U.S. patent application number 13/457747 was filed with the patent office on 2012-08-23 for lead retention and sealing device.
This patent application is currently assigned to Medtronic, Inc.. Invention is credited to Richard A. Bruchmann, Michael R. Klardie, John E. Lovins, Kathleen P. Macke, Andrew J. Ries, Randy S. Roles, Eric J. Wengreen, Jennifer J. Zhao.
Application Number | 20120215296 13/457747 |
Document ID | / |
Family ID | 42785196 |
Filed Date | 2012-08-23 |
United States Patent
Application |
20120215296 |
Kind Code |
A1 |
Ries; Andrew J. ; et
al. |
August 23, 2012 |
LEAD RETENTION AND SEALING DEVICE
Abstract
This application discusses, among other things, a header
assembly for coupling a medical electrical lead to a medical
stimulating device including a header having a capture mechanism
within a bore of a lead retention device. In an example, when the
lead retention device is retracted from the bore, the capture
mechanism prevents the device from falling out. In another example,
the header assembly has a vent disposed within the bore of the lead
retention device that permits unrestricted flow of air when the
lead retention device is retracted from an engagement surface.
Inventors: |
Ries; Andrew J.; (Lino
Lakes, MN) ; Wengreen; Eric J.; (Blaine, MN) ;
Klardie; Michael R.; (Bloomington, MN) ; Zhao;
Jennifer J.; (Simi Valley, CA) ; Bruchmann; Richard
A.; (Andover, MN) ; Macke; Kathleen P.; (Hugo,
MN) ; Lovins; John E.; (Oakdale, MN) ; Roles;
Randy S.; (Elk River, MN) |
Assignee: |
Medtronic, Inc.
|
Family ID: |
42785196 |
Appl. No.: |
13/457747 |
Filed: |
April 27, 2012 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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12410124 |
Mar 24, 2009 |
8190260 |
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13457747 |
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Current U.S.
Class: |
607/116 |
Current CPC
Class: |
A61N 1/3752
20130101 |
Class at
Publication: |
607/116 |
International
Class: |
A61N 1/05 20060101
A61N001/05 |
Claims
1. An implantable medical device (IMD) header assembly, comprising:
a header; a connector block disposed within the header, the
connector block including a lead bore and a setscrew bore, the lead
bore having a transverse orientation relative to and being in
communication with setscrew bore; and a capture mechanism disposed
within a sidewall of the setscrew bore, wherein the capture
mechanism comprises a protruding member disposed proximate to the
exterior opening of the setscrew bore.
2. The IMD header of claim 1, wherein the protruding member is a
reflowed post that partially covers the exterior opening of the
setscrew bore.
3. The IMD header of claim 1, wherein the protruding member is a
washer that partially covers the exterior opening of the setscrew
bore.
4. The IMD header of claim 1, further comprising a setscrew having:
a head portion integrally formed with a shank portion, the head
portion having an engagement segment configured for engagement with
a torque wrench, wherein the shank portion has a threaded outer
surface configured for coupling to a mating threaded bore of the
IMD; a necked region disposed between the head portion and the
shank portion; and an insulating coating substantially
encapsulating the head portion to electrically isolate the head
portion, wherein the insulating coating is placed in substantial
compression when torque is applied to the head portion.
5. The IMD header of claim 1, further comprising a setscrew having
a vent channel disposed within the setscrew bore.
Description
CROSS REFERENCE TO RELATED APPLICATIONS
[0001] This application is a divisional of U.S. application Ser.
No. 12/410,124, filed on Mar. 24, 2009, now allowed. Reference is
also made to commonly-assigned and co-pending application U.S. Ser.
No. 12/410,233, Attorney Docket No. P0028700.00, filed Mar. 24,
2009, entitled "Full Visibility Lead Retention;" and U.S. Ser. No.
12/410,203, Attorney Docket No. P0026574.00, filed Mar. 24, 2009,
entitled "Lead Retention and Sealing Device," now issued U.S. Pat.
No. 8,032,221, all of which are herein incorporated by reference in
their entirety.
TECHNICAL FIELD
[0002] The present disclosure generally relates to implantable
medical devices. More specifically and without limitation, this
disclosure relates to headers and setscrews for implantable medical
devices.
BACKGROUND
[0003] Many implantable medical devices such as pacemakers,
defibrillators and neural stimulators deliver electrical therapy to
tissue and sense various physiological parameters via medical
leads. Such leads typically include an elongated flexible lead body
with one or more electrodes disposed at a distal end of the lead.
The electrodes are connected to a terminal pin on the lead's
proximal end by conductors that are disposed within the lead
body.
[0004] The lead is typically coupled to a header of the implantable
medical device with a proximal portion of the lead being secured
within the header to prevent the lead from dislodging. In general,
the header has a connector block that includes a lead bore into
which the lead's proximal portion is received. The connector block
also includes a threaded setscrew bore that intersects with the
lead bore. The setscrew bore receives a setscrew that engages the
lead to secure it within the header.
[0005] The connector block is also coupled to a feedthrough pin,
which passes through hermetic seals to connect with input and/or
output nodes of the implantable medical device's electronic
circuitry. Typically, the connector block is formed from a
conductive material, such as metal, thereby permitting electrical
connectivity between the lead and the electronic circuit.
[0006] To provide a reliable connection of the lead within the
connector block, the setscrew is typically comprised of metal.
Thus, the contact with the electrically active connector block
causes the setscrew to be electrically active. Exposure of the
setscrew to adjacent body tissue and body fluids might result in
undesired electrical conduction to the adjacent tissue.
Additionally, because the setscrew bore intersects with the
terminal pin of the lead, ingress of fluid into the setscrew bore
may result in the fluid contacting the terminal pin and this may
compromise the device's delivery of electrical therapy.
Consequently, a septum, typically referred to as a grommet, is
disposed within the setscrew bore to cover the setscrew, thereby
sealing the setscrew bore and isolating the electrically active
setscrew from body fluids. In one example, the grommet is a
silicone disk that has an elastic quality and has a slit that
allows passage of a screw driver for tightening the setscrew and
re-seals upon removal of the torque wrench to block entry of body
fluids. Additionally, when the shank of the setscrew is disengaged
from the threaded bore, the grommet retains the setscrew and
prevents it from falling out.
[0007] While the use of a grommet has been satisfactory at
preventing entry of fluids into the device and contact between the
electrically active setscrew and surrounding tissue, it also
substantially obstructs the visibility of the lead's terminal pin
within the connector block. Lead tip visibility is an indicator of
full lead insertion into the conductive block. The visibility
enables verification that a proper and secure electrical and
mechanical connection between the lead and the conductive block has
been made.
BRIEF SUMMARY
[0008] Embodiments of the present disclosure provide, among other
things, a setscrew that enables lead tip visibility as an indicator
of full lead insertion without requiring a grommet. In one
embodiment, a setscrew is provided having a metal core with an
insulative coating disposed over the core to electrically isolate
it from body fluids and surrounding tissue without requiring a
grommet In one embodiment, the setscrew incorporates a sealing
capability by including a sealing member that is coupled to the
setscrew. In another embodiment, the sealing member is disposed
within the setscrew bore to engage the setscrew. The sealing
capability seals the setscrew bore to prevent entry of body fluids
into the implantable medical device.
[0009] In one embodiment, the setscrew is provided with an
engagement segment on a head portion that is configured for
engagement with a torque wrench. In another embodiment, a
reinforcement sleeve is disposed on the setscrew head. In one
example, the reinforcement sleeve is disposed on the entire head.
In another example, the reinforcement sleeve is disposed on the
engagement segment of the head.
[0010] In another embodiment, an implantable medical device header
has a setscrew bore configured for engagement with a setscrew. The
setscrew bore is provided with an undercut that is formed at a
location proximate to the exterior opening of the setscrew
bore.
[0011] In another embodiment, the setscrew bore has a capture
mechanism that at least partially covers the exterior opening of
the setscrew bore. Thus, when the setscrew is retracted from the
threaded region of the bore, the capture mechanism prevents the
setscrew from falling out. In some embodiments, the capture
mechanism has a radial opening having a diameter that is less than
the diameter of the setscrew while still allowing insertion of a
torque inducing tool.
[0012] In another embodiment, an implantable medical device header
is provided with a lead bore and a setscrew bore with the setscrew
bore having a longitudinal axis that extends in a transverse
direction to, and in communication with, the lead bore. In one
example, the setscrew bore intersects with the lead bore at a
location that is offset from the central longitudinal axis of the
lead bore.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] The following drawings are illustrative of particular
embodiments of the present disclosure and therefore do not limit
the scope of the disclosure. The drawings (not to scale) are
intended for use in conjunction with the explanations in the
following detailed description, wherein similar elements are
designated by identical reference numerals. Moreover, the specific
location of the various features is merely exemplary unless noted
otherwise.
[0014] FIG. 1 is an illustration of an example implantable medical
device system that has a lead extending into a heart;
[0015] FIG. 2A shows a perspective view of a cut-out of the header
of FIG. 1 taken along lines 2-2;
[0016] FIG. 2B shows a perspective view of an alternative
embodiment of the header of FIG. 1 taken along lines 2-2;
[0017] FIG. 3 is a cross-sectional view of one embodiment of
setscrew 200;
[0018] FIGS. 4A-C illustrate perspective views of the coupling
between a torque wrench and a setscrew of the present
disclosure;
[0019] FIG. 5 shows a cross sectional view of header 140 taken
along lines 5-5 (FIG. 1);
[0020] FIGS. 6A-B illustrate cross sectional views of header 140 in
conjunction with a prior art setscrew;
[0021] FIG. 7 illustrates an alternative embodiment of a setscrew
of the present disclosure;
[0022] FIG. 8 illustrates another alternative embodiment of a
setscrew of the present disclosure;
[0023] FIG. 9A-B illustrate cross-sectional views of header 140 in
conjunction with setscrew 200 of FIG. 8;
[0024] FIG. 10 illustrates a perspective view of yet another
alternative embodiment of a setscrew of the present disclosure;
[0025] FIG. 11 illustrates a perspective view of an alternative
embodiment of a coupling of lead within a header;
[0026] FIGS. 12A-B illustrate alternative embodiments of a setscrew
of the present disclosure;
[0027] FIG. 13 illustrates a perspective view of a first embodiment
of a header of the present disclosure;
[0028] FIG. 14 illustrates a cross-sectional view of the header of
FIG. 13, in conjunction with a setscrew of the present
disclosure;
[0029] FIG. 15 shows a cross-sectional view of the header of FIG.
14 in connection with a lead;
[0030] FIGS. 16-17 illustrate an exemplary process for making the
header of FIG. 13;
[0031] FIG. 18A-B illustrate perspective views of a second
embodiment of a header of the present disclosure; and
[0032] FIG. 19 illustrates a perspective view of a third embodiment
of a header of the present disclosure.
DETAILED DESCRIPTION
[0033] The following description is exemplary in nature and is not
intended to limit the scope, applicability, or configuration of the
present disclosure in any way. Rather, the description provides
practical illustrations for implementing exemplary embodiments of
the present disclosure.
[0034] FIG. 1 is an illustration of an example implantable medical
device system 2 including an implantable medical device (IMD) lead
135 connected to an IMD 10. In some embodiments, IMD 10 takes the
form of a cardiac pacemaker, defibrillator, neurostimulator, muscle
stimulator, or gastric stimulator. As will be described in more
detail below, the proximal end of lead 135 is coupled to a header
140 of IMD 10. Lead 135 is secured in header 140 by a setscrew 200,
which will be described in more detail below. A distal end of lead
135 is coupled to an organ or any other desired tissue such as, for
example, a heart 4. IMD 10 delivers electrical stimulation to the
tissue and/or detects electrical activity via electrodes 136, 138.
The illustration of the embodiment of FIG. 1 showing IMD 10 coupled
to a single lead 135 is merely for ease of description of the
various aspects of the present disclosure and is not intended to be
limiting. For example, in one or more embodiments, IMD 10 is
coupled to a plurality of leads 135.
[0035] FIG. 2A is an isovolumetric sectional view of header 140
taken along lines 2-2 (FIG. 1). Header 140 includes a connector
block 150 comprised of a suitable biocompatible material that is
also electrically conductive such as titanium. Connector block 150
includes a lead bore 155 into which lead 135 is received. Connector
block 150 also includes a setscrew bore 165 which receives setscrew
200. Setscrew bore 165 is oriented to be in alignment with, and
intersect, lead bore 155. In other words, the central longitudinal
axis of setscrew bore 165 is oriented in a transverse direction,
relative to the longitudinal axis of lead bore 155. Therefore, when
setscrew 200 is threaded into setscrew bore 165, a distal tip 290
abuts lead 135 thereby securing it within header 140.
[0036] Setscrew 200 has a tool interface 300 that has a generally
cross-shaped external drive interface. An external drive interface,
generally, has faces that are aligned with the thread axis and face
outward. Tool interface 300 facilitates the threading of setscrew
200 into the setscrew bore 165.
[0037] A sealing member 230 is coupled to setscrew 200. The
engagement of sealing member 230 between setscrew 200 and setscrew
bore 165 seals the region of header 140 extending inwardly of
sealing member 230 to prevent penetration of body fluids. Sealing
member 230 can be any component that forms a fluid seal such as an
o-ring or wiper seal. In some embodiments, the material used to
form the seal is silicone.
[0038] FIG. 2B illustrates an alternative embodiment of the header
140 of FIG. 2A incorporating sealing member 230 onto setscrew bore
165. Thus, sealing member 230 is circumferentially disposed within
setscrew bore 165. In some embodiments, engagement of setscrew 200
compresses sealing member 230 against setscrew bore 165 or
connector block 150 to form a seal.
[0039] FIG. 3 is a cross-sectional view of one embodiment of
setscrew 200. Setscrew 200 includes a core 205 having a head
portion 220 and a threaded shank portion 210. Shank 210 has a
thread type compatible with a threaded setscrew bore 165 such, for
example, as a standard 2-56 UNC-2A screw thread. In one embodiment,
core 205 also includes a necked region 235. Necked region 235 is
formed between head portion 220 and shank 210 and has a narrower
diameter than head 220. In some embodiments, the sealing member 230
is coupled to necked region 235. Core 205 includes a shoulder 280
disposed between necked region 235 and shank 210. Shoulder 280 is
dimensioned to limit the downward movement of setscrew 200 by
abutting connector block 150 (FIG. 2A). In the illustrative
embodiment of FIG. 3, head portion 220 and shank 210 are integrally
formed to define unitary core 205. In some embodiments, core 205 is
comprised of a material having a high resiliency and strain
endurance with the ability to be deformed under stress without
cleaving such, for example, as a metal, organic metals or metallic
polymers. In other embodiments, the material is a suitable
biocompatible material and or is electrically conductive such, for
example, as gold, titanium or their alloys. In other embodiments,
core 205 does not significantly deform under typical loading
conditions such as the forces exerted during the assembly
process.
[0040] Setscrew 200 includes insulating coating 225 that is
disposed over a portion of core 205. In the illustrative
embodiment, insulating coating 225 is disposed over head 220 and
necked region 235. Insulating coating 225 will prevent exposure of
surrounding tissue or fluids to electrical current generated by IMD
10 (FIG. 1) and will prevent exposure of the lead 135 to the
electrical signals of the tissue outside the header. Insulating
coating 225 is generally a non-conductive material that has
dielectric properties. In one example, the material selected for
insulating coating 225 is a biocompatible dielectric material such
as polyaryletheretherketone (PEEK) thermoplastic, PARYLENE.RTM.
polyxylylene polymers, or a suitable polymer material. Insulating
coating 225 is coupled to core 205 by any conventional coating,
molding or deposition processes. Insulating coating 225 is applied
in a thickness to prevent electrical conduction via core 205 that
may arise from contact with the electrically active connector block
150. In an example where insulating coating 225 is primarily relied
upon to provide electrical insulation from the surrounding medium,
the thickness of insulating coating 225 is typically in the range
of about 0.1 mm to about 0.8 mm (0.0039 inches to 0.0315 inches).
However, the thickness of insulative coating 225 may also be
determined by the thickness necessary to ensure the force from a
wrench 302 (FIG. 4A) used to tighten and loosen the setscrew will
not jeopardize the dielectric integrity of the insulator by
tearing, cracking, penetrating, or otherwise weakening the
insulative coating 225.
[0041] FIGS. 4A-C illustrate the coupling between torque wrench 302
and setscrew 200. As shown in the exemplary embodiment of FIG. 4A,
tool interface 300 is configured such that it interfaces with
mating segment 304 of torque wrench 302. The apex of tool interface
300 may be configured to be a guiding surface such that it
facilitates the positioning of torque wrench 302 over the setscrew
200. As an example, the apex of tool interface 300 is formed as a
dome-shape. As illustrated in FIG. 4B mating segment 304 fits over
tool interface 300, in direct contact with insulating coating 225.
Thus, torque applied by torque wrench 302 is transferred to both
insulating coating 225 and tool interface 300. Due to insulating
coating 225 being trapped between torque wrench 302 and core 205,
the torque motion compresses insulating coating 225 against core
205. Accordingly, insulating coating 225 is placed primarily under
compressive stress, rather than shear stress. The underlying core
205 provides a high rigidity to insulating coating 225, which is
placed primarily in compression, thereby increasing the torque
bearing capability of setscrew 200.
[0042] FIG. 4C illustrates a cross sectional view of the coupling
of setscrew 200 to torque wrench 302. Prongs 306 of mating segment
304 fit in between the tool interface 300 walls. Thus, the torque
motion exerted by wrench 302 places insulating coating 225 in
compression against core 205.
[0043] With reference to FIG. 5, a cross sectional view of header
140 taken along lines 5-5 of FIG. 1 is illustrated. Lead 135 and
setscrew 200 are insertable into connector block 150 as described
above. As the view illustrates, lead 135 is engaged within
connector block 150 thereby providing the physical contact for
electrical connectivity of lead 135 with the electrical circuit
(not shown) of IMD 10. The engagement of lead 135 with connector
block 150 provides the electrical connectivity with the electrical
circuit. The overall diameter arising from the implementation of
setscrew 200 with a core 205 facilitates the visibility of the
engagement between lead 135 and connector block 150. Accordingly,
the engagement of lead 135 with connector block 150 can be verified
visually based on the protrusion of lead 135 from the connector
block 150.
[0044] FIGS. 6A-B illustrate cross sectional views of assemblies of
header 140 with a prior art setscrew 100. FIG. 6A is a side cross
sectional view (similar to lines 1-1 of FIG. 1) showing lead 135
and a prior art setscrew 100, such as that disclosed in U.S. Pat.
No. 4,316,471 issued to Shipko et al., inserted into connector
block 150. Setscrew 100 includes a plastic head 120 that is coupled
to a threaded metal shaft member 110. Torque applied to head 120 is
transferred to shaft member 110 to threadedly engage setscrew 100
within header 140. The indirect transfer of torque from a
screwdriver (not shown) to shaft member 110, via head 120, places
head 120 under sheer stress. Due to the sheer stress loading, head
120 is formed with a large diameter to prevent tearing from the
sheering stress. Thus, setscrew 100 has an overall diameter that is
much larger in comparison to setscrew 200 (FIG. 3).
[0045] FIG. 6B illustrates the top cross sectional view (similar to
lines 2-2 of FIG. 1) of setscrew 100 inserted into header 140. As
illustrated, the large cross-sectional area of setscrew 100
obstructs visibility of connector block 150 and lead 135. As a
result of the obstructed visibility, setscrew 100 inhibits visual
verification of the engagement, or lack of engagement, between lead
135 and connector block 150. Therefore, visual determination of
whether lead 135 is fully engaged, partially engaged, or fully
disengaged from connector block 150 is prevented.
[0046] Consequently, contrasting the assembly of FIG. 5 with the
assembly in FIG. 6B, setscrew 200 facilitates visibility of the
engagement between lead 135 and connector block 150. As described
above, due to setscrew 200 being formed with core 205 having both
head portion 220 and shank 210, the overall diameter of setscrew
200 is small, relative to setscrew 100, while maintaining the same
or better torque bearing ability. Moreover, while the overall
volume of setscrew 200 is much smaller compared to that of setscrew
100, the engagement capability of setscrew 200 is still sufficient
to prevent dislodgment of lead 135.
[0047] Turning now to FIG. 7, an alternative embodiment of setscrew
200 having a reinforcement sleeve 500 is illustrated. As described
above, insulating coating 225 is contemplated to come in contact
with torque wrench 302 during implantation. Depending on the
thickness and/or properties of insulating coating 225, or the
amount of force exerted, the contact may result in chaffing,
abrasion or other physical damage that could potentially compromise
the electrical insulation. Thus, reinforcement sleeve 500 is
disposed over insulating coating 225 to prevent damage that may
arise from improper contact between torque wrench 302 with
insulating coating 225 or other mishandling of setscrew 200.
Reinforcement sleeve 500 is comprised of a resilient and high
strain endurance material, for example, a metal. In certain
embodiments, the material is also a suitable biocompatible
material, for example, gold, titanium or their alloys. In one
example, the material for reinforcement sleeve 500 is an
electrically insulative material that provides electrical isolation
of setscrew 200. Reinforcement sleeve 500 is coupled to setscrew
200 through any suitable bonding method such, for example, as
adhesion with an adhesive compound. In one embodiment,
reinforcement sleeve 500 is bonded to head 220, over insulating
coating 225. While not intended to be limiting, the exemplary
embodiment shows reinforcement sleeve 500 enveloping a portion of
head 220.
[0048] FIG. 8 illustrates another embodiment of setscrew 200 of the
present disclosure. In this embodiment, setscrew 200 has shank 210
detachedly coupled to head 220. Head 220 includes an opening 605
that is disposed on distal end 600 into which a coupling segment
615 of shank 210 is received. In one example, opening 605 and
coupling segment 615 are configured in an interlocking manner such
as a lock and key arrangement such that coupling segment 615 is
configured to fit into opening 605.
[0049] FIG. 9A-B illustrate cross-sectional views of header 140 in
conjunction with setscrew 200 of FIG. 8. In the illustration of
FIG. 9A, coupling segment 615 (FIG. 8) is fully inserted within
opening 605 (FIG. 8). Head 220 is configured to be positioned at a
stationary location within setscrew bore 165. As such, vertical
motion of head 220 is inhibited but rotational motion is allowed.
In this embodiment, when torque is applied to setscrew 200, head
220 rotates about the stationary location and the rotational
movement causes vertical motion of shank 210 due to the engagement
of the setscrew's threads with the connector block's threads.
[0050] As shown in FIG. 9B, rotation of head 220 causes shank 210
to be advanced into setscrew bore 165 to abut lead 135.
Alternatively, head 220 can be rotated in the counter direction to
retract shank 210 causing it to disengage lead 135.
[0051] FIG. 10 illustrates a perspective view of yet another
embodiment of setscrew 200. In one example, shoulder 280 is tapered
towards base 290 of setscrew 200. The degree of taper of shoulder
280 is varied in the range between zero (0) to ninety (90) degrees.
In another example, shoulder 280 has a rounded edge.
[0052] With particular attention now to FIG. 11, an alternative
embodiment of the coupling of lead 135 within header 140 is
illustrated. Setscrew bore 165 is formed within connector block 150
in a substantially vertical direction that is transverse to, and in
communication with, the longitudinal axis of lead bore 155. Lead
bore 155 is formed in a substantially horizontal direction,
relative to the orientation of setscrew bore 165. However, unlike
the embodiment of FIG. 2, the central longitudinal axis of setscrew
bore 165 is offset from the midpoint of the longitudinal axis of
lead bore 155. Thus setscrew 200 engages lead 135 at a location
other than tip 290. For example, in the embodiment of FIG. 11, when
setscrew 200 is threadedly coupled to the setscrew bore 165, lead
135 is engaged by shoulder 280 of setscrew 200. In one or more
embodiments, the angle of the taper of shoulder 280 is preferably
selected such that the surface in contact between setscrew 200 with
lead 135 is approximately tangent to lead 135. Thus, in some
examples, the taper of shoulder 280 is selected to be about thirty
(30), forty-five (45) or sixty (60) degrees. It will be appreciated
that embodiments where shoulder 280 engages lead 135, the surface
area in contact between setscrew 200 and lead 135 is greater than
that of FIG. 2 where lead 135 is engaged by base 290 of shank 210
of setscrew 200. Moreover, the offset orientation described above
permits setscrew 200 and lead 135 to overlap, relative to one
another, while still achieving the desired lead 135 retention
functionality.
[0053] With reference now to FIG. 12A, alternative embodiments of
setscrew 200A-B are illustrated. In the exemplary embodiment of
setscrew 200A, head portion 220A of core 205 is shown having a
star-shaped external drive configuration. The exemplary setscrew
200B shows head portion 220B having a concave-shaped external drive
configuration with the concave regions having varying dimensions.
It should be noted that the illustrative external drive
configurations are merely exemplary and are not intended to be
limiting. In alternative embodiments, head portion 220C has an
internal drive interface as illustrated in the example of FIG. 12B.
Head portion 220C has a hollowed out region, configured with
several lobed cutouts, that is integrally formed within head 220.
In comparison with an external drive interface, the internal drive
interface generally has faces aligned with the thread axis and that
face inward in relation to the contact surface of wrench 302.
[0054] FIGS. 13-15 illustrate magnified views of an exemplary
embodiment of setscrew bore 165 of header 140. As earlier noted,
IMD 10 is typically shipped with setscrew 200 already having been
inserted in setscrew bore 165. The diameter of setscrew bore 165 is
typically sized to be slightly larger than the external diameter of
setscrew 200. Thus, the illustrative embodiments of header 140
prevent unintentional falling out of setscrew 200 from setscrew
bore 165.
[0055] FIG. 13 shows setscrew bore 165 of header 140 having an
undercut 700. Undercut 700 is formed within the setscrew bore 165.
In some embodiments, undercut 700 is located proximate within the
region between an exterior opening 170 and a midpoint of setscrew
bore 165. Undercut 700 extends circumferentially at least partially
around setscrew bore 165. The structure of undercut 700 resembles a
furrow or a groove. Undercut 700 functions to receive a portion of
setscrew 200 thereby preventing setscrew 200 from falling out of
header 140. Additionally, a venting channel 710 that extends from
the proximal opening 170 is formed within setscrew bore 165. In
some embodiments, the longitudinal dimension of venting channel 710
is sized such that head 220 will be located within a portion of
venting channel 710 when setscrew 200 is disengaged from setscrew
bore 165. In one embodiment, venting channel 710 is formed using
molding techniques that incorporate venting channel 710 in the
formation of setscrew bore 165 within connector block 150. In
another example, venting channel 710 is formed by any suitable
process that extracts the molding material, such as machining, or
carving out to form the desired configuration, or depressing the
wall of setscrew bore 165 at the desired location during formation
of header 140.
[0056] FIG. 14 illustrates a cross-sectional view of header 140 of
FIG. 13, in conjunction with setscrew 200. In the illustrative
embodiment, undercut 700 receives a portion of setscrew 200 such,
for example, as a region having the largest diameter of setscrew
200 or a protrusion of the insulating material. In the exemplary
illustration, sealing member 230 has the largest diameter of
setscrew 200 and thus is received by undercut 700. Consequently, as
setscrew 200 retracts from setscrew bore 165, sealing member 230 is
engaged within undercut 700 thereby preventing setscrew 200 from
leaving the confines of setscrew bore 165. In alternative
implementations, undercut 700 is formed of several partial regions
spaced around setscrew bore 165.
[0057] Referring to FIG. 15, the insertion of lead 135 into header
140 of FIG. 14 is illustrated. It should be noted that insertion of
lead 135 into lead bore 155 will cause displacement of air within
lead bore 155 and connector block 150. With reference to FIG. 2 by
way of illustration, when setscrew 200 is inserted into setscrew
bore 165, sealing member 230 compresses against the walls of
setscrew bore 165 thereby sealing the bore 165 and preventing flow
of air. Consequently, the air in lead bore 155 causes a piston-like
effect when lead 135 is inserted. In other words, the air will
oppose insertion of lead 135 thereby encumbering the assembly
during an implantation. Turning then to FIG. 15, as lead 135 is
inserted into lead bore 155, the air within lead bore 155 is
permitted to freely flow between venting channel 710 and sealing
member 230. As an illustration, this free movement of air occurs
through venting channel 710. Additionally, the completed assembly
of IMD 10 is typically sterilized subsequent to insertion of
setscrew 200. Venting channel 710 also facilitates the
sterilization process of header 140 since the sterilization fluid
is permitted to flow through easily. Venting channel 710 is located
such that when setscrew 200 is fully unscrewed from the connector
block 150, fluids can freely pass through venting channel 710. Yet,
when setscrew 200 is fully screwed into the connector block 150,
fluids cannot freely pass by the sealing member 230 because the
venting channel 710 does not pass through the zone between the
location of the sealing member 230 when setscrew 200 is fully
screwed into the connector block 150.
[0058] FIGS. 16-17 illustrate an exemplary process for
manufacturing setscrew bore 165 having undercut 700 within header
140. It should be noted that the exemplary molding process for
molding header 140 typically includes the use of a mold 840 having
identical features to those of the desired header 140 that are
inverse to those of header 140. The manufacturing process used for
the formation of header 140 is any suitable molding process such,
for example, as injection molding.
[0059] FIG. 16 is a perspective view of a portion of exemplary mold
840 for the formation of header 140. Mold 840 is provided with a
setscrew bore-forming pin 800 for the formation of a setscrew bore
165. Setscrew bore-forming pin 800 has a raised rib 810 for the
formation of undercut 700. The diameter of raised rib 810 is sized
to be larger than the diameter of the setscrew bore-forming pin 800
such that the point of contact between raised rib 810 defines the
desired undercut 700. Pin 800 is also provided with an extended
longitudinal portion 805 for the formation of venting channel 710.
At least one crest 815 is provided along the circumference of a
proximal end 870 of pin 800.
[0060] A molding process, such as injection molding, is performed
to fill mold 840 with a molding material that is shaped into header
140. The material is allowed to cure and subsequently, the formed
header 140 is separated from mold 840. In one example, the step of
curing includes providing sufficient time for the molded material
to settle and cool to a room temperature, or about twenty degrees
Celsius. The material used in the molding process is a creep
recovering material, or has certain deflection properties such that
the material temporarily deforms when stress is exerted upon it but
substantially returns to its original form when the stress is
withdrawn. In one example, the material is a biocompatible material
that has elastic "memory" such as TECOTHANE.RTM. thermoplastic
polyurethanes.
[0061] FIG. 17 illustrates the step of ejection of pin 800 during
the separation of mold 840 from the molded header 140. During the
ejection, raised rib 810 causes an outward expulsion of the
material proximate the raised rib 810. However, crest 815 will
facilitate a controlled outward expulsion of the material at
exterior opening 170 during the withdrawal motion and prevent
rupture. In one example, four crests 815 are provided so that the
ejection of pin 800 will cause the material to be separated into
quadrants during the expulsion. Subsequent to the ejection of pin
800, the expelled material will substantially re-form back into its
pre-expulsion location because of its elastic memory and deflection
properties. This re-forming creates undercut 700 at the point of
contact with raised rib 810 and venting channel 710 at the location
of extended longitudinal portion 805.
[0062] In alternative embodiments, a flattening process is
additionally utilized to further re-form molded header 140 and/or
to create a smooth surface finishing along exterior opening 170 of
setscrew bore 165 and the surrounding edge. In one example, the
flattening process includes an annealing technique or application
of heat to re-shape the material around exterior opening 170. In
another example, the flattening process includes the application of
a physical force to depress the material back into setscrew bore
165. In alternative embodiments, sealing member 230 is coupled to
setscrew bore 165. Sealing member 230 may be coupled using any
known bonding technique such, for example, as a silicone
adhesive.
[0063] FIGS. 18A-B illustrate an alternative embodiment of header
140 having one or more protruding members 760. In the exemplary
embodiment, protruding members 760 are posts molded as part of
header 140 to extend adjacent to exterior opening 170. In an
example, the protruding members 760 are molded from the same
material as the header 140. As illustrated in FIG. 18B, upon
insertion of setscrew 200, the protruding members 760 are reflowed
downward toward setscrew bore 165 using any suitable reflow process
such as ultrasonic welding so as to protrude over exterior opening
170 thereby preventing setscrew 200 from falling out.
[0064] FIG. 19 illustrates a capture mechanism 750 extending over
exterior opening 170 of setscrew bore 165. In some embodiments,
capture mechanism 750 has a radial opening 755 having a diameter
that is less than the diameter of setscrew 200. Thus, when setscrew
200 is retracted from setscrew bore 165, capture mechanism 750
prevents setscrew 200 from falling out of setscrew bore 165. In one
embodiment, capture mechanism 750 is a rigid thin plate that is
formed such that it defines a trough-shaped opening 755. The
exemplary opening 755 is sized to enable insertion of torque wrench
302 for tightening or loosening setscrew 200. In one embodiment,
channel 755 on capture mechanism 750 is aligned with a vertical
axis of setscrew 200 to provide a continual line of vision to lead
135. Capture mechanism 750 is created from a bio-compatible rigid
material such, for example, as TECOTHANE.RTM. thermoplastic
polyurethanes or titanium. Capture mechanism 750 is bonded to
header 140 for example, at region 780, proximate to exterior
opening 170. In one example, capture mechanism 750 is bonded
through the coupling of posts 760 to correspondingly sized holes
765 by a reflow process. In another embodiment, the capture
mechanism 750 is a flat washer with a hole in approximately the
middle that is large enough to allow the torque wrench 302 to pass
but smaller than the maximum diameter of the setscrew to prevent
the setscrew from falling out of the sealing bore. In one
embodiment, capture mechanism 750 is formed as part of the header
140 by constructing a correspondingly shaped mold.
[0065] The specific shape and size of capture mechanism 750 is
predicated on keeping setscrew 200 from falling out while in its
disengaged position. The shape and size of radial dimension 770 of
opening 755 is controlled by various factors, for example, the
assembly requirements including the size and shape of the torque
wrench 302, the shape of the tool interface 300 and/or the coupling
technique. By way of example which is not intended to be limiting,
alternative embodiments of capture mechanism 750 have radial
dimension 770 formed to define a v-shape, or a u-shape.
Additionally, the variation of radial dimension 770 facilitates the
reduction of the spacing between multiple setscrew bores 165. Thus,
the variation of radial dimension 770 also enables reduction in
size of header 140.
[0066] In the foregoing detailed description, the present
disclosure has been described in considerable detail in order to
comply with the patent statutes and to provide those skilled in the
art with specific implementations that facilitate the understanding
of the novel principles of the disclosure. However, it is to be
understood that the principles of the present disclosure can be
carried out by specifically different equipment and devices and
that various modifications, both as to the equipment and operating
procedures, can be accomplished without departing from the scope of
the disclosure as set forth in the appended claims.
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