Patent Application
20140114387
The present invention relates to medical apparatus and methods. More specifically, the present invention relates to implantable therapy leads and methods of using such leads.
Implantable therapy leads may be configured for active fixation. A common arrangement for a lead configured for active fixation provides a lead distal end with an active fixation helix that extends from the distal end of the lead when an IS-1 connector pin is rotated at a proximal end of the lead. As the connector pin is rotated clockwise, the sharp helix rotates and extends from the lead distal end to screw into myocardial tissue. Such an active fixation helix arrangement is mechanically complex and expensive to manufacture.
Because the helix can also serve as an electrode for pacing and sensing functions of the lead, such a helix arrangement has the disadvantage that the helix is not fixedly connected to the electrical conductors extending through the lead between the helix and the IS-1 connector pin. The loose connection between the helix and the electrical conductors can cause electrical noise in the sense amplifier of the pacemaker or implantable cardioverter defibrillator (ICD) electrically connected to the IS-1 connector pin. This electrical noise is known as “chatter”.
There is a need in the art for an active fixation lead that is less mechanically complex and expensive to manufacture. There is also a need in the art for an active fixation lead that substantially, if not totally, eliminates chatter associated with the helix electrode circuit.
An implantable therapy lead is disclosed herein. In one embodiment, the therapy lead is configured for active fixation to heart tissue. The lead includes a tubular body, an opening, an obturator, and a helical anchor. The tubular body includes a distal end, a proximal end opposite the distal end, and a longitudinal axis extending between the proximal end and distal end. The opening is defined in the distal end generally coaxial with the longitudinal axis. The obturator includes an outer cylindrical surface and is displaceable along the longitudinal axis between a recessed position and an extended position. The obturator is at least substantially located within the distal end proximal the opening when the obturator is in the recessed position, and the obturator extends substantially distal the opening when the obturator is in the extended position. The helical anchor extends from the opening generally coaxial with the longitudinal axis and positionally fixed relative to the distal end. The helical anchor includes a longitudinal center axis and a distal tissue penetrating point. The point is configured such that, when the obturator is in the extended position within the helical anchor, an extreme distal tip of the point and the outer cylindrical surface make surface contact in such a manner that the point is generally prevented from cutting or abraiding the patient's blood vessel wall while the lead is being inserted into the patient. Once the lead tip is located at the location where it is to be screwed into the myocardium, the obturator is allowed to slide back into the lead body toward the proximal end of the lead so that the helix can advance into the tissue.
The lead may also include a connector assembly near the proximal end. The connector assembly includes an electrical contact in electrical communication with the helical anchor. The helical anchor is also configured to act as an electrode in addition to serving as a mechanism for active fixation. In some embodiments, the helical anchor is not electrically active, but simply acts as an anchor. In such a non-electrically active embodiment, the helical anchor may be formed of metal or even of non-electrically conductive materials.
In one embodiment, the obturator is biased towards the recessed position.
In one embodiment, the surface contact is at least partially a result of the tip making generally tangential surface contact with the outer cylindrical surface. In other words, the surface contact is at least partially a result of the tip intersecting the outer cylindrical surface in a generally flush manner.
In one embodiment, the helical anchor includes a wire-like member helically wound into multiple coils. A most distal coil distally terminates in the point and includes a radially inner curved boundary and a radially outer curved boundary opposite the radially inner curved boundary. The point proximally begins on the radially outer curved boundary and distally terminates in the tip at the radially inner curved boundary. The point includes a bevel having a proximal border on the radially outer curved boundary and a distal border in a form of the tip on the radially inner curved boundary. The bevel includes a curved surface or planar surface between the proximal border and the tip. The tip is defined at least in part by an intersection of the radially inner curved boundary and the bevel.
A method of implanting an active fixation implantable therapy lead is also disclosed herein. In one embodiment, the method includes: a) negotiating the lead through a cardiovascular system of a patient with an obturator of the lead in an extended position wherein an extreme distal tip of a tissue penetrating point of a helix anchor electrode contacts an outer surface of the obturator in a manner that prevents the extreme distal tip from being capable of cutting a blood vessel during implanting and preventing the helix anchor electrode from being screwed into tissue; b) allowing the obturator to move to a recessed position wherein the extreme distal tip no longer contacts the outer surface of the obturator and the extreme distal tip is positioned relative to the outer surface of the obturator so as to allow the extreme distal tip to penetrate tissue; and c) with the extreme distal tip and outer surface of the obturator positioned as recited in b), rotating the lead about a longitudinal axis of the lead to cause the helix anchor electrode to screw into the tissue.
Another implantable therapy lead is also disclosed herein. In one embodiment, the therapy lead is configured for active fixation to heart tissue. The lead includes a tubular body, an obturator, and a helical anchor electrode. The tubular body includes a distal end, a proximal end opposite the distal end, and a longitudinal axis extending between the proximal end and distal end. The obturator is displaceably supported on the distal end between a recessed position and an extended position. The helical anchor electrode is fixedly supported on the distal end and includes a tissue penetrating point including an extreme distal tip. When the obturator is in the extended position, the extreme distal tip of the tissue penetrating point of the helical anchor electrode contacts an outer surface of the obturator in a manner that prevents the extreme distal tip from being capable of tissue penetration significant enough to allow the helical anchor electrode to be screwed into the heart tissue. When the obturator is in the recessed position, the extreme distal tip no longer contacts the outer surface of the obturator and the extreme distal tip is positioned relative to the outer surface of the obturator so as to allow the extreme distal tip to penetrate the heart tissue.
While multiple embodiments are disclosed, still other embodiments of the present invention will become apparent to those skilled in the art from the following detailed description, which shows and describes illustrative embodiments of the invention. As will be realized, the invention is capable of modifications in various aspects, all without departing from the spirit and scope of the present invention. Accordingly, the drawings and detailed description are to be regarded as illustrative in nature and not restrictive.
An implantable therapy lead 20 (e.g., a CRT lead, etc.) and a method of using such a lead are disclosed herein. In one embodiment, the therapy lead 20 is configured for active fixation to heart tissue. The lead 20 includes a tubular body 22, an opening of a bore 64, an obturator 62, and an active fixation helical anchor electrode 82. The tubular body includes a distal end 34, a proximal end 26 opposite the distal end, and a longitudinal axis extending between the proximal end and distal end. The opening of the bore 64 is defined in the distal end 34 generally coaxial with the longitudinal axis. The obturator 62 includes an outer cylindrical surface 92 and is displaceable along the longitudinal axis between a recessed position (see
The helical anchor 82 extends from the opening of the bore 64 generally coaxial with the longitudinal axis and positionally fixed relative to the distal end 34. The helical anchor 82 includes a longitudinal center axis and a distal tissue penetrating point 88. The point 88 is configured such that, when the obturator 62 is in the extended position within the helical anchor 82, an extreme distal tip 90 of the point 88 and the outer cylindrical surface 92 make surface contact in such a manner that the point 88 is generally prevented from biting into the blood vessels or heart tissue when the helical anchor 82 is moved or rotated against tissue.
At least in part because the active fixation helix anchor electrode 82 is permanently fixed to the both the structure of the distal region of the lead body and the electrical conductor extending between the helix electrode 82 and the pin contact 33 of the connector assembly 28, the helix electrode configuration disclosed herein is both electrically and mechanically stable. As a result, the helix electrode configuration eliminates eliminating (or at least substantially reduces) the associated electrical noise (i.e., chatter) and also reduces the associated manufacturing complexity and costs.
To begin a detailed discussion of the lead 20, reference is made to
The connector assembly 28 is constructed using known techniques and is preferably fabricated of silicone rubber, polyurethane, SPC, or other suitable plastic. Electrical contacts 32, 33 are preferably fabricated of stainless steel or other suitable electrically conductive material. The lead 20 is constructed to include a hollow interior extending from the proximal end 26 to a distal end 34. The hollow interior allows for the introduction of a stylet, guidewire or other device during implant, which is beneficial in allowing the surgeon to guide the otherwise flexible lead 20 from the point of venous insertion to the myocardium.
As shown in
The construction of the electrode assembly 36 of
Lead conductor 51 is crimped to crimp tube 41, which is in electrical contact with ring electrode 40, thereby establishing an electrical connection between conductor 51 and electrode 40. The conductor 51 is in electrical communication with one of the ring contacts 32 of the connector assembly 28.
The conductive electrode 50 is preferably a unitary construction including at its proximal end a cylindrical portion 52 being secured by means of a press fit in an axial bore 54 that is defined by conductive annular sleeve 57. The helical coil conductor 56 extends through the lead body 22 of
As illustrated in
The electrode distal tip 60 is depicted as including an internal bore 64 defined by the inner annular surface of conductive electrode 50. The electrode materials for the electrode distal tip 60 are preferably a base metallic material, optimally a platinum-iridium alloy or similarly conductive biocompatible material. In one embodiment, the platinum-iridium alloy has a composition of about 90% platinum and 10% iridium by weight.
As indicated in
As shown in
For a detailed discussion of the helix anchor electrode 82 in the vicinity of the point 88, reference is now made to
As best understood from the enlarged view of the point 88 depicted in
As can be understood from
The obturator 62 may be formed of an electrically non-conductive, biocompatible material. In one embodiment, the obturator 62 may be configured to contain and deliver over time a therapeutic agent. For example, in one embodiment, the obturator 62 may be at least partially formed of or support a mixture of copolymeric Lactic/Glycolic acid (PLA/GLA), polylactic acid, polyglycolic acid, polyamino acid, or polyorthoester and a desirable therapeutic, up to 50% by weight, such as dexamethasone sodium phosphate for the minimization of inflammation resultant from foreign body reactions to the surrounding tissue. The obturator releases the desired therapy (e.g., steroid) over time to counter the commonly known undesirable side effects of the implant, i.e., inflammation. Because the obturator 62 with its therapeutic are at the center of the helical electrode 82, the therapeutic can be delivered to the myocardium, very close to the site of implantation of the helical electrode 82.
As can be understood from a comparison of
In an alternative embodiment, a helical spring (not shown) may be positioned in the bore 54 to act between the distal face of the base 55 and the proximal edge of the conductive electrode 50 located in the bore 54, thereby biasing the obturator 62 proximally to recess the obturator 62 within the confines of the distal end of the lead unless distally displaced by the stylet 66 urging the base 55 and the obturator 62 distally. Thus, to place anchor 82 in condition to be screwed into tissue, the stylet only needs to cease pushing distally on the base 55, thereby allowing the obturator 62 to recess to expose the helix tip 88 such that the helix tip will be able to bite into tissue.
As can be understood from
For a discussion of a method of employing the lead disclosed herein, reference is made to
As can be understood from
As represented in
As indicated in
If helix electrode relocation is needed after the helix is screwed into the myocardium, the stylet can be reinserted, the helix unscrewed via counter-clockwise rotation of the entire lead body, and the obturator will slide back into the helix by gentle pressure on the stylet. The helix electrode can then be relocated.
The mechanical characteristics of the helix tip and obturator tip design allow electrical mapping during placement of the electrode. At the candidate site, the helix can be pressed against the myocardium with the obturator released. Pacing and sensing thresholds can then be assessed and if adequate, the helix can be screwed into the myocardium. If thresholds are not adequate, the obturator can be re-extended and the lead tip moved to another site.
An additional advantage with respect to torque transfer is provided by the lead embodiment disclosed herein. For example, commonly known leads often require about a five to one turn ratio between the lead connector and the helix, which means that 10-15 turns are required at the connector to fix the helix. With the lead embodiment disclosed herein, because the helix is fixedly coupled to the lead body, the entire lead body structure can be used to transmit torque, not just the inner conductor coil and, as a result, fewer rotations are need to fix the helix in tissue.
Although the present invention has been described with reference to preferred embodiments, persons skilled in the art will recognize that changes may be made in form and detail without departing from the spirit and scope of the invention.
