixation anchor 350 may constitute a first electrode of the implantable lead 306 and is illustrated as a helical screw. The implantable lead 306 also includes a second electrode 352, which is shown as a ring electrode in the illustrated embodiment. In some embodiments, the second electrode 352 may function as an anode and the first electrode 350 may function as a cathode. As shown, an electrical conductor 354 electrically connects the first electrode 350 to a lead contact 315 at a proximal end of the lead 306. An electrical conductor 362 electrically connects a lead contact 317 to the second electrode 352.
A portion of the implantable lead 306 forms a lead connector 324 that includes the lead contacts 315, 317 that is insertable into the receptacle connector 344. The receptacle connector 344 includes a connector block 356 and a connector block 358. The connector blocks 356, 358 align with and electrically couple to the lead contacts 315, 317, respectively. Fasteners 360, 362 are positioned adjacent to self-sealing septa that engage the lead connector 324 and urge the lead connector 324 against the receptacle connector 344, thereby establishing an electrical connection between the connector block 356 and the lead contact 315 and the connector block 358 and lead contact 317.
The lead adaptor 308 includes an electrical conductor 370 that communicatively couples the connector block 356 to a mating contact 380 and also includes an electrical conductor 372 that communicatively couples the connector block 358 to a mating contact 382. The insertable connector 332 of the lead adaptor 308 may be consistent with a predetermined standard, such as IS-1. The receptacle connector 344 may also be consistent with a predetermined standard.
The lead 406 also has a lead connector 424 positioned at the proximal end 412. The lead connector 424 includes a portion of the lead body 407 and lead contacts 426, 428 that are communicatively coupled to the electrodes 420, 422 through a plurality of conductors (not shown) that are contained within the lead body 407. The lead connector 424 may size and configured to be similar to an IS-1 connector or another unified or industry standard. However, the lead connector 424 is devoid of sealing rings that project radially away from an outer surface of the lead connector 424. The sealing rings may be effectively replaced by interior ridges of the lead adaptor 408.
As shown, the lead adaptor 408 includes a first sealing ridge 480 and a second sealing ridge 482 positioned within the adaptor cavity 438. The first and second sealing ridges 480, 482 may extend circumferentially around the adaptor cavity 438 and the lead connector 424. The first sealing ridge 480 is positioned to engage an insulating portion 484 of the lead connector 424, thereby electrically isolating the lead contacts 426, 428. The second sealing ridge 482 may engage an insulative outer surface of the lead 406 at a trailing edge 429 of the lead contact 428. By engaging the outer surface of the lead 406 behind the trailing edge 429, the second sealing ridge 482 separates the lead contact 428 from fluid outside of the lead adaptor 408 and stops movement or prevents movement of the lead connector 424 in a withdrawal direction.
Returning to
In other embodiments however, the body 506 may have other shapes, such as having an octagonal cross-section, rectangular cross-section, or triangular cross-section that is taken transverse to the longitudinal axis. Likewise, the recess may have another location and/or shape. For example, the recess may be cross-shaped or may be configured to receive multiple fingers or projections of the holding stylet.
In some embodiments, the fixation anchor is 502 is helically- or corkscrew-shaped and is secured to a plate or disc 510 that is coupled to the body 506. The fixation anchor 502 is electrically-conductive and comprises a suitable material for the cardiovascular environment (e.g., platinum-iridium). The plate 510 comprises MP35N (e.g., Nickel-Cobalt-Chromium alloy) that is also suitable material for the cardiovascular environment. The fixation anchor 502 may be welded to the plate 510, and the plate 510 may be welded to the body 506. In other embodiments, the holding spool can be machined to include a disc- or plate-shaped top.
The fixation anchor 502 and the plate 510 may constitute the distal tip of the implantable lead. When the lead (not shown) is rotated, the fixation anchor 502 is driven into the tissue (not shown) and the plate 510 is drawn closer to the tissue. The plate 510 may directly face and abut, including contact, the tissue when the fixation anchor 502 is fully embedded.
As shown in
The electrical conductor 520 is electrically coupled to one of the lead contacts (not shown) of the implantable lead. The electrical conductor 520, the body 506, and the plate 510 are portions of a common conductive pathway that is configured for at least one of pacing or sensing electrical activity of the heart. As described below, when the optional recess 508 is utilized, a holding stylet 522 may be inserted into the recess 508 to hold the distal end of the lead in position as the introducer sheath is withdrawn.
Also shown in
As used herein, a “cross-sectional profile” includes the outer surface (or outline) of an elongated instrument at a certain axial location of the elongated instrument. An outer envelope (e.g., of a lead body or a lead connector), on the other hand, may include an axial segment or portion of the lead. The outer envelope may account for localized features along that segment of the lead that extend radially outward, such as sealing rings or portions of an electrical contact, or biased segments or kinks in the lead. For example, a length of the outer envelope may be determined by the length of the designated lead segment (e.g., length of the lead connector) and the two-dimensional cross-section of this outer envelope may be determined by the maximum cross-sectional profile along this designated lead segment. For embodiments in which the lead 622 is iso-diametric, a cross-sectional profile and an outer envelope can be the same.
As shown, the body outer envelope 752 and the connector outer envelope 754 are defined by respective dimensions. For example, a dimension of the connector outer envelope 754 may be a diameter D1 that intersects a central longitudinal axis 790 of the lead 722. The dimension of the connector outer envelope 754 may also be a radius R1 that projects from the central longitudinal axis 790 to the outer surface. Similarly, a dimension of the body outer envelope 752 may be a diameter D2 that intersects the central longitudinal axis 790 of the lead 722. The dimension of the body outer envelope 752 may also be a radius R2 that projects from the central longitudinal axis 790.
The connector outer envelope 754 is configured to fit within the lumen 726 of the introducer sheath 724 for an entire length of the introducer sheath 724. The introducer sheath 724 may be similar or identical to the introducer sheath 202 (
Returning to
At 602, the delivery system 200 is provided. As described above, the delivery system 200 includes the introducer sheath 202, the handle 204 (
With a mapping device (not shown) coupled to the electrodes 270, 272 (
With the distal portion of the introducer sheath 202 fully within the right atrium, the implanter may operate the delivery system 200 to place the introducer sheath 202 in a deflected configuration. Deflecting the introducer sheath 202 may be accomplished by an actuator 235 (
If the electrodes 270, 272 are not receiving electrical signals, or if the signals are very faint, the implanter may maneuver the distal tip 225 of the introducer sheath 202 by small movements of the actuator 235 in either a forward or reverse direction to scan the atrial wall. These small movements of actuator 235 will deflect the deflectable section 223 of the introducer sheath 202 by small amounts toward or away from the proximal section 221 of the introducer sheath 202. The His bundle 670 is located when the signals received by the electrodes 270, 272 are strongest.
Once this mapping procedure has located the bundle of His, the distal end 632 of the implantable lead 622 can be secured to the desired location, at 608. More specifically, the implantable lead 622 can be secured to the His bundle by advancing a fixation anchor 680 out from the distal tip 225 of the introducer sheath 202 and rotating the implantable lead 622 within delivery system 200 to drive the fixation anchor 680 into the atrial septal wall.
Once the implantable lead 622 has been properly fixed to the tissue including the bundle of His 670, the introducer sheath 202 may be returned to a substantially straight configuration by rotating the actuator 235 in the direction opposite that used for deflection. The introducer sheath 202 may then be removed from around the lead 622. Optionally, at 610, a holding stylet 692 may operably engage the implantable lead 622 at the tip assembly or at a tip of the lead connector, thereby holding the implantable 622 in a substantially stationary position while the introducer sheath 202 is withdrawn. As described herein, the introducer sheath 202 may be withdrawn without splitting, peeling, or otherwise separating the introducer sheath 202 into sections.
With the implantable lead 622 operably engaged by a holding stylet (e.g., either of the holding stylets 692, 693), the holding stylet reduces the likelihood that the implantable lead 622 will be excessively moved or dislodged by the introducer sheath 202 as the introducer sheath 202 is withdrawn. Because the body outer envelope and the connector outer envelope of the implantable lead 622 fit within the sheath lumen 250, the introducer sheath 202 may slide over the entire implantable lead 622. For embodiments that include the holding stylet 692, the introducer sheath 202 may be completely removed because the length of the holding stylet 692 is at least about 2× the length of the introducer sheath 202. For embodiments that include the holding stylet 693, the introducer sheath 202 may be completely removed because the length of the holding stylet 693 is at least equal to the length of the introducer sheath 202. After the distal tip of the introducer sheath 202 clears the proximal end of the implantable lead 622, the introducer sheath 202 is removed, at 612.
At 614, the lead connector of the implantable lead 622 may be mated with a lead adaptor. Optionally, the lead adaptor may include a strain-relief segment that extends beyond an end of the body of the lead adaptor. At 616, the lead adaptor may then be mated with the medical device. In particular embodiments, the lead adaptor may include an insertable connector having an insertable outer envelope that is larger than the lumen of the introducer sheath.
It will be readily understood that the components of the embodiments as generally described and illustrated in the Figures herein, may be arranged and designed in a wide variety of different configurations in addition to the described example embodiments. Thus, the more detailed description of the example embodiments, as represented in the Figures, is not intended to limit the scope of the embodiments, as claimed, but is merely representative of example embodiments.
Reference throughout this specification to “one embodiment” or “an embodiment” (or the like) means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment. Thus, appearances of the phrases “in one embodiment” or “in an embodiment” or the like in various places throughout this specification are not necessarily all referring to the same embodiment.
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the inventive subject matter without departing from its scope. While the dimensions and types of materials described herein are intended to define the parameters of the inventive subject matter, they are by no means limiting and are exemplary embodiments. Many other embodiments will be apparent to one of ordinary skill in the art upon reviewing the above description. The scope of the inventive subject matter should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. Further, the limitations of the following claims are not written in means-plus-function format and are not intended to be interpreted based on 35 U.S.C. § 112(f) unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.