U.S. patent application number 11/870001 was filed with the patent office on 2008-08-28 for systems and methods for placement of valve prosthesis system.
This patent application is currently assigned to ENDOVALVE, INC.. Invention is credited to Gregorio Ramon M. Abesames, Joseph D. Antocci, Salvatore Castro, Howard C. Herrmann, David G. Lamphere.
Application Number | 20080208328 11/870001 |
Document ID | / |
Family ID | 39710690 |
Filed Date | 2008-08-28 |
United States Patent
Application |
20080208328 |
Kind Code |
A1 |
Antocci; Joseph D. ; et
al. |
August 28, 2008 |
Systems and Methods For Placement of Valve Prosthesis System
Abstract
Valve prosthesis systems and methods/systems for placement of
such valve prostheses are provided that facilitate efficient,
reliable and minimally invasive delivery modalities. The placement
systems and methods permit remote manipulation and positioning of
the valve prosthesis such that desirable placement relative to
anatomical structures, e.g., the heart annulus, may be achieved.
The valve prosthesis includes a resilient ring, a plurality of
leaflet membranes mounted with respect to the resilient ring, and a
plurality of positioning elements movably mounted with respect to
the flexible ring. The delivery system includes a first elongate
element that terminates at the valve prosthesis and is manipulable
by an operator to remotely rotate the positioning elements relative
to the flexible ring. A second elongate element terminates at the
valve prosthesis and is manipulable by an operator to remotely
advance the valve prosthesis downward into an anatomical annulus.
The second elongate element may be manipulated to remotely advance
the valve prosthesis into the anatomical annulus to assume a
position for supporting post-implantation function of the valve
prosthesis in situ. The first elongate element may be further
manipulated to remotely rotate the positioning element relative to
the flexible ring to cause the positioning element to engage tissue
associated with the anatomical annulus and to thereby maintain the
post-implantation position of the valve prosthesis in situ. Methods
for valve prosthesis deployment are also provided.
Inventors: |
Antocci; Joseph D.;
(Leominster, MA) ; Lamphere; David G.;
(Framingham, MA) ; Castro; Salvatore; (Milford,
MA) ; Abesames; Gregorio Ramon M.; (North Andover,
MA) ; Herrmann; Howard C.; (Bryn Mawr, PA) |
Correspondence
Address: |
MCCARTER & ENGLISH , LLP STAMFORD OFFICE
FINANCIAL CENTRE , SUITE 304A, 695 EAST MAIN STREET
STAMFORD
CT
06901-2138
US
|
Assignee: |
ENDOVALVE, INC.
Princeton
NJ
THE TRUSTEES OF THE UNIVERSITY OF PENNSYLVANIA
Philadelphia
PA
|
Family ID: |
39710690 |
Appl. No.: |
11/870001 |
Filed: |
October 10, 2007 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
60902988 |
Feb 23, 2007 |
|
|
|
Current U.S.
Class: |
623/2.11 |
Current CPC
Class: |
A61F 2/2439 20130101;
A61F 2/243 20130101; A61F 2/2436 20130101; A61F 2/2412
20130101 |
Class at
Publication: |
623/2.11 |
International
Class: |
A61F 2/24 20060101
A61F002/24 |
Claims
1. A method of implanting a valve prosthesis with respect to an
anatomical annulus, the method comprising: providing, in a vicinity
of the anatomical annulus: a valve prosthesis including a resilient
ring, a plurality of leaflet membranes mounted with respect to the
resilient ring, and a plurality of positioning elements movably
mounted with respect to the flexible ring; a first elongate element
terminating at the valve prosthesis and manipulable by an operator
to remotely rotate the positioning elements relative to the
flexible ring; and a second elongate element terminating at the
valve prosthesis and manipulable by an operator to remotely advance
the valve prosthesis downward into the anatomical annulus;
manipulating the first elongate element to remotely rotate the
positioning elements relative to the flexible ring manipulating the
second elongate element to remotely advance the valve prosthesis
into the anatomical annulus to assume a position within the
anatomical annulus suitable for supporting post-implantation
function of the valve prosthesis in situ; and manipulating the
first elongate element to remotely further rotate the positioning
element relative to the flexible ring to cause the positioning
element to engage tissue associated with the anatomical annulus for
maintaining the post-implantation position of the valve prosthesis
in situ.
2. The method according to claim 1, wherein the first elongate
element includes one or more filaments and the second elongate
element is a delivery tube.
3. A delivery system for percutaneous delivery of a valve
prosthesis, comprising: a valve prosthesis including a flexible
ring, a plurality of leaflet members mounted with respect to the
flexible ring, and a plurality of positioning elements (i) mounted
with respect to the flexible ring for engaging tissue at an
anatomical location, and (ii) rotatable relative to the flexible
ring to facilitate delivery and implantation of the valve
prosthesis; a first elongate element defining an internal lumen for
accommodating a guide wire, the first elongate element being
detachably mounted with respect to the valve prosthesis and
manipulable by an operator to remotely position the valve
prosthesis with respect to tissue at the anatomical location; one
or more second elongate elements manipulable by an operator to
remotely rotate the plurality of positioning elements with respect
to the flexible ring; and a third elongate element manipulable by
an operator to remotely decouple the first elongate element from
the valve prosthesis after implantation thereof; wherein for
purposes of being so manipulated, each of the second elongate
element and the third elongate element is adapted to translate with
respect to the first elongate element when at least partially
disposed together with the first elongate element within a central
lumen of a delivery catheter.
4. The delivery system in accordance with claim 3, wherein the
first elongate element includes a delivery tube, the second
elongate element includes a flexible cable, and wherein the
flexible cable is at least partially contained within the delivery
tube.
5. The delivery system in accordance with claim 3, wherein the
first elongate element includes a delivery tube, the third elongate
element includes a flexible sleeve, and the delivery tube is at
least partially contained within the flexible sleeve.
6. The delivery system in accordance with claim 3, wherein the
third elongate element terminates in a tool capable of coupling the
first elongate element and the valve prosthesis together, and
wherein the third elongate element is manipulable to decouple the
first elongate element from the valve prosthesis at least in part
by rendering the tool incapable of continuing to couple the first
elongate element and the valve prosthesis.
7. The delivery system in accordance with claim 6, wherein the
third elongate element is manipulable to decouple the first
elongate element from the valve prosthesis by removing the tool
from a corresponding interface between the first elongate element
and the valve prosthesis.
8. The delivery system in accordance with claim 7, wherein the tool
at least partially surrounds a corresponding portion of the valve
prosthesis and is operable to engage and hold the corresponding
portion against the first elongate element.
9. The delivery system in accordance with claim 8, wherein the tool
is a force-bearing loop of a flexible cable.
10. The delivery system in accordance with claim 7, wherein the
tool at least partially surrounds a corresponding portion of the
first elongate element and is operable to engage and hold the
corresponding portion against the valve prosthesis.
11. The delivery system in accordance with claim 10, wherein the
tool is a collar and the corresponding portion of the first
elongate element is a finger, the finger being associated with a
spring bias and being adapted to engage the valve prosthesis upon
the collar overcoming the spring bias.
12. The delivery system in accordance with claim 3, wherein the
third elongate element terminates in a tool capable of preventing
the first elongate element and the valve prosthesis from becoming
decoupled, and wherein the third elongate element is manipulable to
decouple the first elongate element from the valve prosthesis at
least in part by rendering the tool incapable of continuing to
prevent the first elongate element and the valve prosthesis from
becoming decoupled.
13. The delivery system in accordance with claim 12, wherein the
tool is at least partially surrounded by a corresponding portion of
the first elongate element and is operable to block movement of the
corresponding portion away from the valve prosthesis.
14. The delivery system in accordance with claim 12, wherein the
tool is a collar and the corresponding portion of the first
elongate element is a finger, the finger being associated with a
spring bias and being adapted to disengage the valve prosthesis
when the collar no longer blocks movement of the finger away from
the valve prosthesis and upon a concurrent defeat of the spring
bias.
15. The delivery system in accordance with claim 14, wherein the
third elongate element is manipulable to decouple the first
elongate element from the valve prosthesis at least in part by
removing the collar from a vicinity of the finger.
16. The delivery system in accordance with claim 14, wherein the
third elongate element further includes a flexible cable extending
upward from the force-bearing ring and extending alongside the
first elongate element, and wherein the third elongate element is
manipulable to decouple the first elongate element from the valve
prosthesis at least in part by employing the flexible cable to pull
the collar away from a vicinity of the finger.
17. The delivery system in accordance with claim 3, wherein the
third elongate element includes a flexible cable terminating in a
loop in a vicinity of the valve prosthesis for transmitting a force
to at least one of the first elongate element and the valve
prosthesis.
18. The delivery system in accordance with claim 17, wherein the
flexible cable is adapted to transmit a coupling force whereby the
loop thereof engages the valve prosthesis for pulling the valve
prosthesis against the first elongate element, and wherein the
third elongate element is manipulable to remotely decouple the
first elongate element from the valve prosthesis via an operator
withdrawing the coupling force, such that the loop of the flexible
cable is caused to cease so engaging the valve prosthesis.
19. The delivery system in accordance with claim 17, wherein the
flexible cable is adapted to transmit a decoupling force, whereby
the loop engages a coupling element of the first elongate element
for pulling the coupling element away from a corresponding coupling
element of the valve prosthesis, and wherein the third elongate
element is manipulable to remotely decouple the first elongate
element from the valve prosthesis via an operator applying the
decoupling force, such that the loop of the flexible cable is
caused to engage the coupling element.
20. The delivery system in accordance with claim 3, wherein the
third elongate element terminates in a displaceable ring at least
partially surrounding the first elongate element in a vicinity of
the valve prosthesis.
21. The delivery system in accordance with claim 20, wherein the
displaceable ring is effective to maintain the first elongate
element and the valve prosthesis in coupled engagement, and wherein
the third elongate element further includes a flexible sleeve
extending upward from the force-bearing ring, and at least
partially surrounding the first elongate element.
22. The delivery system in accordance with claim 20, wherein the
displaceable ring is effective to prevent the first elongate
element and the valve prosthesis from being disengaged, and wherein
the third elongate element further includes a flexible cable
extending upward from the displaceable ring, extending alongside
the first elongate element.
23. A tool for facilitating percutaneous delivery of a valve
prosthesis to an anatomical location, comprising: a body defining a
longitudinal axis, a distal end disposed on the longitudinal axis,
and a proximal end disposed on the longitudinal axis opposite the
distal end; a first actuator mounted with respect to the body at
one of the distal end thereof and the proximal end thereof, the
first actuator being configured to receive and engage a first
elongate element manipulable to remotely rotate a positioning
element associated with a valve prosthesis, and being reciprocally
actuatable with respect to the body for manipulating the first
elongate element by causing the first elongate element to translate
with respect to a delivery tube along the longitudinal axis; and a
second actuator mounted with respect to the body at the other of
the distal end thereof and the proximal end thereof, the second
actuator being configured to receive and engage a second elongate
element manipulable to remotely detach the delivery tube from the
valve prosthesis, and being reciprocally actuatable with respect to
the body for manipulating the second elongate element by causing
the second elongate element to translate with respect to the
delivery tube along the longitudinal axis.
24. The tool according to claim 23, wherein the valve prosthesis
includes a flexible ring, a plurality of leaflet members mounted
with respect to the flexible ring, and a plurality of positioning
elements (i) mounted with respect to the flexible ring for engaging
tissue associated with the anatomical structure and (ii) rotatable
relative to the flexible ring to facilitate delivery and
implantation of the valve prosthesis.
25. The tool according to claim 24, further comprising a delivery
tube detachably coupled to the valve prosthesis and defining an
internal lumen for accommodating a guide wire.
Description
CROSS-REFERENCE TO RELATED APPLICATIONS
[0001] The present application claims the benefit of co-pending
provisional patent application entitled "Valve Prosthesis System"
that was filed on Feb. 23, 2007 and assigned Ser. No. 60/902,988.
The entire contents of the foregoing provisional application are
incorporated herein by reference.
BACKGROUND
[0002] 1. Technical Field
[0003] The present disclosure is directed to advantageous valve
prosthesis systems and associated methods/systems for placement of
a heart valve prosthesis and, more particularly, to deployment
systems and methods for placement of a mitral valve prosthesis
relative to a heart annulus.
[0004] 2. Background Art
[0005] Heart valve regurgitation occurs when the heart valve does
not close completely as a result of disease or injury. Mitral
regurgitation due to ischemic and degenerative (prolapse) disease
has been shown to contribute to left ventricular dilation and
dysfunction due to remodeling, and is associated with increased
rates of cardiac events and death. Currently, malfunctioning heart
valves may be replaced with biologic or mechanical prostheses
through open-heart surgery with the attendant significant risk of
death, stroke, infection, bleeding, and complications due to the
use of general anesthesia and cardiopulmonary bypass.
[0006] Based on the success of percutaneous balloon valvuplasty for
mitral stenosis, investigators have explored other alternative
methods to treat valvular heart disease without surgery. For
example, Cribier et al. describe a balloon-expandable stent to
which a biologic valve prosthesis is sewn. (See, "Percutaneous
Transcatheter Implantation of an Aortic Valve Prosthesis for
Calcific Aortic Stenosis," Circulation, Dec. 10, 2002, pages
3006-3008.) The Cribier device is utilized to treat calcific aortic
stenosis. Bonhoeffer et al. describe a similar stent approach with
a bovine venous jugular) valve inserted to treat pulmonic valve
disease. (See, "Percutaneous Insertion of the Pulmonary Valve,"
Journal of the American College of Cardiology, Vol. 39, No. 10, May
15, 2002, pages 1664-1669.) Others are developing repair techniques
for mitral valve disease that involve placing a clip on the mitral
leaflets (U.S. Pat. No. 6,629,534), cinching the mitral annulus
from the coronary sinus (U.S. Pat. No. 6,537,314), or deploying an
inflatable heart valve that is mechanically held in place (U.S.
Pat. No. 5,554,185).
[0007] Norred (U.S. Pat. No. 6,482,228) discloses a percutaneous
aortic valve replacement in which a heart valve prosthesis having
ribs and a circular elastomeric canopy is folded for insertion into
a catheter for delivery to the implantation region without surgery.
Once in the ascending aorta, the body and leaflets of the heart
valve prosthesis are opened like an umbrella by pulling on a
central column of suture-like members. Hinge joints are used to
create a miniature umbrella. However, the aortic valve prosthesis
is anchored using a stent system that is extended in the ascending
aorta to anchor the valve in the aortic channel above the biologic
aortic valve. The suture-like members used to open the umbrella
structure are deployed as part of the stent system. Such a design
is not amenable to placement of the heart valve prosthesis at the
location of the biologic valve.
[0008] Other stented heart valve prostheses are described in the
art in which the anchoring system is a passive one that requires
either balloon expandable stents or a self-expanding stent design.
For example, such stented designs are described in U.S. Pat. No.
6,454,799, US 2002/0138138, U.S. Pat. No. 6,582,462, U.S. Pat. No.
6,458,153, U.S. Pat. No. 6,425,916, and U.S. Pat. No. 5,855,601. It
will be appreciated that once these stented heart valve prostheses
are deployed, they cannot be repositioned, refolded, or easily
removed. Furthermore, the rigidity of the stent as it is deployed
in calcified positions may allow for regurgitation around the
outside of the stent, as has been seen in the early aortic valve
deployments which utilize this design. It is also difficult to
position these designs as one has to inflate a balloon in a moving
column of blood while the heart is beating and one only gets one
chance to accurately deploy it.
[0009] An additional difficulty occurs when deploying a stented
heart valve in an annulus that is not thickened by calcium. The
stent design lends itself slightly better to the aortic position
where the height of the annulus has been increased and the width
thickened by the presence of calcium in calcific aortic stenosis.
However, when calcium is not present, as in other causes of aortic
valve disease and in the mitral position, the stent may be
difficult to anchor on the relatively thin annulus. Furthermore,
the nature by which the stent folds on a balloon and then expands
with plastic deformability limits the ratio of its initial to final
size such that it will, by necessity, have a fairly large profile
making percutaneous insertion via catheter more difficult in a
valve annulus with a large diameter that has not been reduced by
calcium deposition.
[0010] Herrmann et al. (US 2007/0016286) disclose a percutaneously
inserted bistable heart valve prosthesis that may be folded inside
a catheter for delivery to the patient's heart for implantation.
The heart valve has an elastic annular ring, a body member having a
plurality of legs, each leg connecting at one end to the annular
ring, claws that are adjustable from a first position to a second
position by application of external force so as to allow ingress of
surrounding heart tissue into the claws in the second position, and
leaflet membranes connected to the annular ring, the body member
and/or the legs. The disclosed leaflet membranes having a first
position for blocking blood flow therethrough and a second position
for allowing blood flow therethrough. The heart valve is designed
such that upon removal of the external force, the claws elastically
revert to the first position so as to grip the heart tissue
positioned within the claws, thereby holding the heart valve in
place. The body member and claws may be integrated into a one-piece
design. The heart valve so designed may be used as a prosthesis for
the mitral valve, aortic valve, pulmonary valve, or tricuspid valve
by adapting the annular ring to fit in a respective mitral, aortic,
pulmonary, or tricuspid valve opening of the heart.
[0011] Machold et al. (US 2004/0127982) disclose an implant that is
sized and configured to attach to the annulus of a dysfunctional
heart valve. In use, the implant extends across the major axis of
the annulus above and/or along the valve annulus. The implant
reshapes the major axis dimension and/or other surrounding anatomic
structures and is intended to restore a more functional anatomic
shape and tension. Machold et al. contemplate a pair of struts that
are joined by a rail and that carry other structures to enhance the
anchorage and stabilization of the implant in the heart valve
annulus. The anchoring mechanisms may be located below the plane of
the annulus to engage infra-annular heart tissue adjoining the
annulus in the ventricle and/or may be located at or above the
plane of the annulus, to engage tissue on the annulus or in the
atrium. Machold et al. further disclose that the struts may be used
to simply locate the implant in the valve, imparting little or no
force on their own. In this arrangement, the annulus reshaping
forces of the Machold design emanate from the rail(s) above the
commissures.
[0012] Under image guidance, the Machold et al. strut on the
leading end of the implant is freed from a sheath and seated
retrograde in the posterior commissure of the valve annulus.
Anchoring structures or mechanisms associated with the strut are
also placed into contact with adjoining tissue below and/or above
the plane of the annulus. As shown in FIG. 25B, the delivery
catheter maintains force on the leading strut within the posterior
commissure as the sheath is withdrawn in line with the coaptation
line in a posterior-to-anterior direction along the coaptation
line. Similar structures for positioning an implant relative to an
annulus are disclosed by Vazquez et al. (U.S. Pat. No.
6,287,339)
[0013] Despite efforts to date, a need remains for an improved
heart valve prosthesis design that allows a low profile for
insertion via a catheter but, in the absence of a balloon or stent,
transforms to a large profile once deployed. A heart valve
prosthesis design is also desired that can be deployed, folded,
removed, and then redeployed so as to increase the safety as well
as the preciseness of prosthesis deployment. Still further, a need
remains for heart valve prosthesis design(s) that may be
effectively aligned and/or oriented relative to the heart and, most
desirably, is substantially self-aligning and/or self-orienting
with respect thereto. Reliable and effective deployment systems and
methods for such advantageous heart valve prostheses are also
needed.
[0014] These and other needs are addressed by the disclosed
prosthesis designs and deployment systems/methodologies, as will be
apparent from the detailed description which follows.
SUMMARY
[0015] Valve prosthesis systems and methods/systems for placement
of such valve prostheses are disclosed herein. Exemplary deployment
systems and methods for placement of a mitral valve prosthesis
relative to a heart annulus are disclosed that facilitate
efficient, reliable and minimally invasive delivery modalities. The
disclosed systems and methods permit remote manipulation and
positioning of the valve prosthesis such that desirable placement
relative to anatomical structures, e.g., the heart annulus, may be
achieved.
[0016] In an exemplary deployment method for implanting a valve
prosthesis according to the present disclosure, the method involves
providing a valve prosthesis including a resilient ring, a
plurality of leaflet membranes mounted with respect to the
resilient ring, and a plurality of positioning elements movably
mounted with respect to the flexible ring. In addition, a first
elongate element may be provided that terminates at the valve
prosthesis and is manipulable by an operator to remotely rotate the
positioning elements relative to the flexible ring. A second
elongate element may be provided that terminates at the valve
prosthesis and is manipulable by an operator to remotely advance
the valve prosthesis downward into an anatomical annulus. The first
elongate element may be manipulated so as to remotely rotate the
positioning elements relative to the flexible ring. In addition,
the second elongate element may be manipulated to remotely advance
the valve prosthesis into the anatomical annulus to assume a
position within the anatomical annulus suitable for supporting
post-implantation function of the valve prosthesis in situ. The
first elongate element may be further manipulated to remotely
rotate the positioning element relative to the flexible ring to
cause the positioning element to engage tissue associated with the
anatomical annulus and to thereby maintain the post-implantation
position of the valve prosthesis in situ. In exemplary embodiments,
the first elongate element includes one or more filaments and the
second elongate element is a delivery tube.
[0017] The present disclosure also advantageously provides a
delivery system for percutaneous delivery of a valve prosthesis.
Exemplary delivery systems are adapted for placement of a valve
prosthesis that includes a flexible ring, a plurality of leaflet
members mounted with respect to the flexible ring, and a plurality
of positioning elements (i) mounted with respect to the flexible
ring for engaging tissue at an anatomical location, and (ii)
rotatable relative to the flexible ring to facilitate delivery and
implantation of the valve prosthesis. A first elongate element may
be provided that defines an internal lumen for accommodating a
guide wire, the first elongate element being detachably mounted
with respect to the valve prosthesis and manipulable by an operator
to remotely position the valve prosthesis with respect to tissue at
the anatomical location.
[0018] The delivery system may further include one or more second
elongate elements that are manipulable by an operator to remotely
rotate the plurality of positioning elements with respect to the
flexible ring. A third elongate element is also generally provided
that is manipulable by an operator to remotely decouple the first
elongate element from the valve prosthesis after implantation
thereof. For purposes of being so manipulated, each of the second
elongate element and the third elongate element are typically
adapted to translate with respect to the first elongate element
when at least partially disposed together with the first elongate
element within a central lumen of a delivery catheter.
[0019] The first elongate element may take the form of a delivery
tube and the second elongate element may take the form of a
flexible cable. The flexible cable is generally at least partially
contained within the delivery tube. The third elongate element may
take the form, in whole or in part, of a flexible sleeve, and the
delivery tube may be at least partially contained within the
flexible sleeve. Exemplary third elongate elements of the present
disclosure terminate in a tool capable of coupling the first
elongate element and the valve prosthesis together. The third
elongate element may be manipulable to decouple the first elongate
element from the valve prosthesis at least in part by rendering the
tool incapable of continuing to couple the first elongate element
and the valve prosthesis.
[0020] The third elongate element may also be manipulable to
decouple the first elongate element from the valve prosthesis by
removing the tool from a corresponding interface between the first
elongate element and the valve prosthesis. An exemplary tool at
least partially surrounds a corresponding portion of the valve
prosthesis and is operable to engage and hold the corresponding
portion against the first elongate element. The tool may take the
form of a force-bearing loop of a flexible cable. Thus, the tool
may be adapted to at least partially surround a corresponding
portion of the first elongate element and be operable to engage and
hold the corresponding portion against the valve prosthesis. An
exemplary tool is a collar and the corresponding portion of the
first elongate element is a finger. In such exemplary arrangement,
the finger may be associated with a spring bias and be adapted to
engage the valve prosthesis upon the collar overcoming the spring
bias.
[0021] In further exemplary embodiments of the present disclosure,
the third elongate element terminates in a tool capable of
preventing the first elongate element and the valve prosthesis from
becoming decoupled. The third elongate element may be manipulable
to decouple the first elongate element from the valve prosthesis at
least in part by rendering the tool incapable of continuing to
prevent the first elongate element and the valve prosthesis from
becoming decoupled. The tool may be at least partially surrounded
by a corresponding portion of the first elongate element and be
operable to block movement of the corresponding portion away from
the valve prosthesis. In an exemplary arrangement, the tool takes
the form of a collar and the corresponding portion of the first
elongate element is a finger, the finger being associated with a
spring bias and being adapted to disengage the valve prosthesis
when the collar no longer blocks movement of the finger away from
the valve prosthesis and upon a concurrent defeat of the spring
bias. The third elongate element may be manipulable to decouple the
first elongate element from the valve prosthesis at least in part
by removing the collar from the vicinity of the finger.
[0022] Exemplary delivery systems of the present disclosure may
also include a third elongate element that defines a flexible cable
extending upward from the force-bearing ring and extending
alongside the first elongate element. Such third elongate element
may be manipulable to decouple the first elongate element from the
valve prosthesis at least in part by employing the flexible cable
to pull the collar away from a vicinity of the finger. The third
elongate element may include a flexible cable terminating in a loop
in a vicinity of the valve prosthesis for transmitting a force to
at least one of the first elongate element and the valve
prosthesis. The flexible cable may be adapted to transmit a
coupling force, whereby the associated loop engages the valve
prosthesis for pulling the valve prosthesis against the first
elongate element, and wherein the third elongate element is
manipulable to remotely decouple the first elongate element from
the valve prosthesis via an operator withdrawing the coupling
force, such that the loop of the flexible cable is caused to cease
so engaging the valve prosthesis.
[0023] The disclosed flexible cable may be adapted to transmit a
decoupling force, whereby the loop engages a coupling element of
the first elongate element for pulling the coupling element away
from a corresponding coupling element of the valve prosthesis. The
third elongate element may be manipulable to remotely decouple the
first elongate element from the valve prosthesis via an operator
applying the decoupling force, such that the loop of the flexible
cable is caused to engage the coupling element. Exemplary third
elongate elements of the present disclosure terminate in a
displaceable ring at least partially surrounding the first elongate
element in a vicinity of the valve prosthesis. The displaceable
ring is generally effective to maintain the first elongate element
and the valve prosthesis in coupled engagement. The third elongate
element may further include a flexible sleeve extending upward from
the force-bearing ring and at least partially surrounding the first
elongate element. The displaceable ring is typically effective to
prevent the first elongate element and the valve prosthesis from
being disengaged. The third elongate element may further include a
flexible cable extending upward from the displaceable ring and
extending alongside the first elongate element.
[0024] Exemplary embodiments of the present disclosure further
provide a tool for facilitating percutaneous delivery of a valve
prosthesis to an anatomical location. Exemplary tools include a
body defining a longitudinal axis, a distal end disposed on the
longitudinal axis, and a proximal end disposed on the longitudinal
axis opposite the distal end A first actuator may be mounted with
respect to the body at one of the distal end thereof and the
proximal end thereof The first actuator is generally configured to
receive and engage a first elongate element manipulable to remotely
rotate a positioning element associated with a valve prosthesis.
The first actuator is also generally reciprocally actuatable with
respect to the body for manipulating the first elongate element by
causing the first elongate element to translate with respect to a
delivery tube along the longitudinal axis.
[0025] The disclosed tool also generally includes a second actuator
mounted with respect to the body at the other of the distal end
thereof and the proximal end thereof The second actuator is
typically configured to receive and engage a second elongate
element manipulable to remotely detach the delivery tube from the
valve prosthesis and is reciprocally actuatable with respect to the
body for manipulating the second elongate element by causing the
second elongate element to translate with respect to the delivery
tube along the longitudinal axis. Exemplary tools of the present
disclosure may further include a delivery tube detachably coupled
to the valve prosthesis and defining an internal lumen for
accommodating a guide wire. The disclosed tool is particularly
adapted for placement of a valve prosthesis that includes a
flexible ring, a plurality of leaflet members mounted with respect
to the flexible ring, and a plurality of positioning elements (i)
mounted with respect to the flexible ring for engaging tissue
associated with the anatomical structure and (ii) rotatable
relative to the flexible ring to facilitate delivery and
implantation of the valve prosthesis.
[0026] Additional features, functions and benefits of the disclosed
delivery systems and methods will be apparent from the description
of exemplary embodiments which follow, particularly when read in
conjunction with the appended figures.
BRIEF DESCRIPTION OF THE FIGURES
[0027] To assist those of ordinary skill in the art in making and
using the disclosed valve prosthesis system and associated
deployment systems/methods, reference is made to the accompanying
figures wherein:
[0028] FIG. 1 is a downward perspective of an exemplary valve
prosthesis system according to the present disclosure;
[0029] FIG. 2 is a partially-sectional side view of an exemplary
valve prosthesis system according to the present disclosure
positioned relative to a heart annulus;
[0030] FIG. 3A is a side view of an exemplary prosthesis system
according to the present disclosure, wherein an exemplary heart
valve prosthesis is positioned within an exemplary delivery
structure;
[0031] FIG. 3B is a partially-sectional side view of the exemplary
prosthesis system of FIG. 3A, also shown positioned within the
exemplary delivery structure;
[0032] FIGS. 4A, 4B, 4C, 4D, 4E, 4F, 4G, 4H, and 4I are schematic
views illustrating percutaneous placement of a heart valve
prosthesis relative to an annulus according to an exemplary
embodiment of the present disclosure;
[0033] FIGS. 5, 6, and 7 are schematic perspective views of
variations of a positioning element according to the present
disclosure;
[0034] FIGS. 8, 9, 10, 11 and 12 are schematic side elevational and
perspective views of variations of a prosthetic heart valve in
accordance with the present disclosure;
[0035] FIGS. 13 and 14 are respective side and views of a flexible
ring according to the present disclosure;
[0036] FIG. 15 is a schematic side view of an exemplary valve
prosthesis contained within a delivery catheter in accordance with
the present disclosure;
[0037] FIGS. 16, 17, 18, 19 and 20 are sequential side views of an
exemplary valve prosthesis being outwardly deployed from within a
delivery catheter in accordance with the present invention;
[0038] FIG. 21 is a schematic perspective view of a variation of a
valve prosthesis system in accordance with the present
disclosure;
[0039] FIG. 22 is a schematic perspective view of a
folded/compressed valve prosthesis of the valve prosthesis system
of FIG. 21;
[0040] FIG. 23 is a side view of a deployed valve prosthesis of the
valve prosthesis system of FIG. 21;
[0041] FIG. 24 is a cutaway detail view of the deployed valve
prosthesis of FIG. 23;
[0042] FIG. 25 is a schematic perspective view of a
folded/compressed valve prosthesis in accordance with the present
disclosure;
[0043] FIG. 26 is a side view of a deployed valve prosthesis of the
valve prosthesis system of FIG. 25;
[0044] FIG. 27 is a cutaway detail view of the deployed valve
prosthesis of FIG. 26;
[0045] FIG. 28 is a schematic perspective view of a variation of a
valve prosthesis system in accordance with the present
invention;
[0046] FIG. 29 is a side elevational view of a valve prosthesis of
the valve prosthesis system of FIG. 28;
[0047] FIG. 30 is a perspective view of a cable guide tube of the
valve prosthesis system of FIG. 28;
[0048] FIG. 31 is an end view of a valve prosthesis of the valve
prosthesis system of FIG. 28;
[0049] FIG. 32 is a sectional side view of a valve prosthesis of
the valve prosthesis system of FIG. 28 taken along section line
32-32 appearing in FIG. 31;
[0050] FIG. 33 is a perspective view of a resilient element in the
valve prosthesis illustrated in FIG. 32;
[0051] FIG. 34 is an end view of the valve prosthesis system of
FIG. 28;
[0052] FIG. 35 is a sectional side view of a tool of the valve
prosthesis system of FIG. 28 taken along section line 35-35
appearing in FIG. 34;
[0053] FIG. 36 is a sectional side view of part of the tool of the
valve prosthesis system of FIG. 28 taken along section line 35-35
appearing in FIG. 35; and
[0054] FIG. 37 is a sectional side view of another part of the tool
of the valve prosthesis system of FIG. 28 taken along section line
35-35 appearing in FIG. 35.
DESCRIPTION OF EXEMPLARY EMBODIMENT(S)
[0055] Advantageous valve prosthesis systems and deployment
systems/methods are provided according to the present disclosure.
The disclosed systems and methods permit surgeons/clinicians to
improve heart valve function without invasive surgical
intervention. Indeed, the disclosed valve prosthesis systems permit
a heart valve prosthesis to be percutaneously delivered to a
desired anatomical location. Once located in the desired anatomical
region/locale, the disclosed valve prosthesis system facilitates
secure and aligned placement of a heart valve prosthesis relative
to a heart annulus. Percutaneous delivery of the disclosed heart
valve prosthesis as disclosed herein provides for efficient and
effective clinical placement of a heart valve prosthesis. The
disclosed heart valve prosthesis and associated delivery techniques
offer numerous clinical benefits, including enhanced valve function
without the need to remove existing valve leaflets, an ability to
effectively and efficiently deliver a valve prosthesis
percutaneously, and an ability to position and reposition a valve
prosthesis relative to an annulus to ensure proper orientation
relative to anatomical features.
[0056] With initial reference to FIG. 1, an exemplary valve
prosthesis system 100 is schematically depicted. The valve
prosthesis system 100 includes a heart valve prosthesis 102 and a
delivery structure 104. The valve prosthesis 102 includes a
flexible ring 106. Mounted with respect to the flexible ring 106
are a plurality of leaflet membranes 108, a valve skirt 110, and a
resilient element 112. The resilient element 112 may include a hub
114 and a plurality of legs 116, each of the legs 116 extending
from the hub 114 (e.g., in a regular radial arrangement, as shown
in FIG. 1) and being movably mounted with respect to the flexible
ring 106 via individual ones of a corresponding plurality of
mounting elements 118. The valve prosthesis 102 may further include
a corresponding plurality of positioning elements 120, each such
positioning element 120 being attached to one of the legs 116 of
the resilient element 112.
[0057] As shown in the exemplary embodiment of FIG. 1, the valve
prosthesis 102 may include three (3) leaflet membranes 108, each
leaflet membrane 108 assuming an inwardly bowed orientation when
mounted with respect to the flexible ring 106. More or fewer of the
leaflet membranes 108 may be employed without departing from the
spirit or scope of the present disclosure, provided the desired
blood flow functionality is achieved. The leaflet membranes 108 may
be fabricated from xenograft tissue, e.g., the valve leaflets may
be fabricated from standard biologic or artificial prosthetic
material, such as cryo-or chemically-preserved bovine pericardium
or porcine heart valve tissue. Synthetic membrane materials may
also be employed in the fabrication of the leaflet membranes 108,
e.g., fiber-reinforced matrix materials. The leaflet membranes 108
may be secured with respect to the flexible ring 106 through
conventional means, e.g., creation of an annulus and/or cuff that
surrounds, in whole or in part, the flexible ring 106 such that
each of the plurality of leaflet membranes 108 extends downwardly
with respect to the flexible ring 106.
[0058] With further reference to FIG. 1, the valve skirt 110 may
extend to a full extent of the flexible ring 106, e.g., to a full
extent of the circumference of the flexible ring 106. The valve
skirt 110 may be formed from a single, contiguous structure, or may
be defined by a plurality of adjacent and/or overlapping elements
that, together, extend along the circumference of flexible ring
106. According to exemplary embodiments of the present disclosure,
the valve skirt 110 may be sutured with respect to the flexible
ring 106. Alternatively, a cuff may be formed at an edge of the
valve skirt 110, such cuff being adapted to receive the flexible
ring 106 therewithin. The cuff may extend along the entire edge of
the valve skirt 110 or may be defined at discrete intervals along
the length of the valve skirt 110, such that the valve skirt 110 is
mounted with respect to the flexible ring 106 at spaced intervals.
The valve skirt 110 may be fabricated from a variety of
substantially flexible and/or pliable materials, e.g., xenographic
tissue or a synthetic material that is compatible with blood flow,
e.g., a non-thrombogenic material. Indeed, in an exemplary
embodiment of the present disclosure, the valve skirt 110 and the
leaflet membranes 108 may be fabricated as integral/contiguous
structures, e.g., from a desired xenographic and/or synthetic
material, and such integral/continuous structure may be
advantageously mounted with respect to the flexible ring 106 such
that the functionalities of both elements (i.e., leaflet membrane
functionality and valve skirt functionality) are achieved.
[0059] The thickness of the valve skirt 110 may be substantially
uniform from edge-to-edge or may vary along its length. For
example, in an exemplary embodiment of the present disclosure, it
is contemplated that the valve skirt 110 would be thicker in a
region thereof adjacent the flexible ring 106 and thinner in a
region thereof relatively more distant from the flexible ring 106,
thereby enhancing the flexibility of the valve skirt 110 in the
latter region to provide more effective sealing functionality
relative to adjacent anatomical structures/tissue. The thicker
region adjacent the flexible ring 106 may serve to reduce the
likelihood of the valve skirt 110 disengaging from the flexible
ring 106.
[0060] Although the exemplary embodiment of FIG. 1 depicts the
valve skirt 110 extending in a single direction relative to the
flexible ring 106, i.e., downward, it is contemplated according to
the present disclosure that the valve skirt 110 may extend both
upwardly and downwardly relative to the flexible ring 106. In some
such implementation of the valve skirt 110, the attachment means
for securing the valve skirt 110 relative to the flexible ring 106
would not necessarily be located at an edge thereof. Rather, such
attachment means, e.g., cuff(s) and/or suturing, may be positioned
along an intermediate line/region of the valve skirt 11 0. In this
way, a first portion of the valve skirt 110 would be free to extend
above the flexible ring 106, and a second portion of the valve
skirt 110 would be free to extend below the flexible ring 106. Both
portions of the valve skirt 110, i.e., the portions above and below
the flexible ring 106, would advantageously function to seal the
valve prosthesis 102 relative to a patient's anatomy when the valve
prosthesis 102 is deployed relative thereto, as described in
greater detail below. Of note, a portion of the valve skirt 110
extending above the flexible ring 106 may include a notch or
discontinuity to accommodate structures associated with the
positioning elements 120, as described in greater detail below. The
valve skirt 110 may have a downward length that is effective to
achieve a desired level of sealing relative to surrounding
anatomical structures. For Example, the valve skirt 110 may have a
downward length of about five (5) millimeters to about fifteen (15)
millimeters relative to the flexible ring 106. Similar dimensions
are contemplated for the upward extending portion of the valve
skirt 110 in implementations wherein the valve skirt 110 extends
both above and below the flexible ring 106.
[0061] For greater security/stability, the valve skirt 110 may be
tacked or otherwise secured in at least some manner relative to the
resilient element 112 (e.g., to one or more of the legs 116 of the
resilient element 112). In an alternative embodiment, the valve
skirt 110 may be positioned radially outward of the positioning
elements 120.
[0062] As shown in FIG. 1, the resilient element 112 may include
three (3) legs 116 mounted in a circumferentially-spaced manner
with respect to the flexible ring 106 via the mounting elements
118. Each leg 116 may be configured or adapted to include or assume
an arcuate shape or bend in the vicinity of the flexible ring 106.
The legs 116 may be spaced by about 120.degree. relative to each
other, although an alternative number and/or spacing of the legs
116 may be employed without departing from the spirit or scope of
the present disclosure. The mounting elements 118 may be of any
suitable shape, design, configuration, and/or attachment technique
relative to the legs 116 to permit rotational and/or overturning
motion of the legs 116 relative to the hub 114, and/or relative to
the flexible ring 106. For example, the mounting elements 118 may
be substantially C-shaped, and/or tube shaped. The mounting
elements 118 may, for example, be affixed to respective undersides
of the legs 116 (e.g., within an arcuate or bent portion thereof)
through an appropriate mounting technique, e.g., a tack weld.
[0063] Returning to the potential interplay between the legs 116 of
the resilient element 114 and the valve skirt 110, the mounting
elements 118 may overlay the valve skirt 110 to the extent that the
valve skirt 110 is secured to the flexible ring 106 in such
circumferential region. Further, the valve skirt 110 may be tacked,
adhered or otherwise joined to the underside of one or more of the
legs 116 where the same extend over the valve skirt 110.
[0064] With further reference to FIG. 1, each of the positioning
elements 120 may be shaped, configured, and/or otherwise adapted to
engage tissue, and/or to position the valve prosthesis 102 relative
to tissue. For example, each positioning element 120 may define an
outer surface 122, an inner surface 124 opposite the outer surface
122, an upper arcuate region 126, and a lower arcuate region 128
opposite the upper arcuate region 126. Each of the positioning
elements 120 may be coupled (e.g., fixedly joined) to a
corresponding leg 116 of the resilient element 112, e.g., through a
weld between the inner surface 124 of the positioning element 120 a
corresponding outer surface of the leg 116. The positioning
elements 120 may be dimensioned such that the upper arcuate regions
126 thereof extend above the flexible ring 106 (e.g., when the
valve prosthesis 102 assumes the orientation depicted in FIG. 1).
The upper and lower arcuate regions 126, 128 of the positioning
elements 120 may be spaced by a distance that facilitates
positioning of the valve prosthesis 102 relative to a heart
annulus, as described in greater detail below. For example, the
upper and lower arcuate regions 126, 128 may be spaced by between
about seven (7) millimeters and about twenty-five (25) millimeters.
The positioning elements 120 and the legs 116 may be fabricated
from a material that permits at least some degree of
flexibility/deformation (e.g., elastic deformation), such as
stainless steel or Nitinol of an appropriate thickness/gauge. Other
materials for the positioning elements 120 and/or the legs 116 are
possible.
[0065] The lower arcuate regions 128 of the positioning elements
120 may include a pair of spaced apertures 130, 132. The delivery
structure 104 may include a plurality of filaments or cords 134,
each cord 134 being threaded through a positioning element 120 via
the pair of spaced apertures 130, 132 formed therein, such that
separate lengths 136 of the cord 134 extend away from the apertures
130, 132 and radially inwardly toward the hub 114 of the resilient
element 112. As may be more clearly seen in FIG. 2, the hub 114 of
the resilient element 112 may include one or more lumen(s) 200
(e.g., a centrally-located lumen 200), the delivery structure 104
may include a delivery tube 202 having one or more corresponding
lumens 204 (e.g., an axially located lumen), and the lengths 136 of
the cords 134 may pass from the respective lower arcuate regions
128 of the positioning elements 120 toward the hub 114, into and
through the lumen 200 thereof, and into and through the lumen 204
of the delivery tube 202. Such lengths 136 of the cords 134, and/or
such routing of such lengths 136 of such cords 134 from the lower
arcuate regions 128 of the positioning elements 120 and via the hub
114 and/or the delivery tube 202, may facilitate deployment of the
valve prosthesis 102 relative to an annulus and/or associated heart
tissue.
[0066] The delivery tube 202 may be flexible, and the lumen or
lumens 204 may accommodate passage of a plurality of lengths 136 of
cords 134. In the exemplary embodiment of FIGS. 1 and 2, three (3)
positioning elements 120 are associated with the valve prosthesis
102 and each positioning element 120 interacts with a separate cord
134. Thus, the respective lumen(s) 200, 204 of the hub 114 and the
delivery tube 200 may be appropriately sized and/or of an
appropriate number to accommodate least six (6) separate lengths
136 of cords 134, based on the looping of each cord 134 through a
pair of spaced apertures 130, 132 formed at or near the respective
lower arcuate regions 128 of the positioning elements 120.
[0067] As is also apparent from the cross-sectional view of FIG. 2,
the legs 116 of the resilient element 112 may cooperate with the
hub 114 thereof and/or with the flexible ring 106 to provide
stability to the valve prosthesis 102, e.g., during the deployment
process, and/or during the useful life of the valve prosthesis 102
in situ. The structural interaction between the legs 116 and the
flexible ring 106, and/or between the legs 116 and the hub 114,
permits a surgeon/clinician to utilize the lengths 136 of the cords
134 and the delivery structure 104 to remotely operate the valve
prosthesis 102 (e.g., to remotely move/rotate the legs 116 relative
to the flexible ring 106 and/or relative to the hub 114). Each of
the legs 116 may, for example, include one or more joints along its
respective length (e.g., one or more living hinges at or near a
mid-point thereof) to facilitate collapse of valve prosthesis 102
for catheter-based delivery thereof In embodiments in accordance
with the present disclosure, one or more such joints may store
energy so as to facilitate the delivery of a spring force to expand
the flexible ring 106 to a full diameter thereof (or at least a
substantial fraction thereof), or assist in an otherwise
substantially self-powered expansion thereof, upon deployment of
the valve prosthesis 102 in situ. In embodiments in accordance with
the present disclosure, one or more such joints may further store
energy so as to urge the positioning elements 120 radially outward
(e.g., toward secure engagement with corresponding tissue, and/or
radially outward from a compressed shape associated with
intra-catheter delivery). According to at least some exemplary
embodiments of the present disclosure, three (3) legs 116 may
extend from the hub 114, such that the resilient element 112
assumes a `tripod`-type shape for expanding and/or supporting the
valve prosthesis 102 (e.g., helping the flexible ring 106 to assume
and/or maintain a shape consistent with the intended function of
the valve prosthesis 102, and/or to urge the positioning elements
120 radially outward) during deployment and/or while implanted in
situ.
[0068] With further reference to FIG. 2, the valve prosthesis 102
of the valve prosthesis system 100 is depicted in alignment and
engagement with an heart valve annulus "A" and a heart wall "W" of
a patient. The valve prosthesis 102 is further shown displacing
heart valve leaflet structure "V" (e.g., the valve prosthesis 102
is implanted within the annulus A for purposes of providing the
valve function for which the valve leaflet structure V is no longer
well suited). The annulus A is depicted in an enlarged and
symmetric fashion for ease of description. The actual geometric and
dimensional details of the relevant anatomical structures are well
known to persons skilled in the art. As shown in FIG. 2, each of
the upper arcuate regions 126 of the respective positioning
elements 120 may be positioned advantageously so as to engage a
corresponding part of an upper portion of the annulus A. In this
fashion, at least, the positioning elements 120 may be employed in
cooperation with each other to align the valve prosthesis 102
relative to the annulus A. As also shown in FIG. 2, each of the
lower arcuate regions 128 may be positioned advantageously so as to
engage a corresponding part of the wall W below the annulus A. In
this fashion, at least, the positioning elements 120 may be
employed in cooperation with each other to stabilize and secure the
valve prosthesis 102 relative to the overall anatomical
environment.
[0069] In the event the surgeon/clinician is or becomes
dissatisfied with the position/orientation of valve prosthesis 102
relative to the annulus A or the wall W, or has or develops some
other concern or uncertainty with respect to the deployment of the
valve prosthesis 102, he/she may deflect the lower arcuate regions
128 of the positioning elements 120 inward by pulling or otherwise
manipulating or moving the respective lengths 136 of the cords 134
a sufficient extent radially inwardly and/or upwardly through the
hub 114 and the delivery tube 202 to cause the lower arcuate
regions 128 of the positioning elements 120 to disengage from the
wall W. The surgeon/clinician may then reposition the structure of
the valve prosthesis 102 relative to the overall anatomical
environment by pulling, pushing, or otherwise manipulating or
moving the delivery tube 202 to a desired extent with respect to
the delivery catheter (not separately shown). Such manipulation
may, for example, be translated to the valve prosthesis 102 via the
hub 114 and the legs 116 of the resilient element 112. In
accordance with embodiments of the present disclosure, after
delivering the valve prosthesis 102 to the position with respect to
the annulus A shown in FIG. 2, the surgeon/clinician may elect to
pull the valve prosthesis 102 at least partially back upward,
causing the lower arcuate regions 128 of the positioning elements
to engage a corresponding part of a lower portion of the annulus A,
and/or to engage the heart valve leaflet structure V, which in at
least some instances results in the valve prosthesis 102 to be
lodged and/or anchored in a particularly secure fashion within the
annulus A.
[0070] Once satisfied with the position of the valve prosthesis 102
relative to the annulus A and/or the wall W, the surgeon/clinician
may withdraw the cords 134 from the valve prosthesis 102 through
the delivery tube 202 by pulling outward on one length 136 thereof
to a sufficient extent while leaving the other length 136 loose.
The surgeon/clinician may further withdraw the remainder of the
delivery structure 104 from the valve prosthesis 102 by separating
the delivery tube 202 from the hub 114 of the resilient element
112. Means for disconnecting the delivery tube 202 from the hub 114
may take a variety of forms, e.g., a screw thread arrangement at
the end of the delivery tube 202 that may be disengaged from a
corresponding socket associated with the hub 114. Still further
(e.g., alternative) connection and/or disconnection means are
possible, including bayonet lock mechanisms, detent engagement
mechanisms, and the like, at least some of which are further
described hereinbelow.
[0071] Tissue-engaging features, e.g., barbs, tacks or the like,
may be formed on, in, and/or through one or more tissue-engaging
surfaces of the respective positioning elements 120. For example,
such features may be formed on the outer surface 122 of the
positioning elements 120, e.g., within the upper and/or lower
arcuate regions 126, 128. Additionally, surface treatments and/or
adjunct structures may be associated with the positioning elements
120 to promote tissue in-growth, thereby further enhancing the
stability/security of an implanted valve prosthesis according to
the present disclosure. For example, a biologic coating and/or a
material or fabric that promotes tissue in-growth, e.g., DACRON.TM.
material, may be applied to a desired portion/region of the
respective outer surfaces 122 of the positioning elements 120.
[0072] The disclosed valve prostheses and valve prosthesis systems
and methods have applicability in a variety of anatomical regions,
e.g., as a prosthesis for the mitral valve, aortic valve, pulmonary
valve, or tricuspid valve. Embodiments of the disclosed valve
prosthesis have particular applicability for mitral valve
applications. Depending on the desired clinical application, the
valve prosthesis system 100 and/or the valve prosthesis 102 may be
sized and dimensioned to accommodate such use by adapting the
annular ring to fit in the requisite anatomical space, e.g., a
mitral, aortic, pulmonary, or tricuspid valve opening of the
heart.
[0073] Turning to FIGS. 3A and 3B, the heart valve prosthesis 102
may assume a collapsed configuration within a lumen 300 of a
catheter 302. Additionally, the positioning elements 120 may be
substantially inverted, e.g., rotated approximately 180.degree.
relative to the flexible ring 106 to which they are mounted and
relative to the hub 114 of the resilient element 112, as compared
to the relative positions or orientations the positioning elements
120 may tend to occupy with respect to such structure (e.g., as
shown in FIG. 1) when not being subjected to the application of
opposing outside forces. The flexible ring 106 may also be
substantially deformed and the legs 116 of the resilient element
112 may be deflected so as to permit the valve prosthesis 102 to
fit within the catheter 302. In this inverted orientation, the
upper and lower arcuate regions 126, 128 associated with the
respective positioning elements 120 may be inwardly directed toward
the delivery tube 202. In an exemplary embodiment of the present
disclosure, the upper and lower arcuate portions 126, 128 of the
respective positioning elements 120 may be associated with and/or
terminate in respective tips 304, 306, and such tips 304, 306 may
feature cut-outs (not shown in FIGS. 3A and 3B), e.g., arcuate
notches, such cut-outs being adapted to cooperate with a
substantially cylindrical geometry of the delivery tube 202 when
the positioning elements 120 are in the substantially inverted
orientations depicted in FIGS. 3A and 3B.
[0074] Turning to FIGS. 4A-4I, an exemplary sequence of steps for
percutaneously delivering and positioning the disclosed valve
prosthesis 102 in a desired anatomical location are schematically
depicted. As shown in FIGS. 4A-4C, the valve prosthesis 102 may be
navigated to the desired anatomical location, e.g., adjacent a
mitral valve, aortic valve, pulmonary valve, or tricuspid valve,
within a delivery catheter 400 having a distal end 402. In
accordance with embodiments of the present disclosure, the valve
prosthesis 102 may be delivered to the mitral valve cavity
transseptally or by direct venous or arterial delivery to the
aortic valve, pulmonary valve, or tricuspid valve cavities. In
exemplary embodiments, the valve prosthesis may be navigated to a
desired location using a guide wire (not shown) that cooperates
with a corresponding guide wire lumen (not shown) formed in or
otherwise present within the delivery catheter 400. The valve
prosthesis 102 may be advanced through the delivery catheter 400
along an associated guide wire in a collapsed/inverted orientation
(by being pushed, for example, by the delivery tube 202) to the
implantation position (e.g., left atrium for mitral valve) where
the valve prosthesis 102 is deployed adjacent the diseased valve
for subsequent implantation therein. Alternatively, the valve
prosthesis 102 may be pre-positioned within the delivery catheter
400 at or near the distal end 402, and both the valve prosthesis
102 and the distal end 402 of the delivery catheter 400 may be so
advanced in unison along an associated guide wire.
[0075] Once a distal end 402 of the delivery catheter 400 has been
delivered to within the necessary proximity of the desired
anatomical location, e.g., annulus "A", the delivery tube 202 may
be extended relative to the delivery catheter 400 to push the valve
prosthesis 102 outward of the catheter via a corresponding opening
in the distal end 402. Upon the valve prosthesis 102 exiting the
distal end 402, resilient properties of several components of the
valve prosthesis 102, particularly the flexible ring 106 and the
legs 116 of the resilient element 112 (FIG. 2), may cause at least
the flexible ring 106 to automatically resume its
non-deformed/uncompressed shape (e.g., as seen in FIG. 4B as well
as all later figures in the sequence of FIGS. 4A-4I), which may be,
for example, a circle, an ellipse, or the like. As best seen in
FIG. 4C, upon the surgeon/clinician allowing the valve prosthesis
102 to emerge from the delivery catheter 400, yet without any
further positive action on the part of the surgeon/clinician, the
valve prosthesis 102 may tend eventually to fully relax, and assume
a generally non-deformed orientation, wherein the positioning
elements 120 are seen to have overturned or become inverted by
rotating both outwardly and downwardly past the horizontal (e.g.,
so that the outer surfaces 122 thereof face generally outward
again, and the upper and lower arcuate regions 126, 128 thereof
are, once again, outwardly directed). The valve skirt 110 may be
appropriately substantially downwardly oriented and positioned for
performing an advantageous sealing function (e.g., as against valve
prolapse) upon being positioned in a desired anatomical
position.
[0076] From the orientation of the valve prosthesis 102, and more
particularly, of the positioning elements 120 thereof, shown in
FIG. 4C, the surgeon/clinician may deflect the lower arcuate
regions 128 of the positioning elements 120 inward by pulling the
respective lengths 136 of the cords 134 (FIG. 2) a sufficient
extent radially inward toward, and/or upward through, the hub 114
(FIG. 2) and the delivery tube 202 in such a way as to continue
(see FIG. 4D) an overturning or inverting motion of the positioning
elements 120 relative to the flexible ring 106 and the hub 114
(FIG. 2), progressing through sequential orientations as depicted
in FIGS. 4D and 4E and arriving at the particularly notable
orientation depicted in FIG. 4F. For example, in accordance with
embodiments of the present disclosure, the surgeon/clinician may be
permitted to accomplish such deflection of the positioning elements
120 by grasping or otherwise seizing respective proximal ends (not
shown) of the lengths 136 of the plurality of cords 134 (FIG. 2)
disposed outside the delivery catheter 400 and outside the
patient's body and pulling such ends outward of the delivery
catheter 400 and the patient's body. Such withdrawal of the lengths
136 of the cords 134 results in the lower arcuate regions 128 of
the positioning elements 120 being pulled radially inwardly, e.g.,
to a point where the tips 306 of the lower arcuate regions 128
extend at least partially downwardly toward the diseased valve. As
shown in FIGS. 4G and 4H, such downwardly-directed and relatively
more closely spaced lower arcuate regions 128 may be utilized in
the manner of a probe or `plow`to deflect the patient's leaflet
membranes (see, e.g., valve structure V in FIG. 2) and/or otherwise
facilitate advancing the valve prosthesis 102 downward into the
patient's diseased valve such that the valve prosthesis 102 is able
to be positioned at an appropriate implantation elevation and an
appropriate lateral position relative to the annulus A,
[0077] As best shown in FIG. 4H, the upper arcuate regions 126 of
the respective positioning elements 120 may be cooperatively
adapted to be contained within a common plane, e.g., in the manner
of a "top hat", so as to facilitate positioning/alignment of the
valve prosthesis 102 relative to the annulus A. The
circumferentially interrupted aspect exhibited by of the valve
prosthesis 102 and collectively defined by the positioning elements
120 may facilitate both inversion of the positioning elements 120
during percutaneous introduction, and effective alignment and
tissue engagement/stability upon final implantation and in situ
valve function. For example, upon each of the plurality of upper
arcuate regions 126 substantially engaging a corresponding part of
the upper portion of the annulus A, the valve prosthesis 102 may be
generally aligned in a desirable fashion.
[0078] The valve prosthesis 102 may now be further positioned
and/or spatially oriented relative to the annulus A in the manner
desired by the surgeon/clinician, e.g., as viewed through
conventional imaging instrumentation. (Of note, the positioning
elements 120 (and particularly, the upper arcuate regions 126
thereof) may be substantially radio-opaque to facilitate imaging
identification thereof to confirm proper positioning and spatial
orientation of the valve prosthesis 102 relative to the annulus A.)
For example, at such time the surgeon/clinician may begin to relax
an accumulated degree of tension within the lengths 136 of the
plurality of cords 134 (FIG. 2), and thereby begin to allow a
corresponding accumulation of energy/spring force contained in the
legs 116 (FIG. 2) of the resilient element 112 (FIG. 2) and/or in
the positioning elements 120 to cause the lower arcuate regions 128
of the positioning elements 120 to, once again, begin to rotate
radially outwardly. Also for example, and as seen in FIG. 4I, the
lower arcuate regions 128 may be allowed to rotate radially outward
to an extent sufficient to permit the respective tips 306 thereof
to contact and/or engage the cardiac tissue comprising the wall W.
Having retracted to an extent sufficient to permit such tissue
engagement, the legs 116 of the resilient element 112 and/or the
positioning elements 120 may still retain sufficient energy/spring
force to further cause the respective tips 306 to collectively
press against and/or become substantially embedded in place with
respect to the wall W. Such collective spring force may be
sufficient to permit the lower arcuate regions 128 of the
positioning elements 120 to offer a degree of resistance against
vertically upward pullout or displacement of the valve prosthesis
102, e.g., a degree of resistance at least comparable to a
naturally strong degree of resistance against vertically downward
displacement thereof offered by the upper arcuate elements 126
positioned across and/or against the annulus A.
[0079] As also seen in FIG. 4I, upon the valve prosthesis 102 being
determined to be properly positioned and oriented relative to the
annulus A, the cords 134 (FIG. 2) may be withdrawn from the
positioning elements 120. Thereafter, the remainder of the delivery
structure 104 may be disconnected and/or separated from the valve
prosthesis 102 (e.g., the delivery tube 202 may be disconnected
from the hub 114 (FIG. 2) , thereby leaving the valve prosthesis
102 in an appropriate position relative to the patient's diseased
heart valve to serve as a functional replacement thereof The
positioning elements 120 may serve to maintain the native leaflet
membranes (see valve structure V in FIG. 2) in an open position,
and each of the leaflet membranes 108 and the valve skirt 110
mounted with respect to the flexible ring 106 may function to
ensure appropriate directional control of blood flow
therethrough.
[0080] The disclosed valve prosthesis and associated delivery
structures/methods offer numerous advantages relative to existing
systems. For example, the positioning elements associated with the
disclosed valve prosthesis valve include upper and lower arcuate
regions that may advantageously function to engage the annulus as
well as the wall of the ventricular chamber below the annulus,
thereby securely aligning and stabilizing the valve prosthesis
(e.g., in a re-deployable manner) relative thereto. In addition,
the invertible and collapsible aspects of the valve prosthesis
(e.g., for purposes of catheter introduction and the automatic
expansion of the valve prosthesis upon exiting the catheter) may
facilitate efficient percutaneous delivery and in situ manipulation
of the disclosed valve prosthesis system. Further, the disclosed
valve skirt may enhance sealing functionality of the disclosed
valve prosthesis when positioned in situ as compared to that which
might otherwise be the case (e.g., without such a skirt and/or the
annular sealing function provided thereby). Still further, the
"top-hat" geometry and/or functionality of the upper arcuate
regions of the positioning elements may advantageously function to
accurately and securely position the valve prosthesis relative to
an annulus and associated anatomical structures.
[0081] It will be appreciated that the disclosed design and
implantation methodology may not require extensive surgery, and
that the disclosed positioning elements may function to provide
stable and well aligned implantation, central blood flow, and/or a
stable platform for the leaflet membranes. Moreover, positioning
may be more precise than with a balloon expandable device, such as
a stent. Additionally, and also unlike a stent, the positioning may
potentially be repeated (e.g., until the desired implantation
position and/or orientation is achieved). The heart valve
prosthesis described herein may also allow anchoring relative to
the valve annulus in states of the diseased valve in which a stent
may not encounter sufficient tissue to which to adhere (e.g., as is
commonly the case with respect to mitral valve disease).
[0082] In accordance with exemplary embodiments of the present
disclosure, the heart valve prosthesis may be placed squarely at
the site of a diseased heart valve, as distinct from certain
existing heart valve prosthesis implementations characterized by
the use of stents configured for placement in the connecting blood
vessels adjacent to and/or near the diseased heart valve, and, as
such, are designed to be disposed in spaced relation therewith,
whether during or after implantation, or during in situ operation.
As a result, the ability of the operator or surgeon to reposition
and/or re-anchor the heart valve prosthesis in order to more
accurately position the heart valve prosthesis in the opening of
the diseased heart valve, such as may be provided in accordance
with embodiments of the present disclosure, may be of increased
significance.
[0083] The positioning elements 120 of the present disclosure may
be implemented by one or more of a plurality of variations,
including those depicted in FIGS. 5-7. More particularly, a
positioning element 500 depicted in FIG. 5 is one such variation of
the positioning element 120. The positioning element 500 may
include upper and lower arcuate regions 502, 504, an intermediate
region 506 disposed therebetween, and an outer surface 508. An
array 510 of holes 512 may be formed in the outer surface 508 in a
vicinity of the intermediate region 506 to encourage in-growth of
tissue, increasing positional and orientational stability in situ.
Referring now to FIG. 6, a positioning element 600 is another such
variation of the positioning element 120. The positioning element
600 may include upper and lower arcuate regions 602, 604, an
intermediate region 606 disposed therebetween, and an outer surface
608. An array 610 of spikes or spurs 612 may be provided, extending
from the outer surface 608 in a vicinity of the intermediate region
606 to facilitate secure engagement of tissue, similarly increasing
positional and orientational stability in situ. A positioning
element 700 depicted in FIG. 7 is yet another variation of the
positioning element 120. The positioning element 700 may include
upper and lower arcuate regions 702, 704, an intermediate region
706 disposed therebetween, and an outer surface 708. An array 710
of holes 712 may be formed in, and spikes or spurs 714 may be
provided so as to extend from, the outer surface 708 in a vicinity
of the intermediate region 706 to facilitate both in-growth of
tissue and secure engagement of tissue, also increasing positional
and orientational stability in situ. While the holes 512 and 712
and the spurs 612 and 714 are shown in FIGS. 5-7 as appearing in
the respective intermediate regions 506, 606, 706 of the respective
positioning elements 500, 600, 700, such features may
alternatively, and/or in addition, be positioned in one or both of
the upper 502, 602, 702 and lower 504, 604, 704 arcuate regions
thereof.
[0084] Another variation of the positioning element 120 is embodied
by the positioning element 800 of FIG. 8. A leg 802 of a resilient
element 804 may support the positioning element 800, which may in
turn include a lower arcuate region 806 having a tissue-engaging
tip 808 that, in a retracted state of the lower arcuate region 806,
may be coiled or `rolled up` so as to extend inward toward an
intermediate region 810 of the positioning element and/or downward
toward itself A deployment structure 812 may include a cord 814
attached to the lower arcuate region 806 (e.g., near the tip 808
thereof) to uncoil the lower arcuate region 806 so as to permit the
tip 808 to be redirected outward so as to be capable of engaging
with a the cardiac tissue comprising a patient's heart wall (not
shown). A surgeon/clinician may be permitted to pull outward on the
cord 814 during positioning of the positioning element 800, and
once the tip 808 has begun to engage the cardiac tissue, to release
the cord 814, allowing an accumulated energy/spring force inherent
in the lower arcuate region 806 (e.g., the same having a
coil-spring configuration) to impinge with additional force upon
the cardiac tissue. Multiple instances of the positioning element
800 may be provided in a valve prosthesis 816 (not otherwise shown)
such that at least some balancing of reaction forces can be
achieved, and an upper arcuate region 818 of the positioning
element 800 may have a similar coiled configuration (not separately
shown) to that of the lower arcuate region 806.
[0085] A modified version of the valve prosthesis 102 is embodied
by the valve prosthesis 900, the latter being shown partially and
schematically in FIG. 9. The valve prosthesis 900 may include a
resilient element 902 having a leg 904 generally similar to the
legs 116 associated with the above-described resilient element 112.
The leg 904 may support a claw 906 having an upper jaw 908, a lower
jaw 910, and a hinge 912 disposed between the upper and lower jaws
908, 910. The valve prosthesis 900 may further include a torsional
spring (not shown) for biasing the upper and lower jaws 908, 910 of
the claw 906 in favor of closure toward each other, and securely
engaging the cardiac tissue of a patient's heart wall. A deployment
structure 914 may include a cord 916 attached to the upper and
lower jaws 908, 910. A surgeon/clinician may be permitted to pull
outward on the cord 916 to hold the claw 906 open during
positioning of the claw 906. Once the claw 906 has begun to engage
the cardiac tissue (e.g., an annulus A as shown in FIG. 2), the
surgeon/clinician may be permitted to release the cord 916,
allowing the spring bias to act on the upper and lower jaws 908,
910 and thereby allowing the claw 906 to affix itself to the
cardiac tissue. Multiple instances (not shown) of the claw 906 may
be provided in the valve prosthesis 900.
[0086] Respective alternative modified versions of the valve
prosthesis 102 are further embodied by the valve prostheses 1000,
1100, and 1200, shown partially and schematically in FIGS. 10, 11
and 12, respectively. The valve prosthesis 1000 of FIG. 10 may
include a resilient element 1002 having multiple instances of a leg
1004 extending from a hub 1006. The leg 1004 may itself be a
spring, and may include at least two leaves 1008 joined at an
arcuate or bend region 1010. The valve prosthesis 1000 may further
include one or more engaging elements 1012, each of which may
include a plurality of prongs 1014 for piercing and/or otherwise
invasively engaging cardiac tissue as appropriate to secure the
valve prosthesis 1000 in place relative to a diseased heart valve,
and/or relative to an annulus associated therewith. The engaging
element 1012 may be supported by one of the leaves 1008 of the leg
1004, and the valve prosthesis 1000 may include a plurality of sets
of two engaging elements 1012 (e.g., having two prongs 1014 each)
as shown in FIG. 10.
[0087] The valve prosthesis 1100 of FIG. 11 may include a resilient
element 1102 having multiple instances of a leg 1104 extending from
a hub 1106. The leg 1104 may itself be a spring, and may include at
least two leaves 1108 joined at an arcuate or bend region 1110. The
valve prosthesis 1100 may further include one or more engaging
elements 1112, each of which may include two arms 1114 extending
outward from a common point of connection in a V shape. The valve
prosthesis 1100 may further include biasing springs (indicated
schematically at reference numeral 1116) for urging the arms 1114
of the engaging elements 1112 together for purposes of closing the
engaging element 1112 about an annulus associated with a patient's
diseased heart valve. The engaging element 1112 may be supported by
one of the leaves 1108 of the leg 1104, and the valve prosthesis
1100 may include a plurality of such engaging elements 1112.
[0088] The valve prosthesis 1200 of FIG. 12 may include a resilient
element 1202 having multiple instances of a leg 1204 extending from
a hub 1206. The leg 1204 may itself be a spring, and includes at
least two leaves 1208 joined at an arcuate or bend region 1210. The
valve prosthesis 1200 may further include one or more engaging
elements 1212, each of which may include a plurality of teeth 1214
for engaging cardiac tissue as appropriate to secure the valve
prosthesis 1200 relative to a diseased heart valve. The engaging
element 1212 may be directly affixed to one of the leaves 1208 of
the leg 1204 (e.g., the valve prosthesis 1200 may include a
plurality of engaging elements 1212 having two rows of teeth 1214
each as shown in FIG. 12). In some embodiments (not separately
shown), the engaging element 1212 may be hinged at a central
location between the two rows of teeth 1214 such that the engaging
element 1212 may be movable to at least some degree relative to the
leg 1204. Accordingly, in at least some such embodiments, the
engaging element 1212 may be utilized in the manner of a toothed
claw otherwise structurally and functionally similar to the claw
906 described above with reference to FIG. 9.
[0089] A variation of the above-discussed flexible ring 106 is
embodied by a flexible ring 1300 illustrated in FIGS. 13 and 14.
The flexible ring 1300 may be resilient such that it may tend
(e.g., absent any substantial compressive forces) to expand outward
to assume a three-dimensional shape (e.g., the three-dimensional
shape shown FIG. 14), in which the flexible ring 1300 may have a
not insubstantial vertical height, in addition to a characteristic
lateral width or diameter. More particularly, the flexible ring
1300 may include multiple instances of a hoop segment 1302. The
hoop segments 1302 may be contained within a common horizontal
plane (e.g., upon the flexible ring 1300 being expanded out to its
maximum width and height) wherein the hoop segments may be
separated by and/or coupled via a corresponding number of instances
of a coupling segment 1304 extending vertically relative to the
common horizontal plane, constituting at least a portion of the
height extent of the flexible ring 1300. Each hoop segment 1302 may
further include a notch 1306 to facilitate secure coupling of one
or more of a valve skirt similar to the above-described valve skirt
110, at least one leaflet membrane similar to the above-described
leaflet membranes 108, and/or an associated annulus or cuff similar
to that described above. For example, such coupling may be obtained
via a knotted suture (not shown) at least partially lodged within
the notch 1306 so as to restrict relative movement of the valve
skirt, leaflet membrane, and/or cuff relative to and/or about a
circumference of the flexible ring 1300. Each of the coupling
segments 1304 may comprise a spring having two leaves 1308 joined
at an arcuate or bend region 1310, whereby the flexible ring 1300
may be particularly amenable to being radially compressed and/or to
assume a compact shape suitable for compressing a corresponding
valve prosthesis (not separately shown) of which the flexible ring
1300 is a part, and/or passing such a prosthesis through a
narrow-gauge catheter (not shown). More particularly, because the
flexible ring 1300 may include intermittent breaks in its
circumference in the plane of the hoop segments 1302 (e.g.,
associated with the coupling segments 1304), its geometry may
further contribute to an elastic radial compressibility exhibited
by the flexible ring 1300. The bend regions 1310 of the coupling
segments 1304 may further serve as anchoring points functionally
similar to the notches 1306. For example, such notches 1306 may be
used as anchoring points for securing, and/or limiting a length
extent of, commisure seams (not shown in FIGS. 13-14; see, e.g.,
corresponding structure illustrated and described below with
reference to FIGS. 16-20) formed between corresponding leaflet
membranes (not shown) of a heart valve prosthesis (not shown)
incorporating the flexible ring 1300 in accordance with embodiments
of the present disclosure.
[0090] A variation of the valve prosthesis 102 in accordance with
the present disclosure is embodied by a valve prosthesis 1500
illustrated in FIG. 15. The resilient element 1502 of the valve
prosthesis 1500 may be structurally and functionally similar to the
above-described resilient element 112. The legs 1504 of the
resilient element 1502 may flex inwardly toward the delivery tube
202. For example, the legs 1504 may be adapted to flex inwardly
toward the delivery tube 202 in a manner that facilitates an
enhanced degree of radial compression of the valve prosthesis 1500.
Such flexure of the legs 1504 may further permit the valve
prosthesis 1500 to pass along a lumen 1506 of a catheter 1508
exhibiting a smaller internal diameter than would otherwise be the
case.
[0091] A modified version of the valve prosthesis system 100 in
accordance with the present disclosure is embodied by a valve
prosthesis system 1600 illustrated in various stages of operation
in FIGS. 16, 17, 18, 19, and 20. The valve prosthesis system 1600
may include a valve prosthesis 1602 that is a modified version of
the valve prosthesis 102 including substantially all structural and
functional features thereof, with at least some exceptions as
discussed below. The valve prosthesis 1602 may include a resilient
element 1604 having multiple instances of a leg 1606 extending
radially outward from a hub 1608, and multiple instances of a
leaflet membrane 1610. Commissures 1612 between the leaflet
membranes 1610 may be partially closed, or at least limited in
length via respective sutured seams 1614 formed between the leaflet
membranes 1610. For example, the sutured seams 1614 may extend from
a flexible ring 1616 of the valve prosthesis 1602, or from a
location in spaced relation below the flexible ring 1616 (e.g., as
in embodiments of the valve prosthesis (not specifically shown) in
which each of the leaflet membranes 1610 forms a portion of a
larger membrane structure of unitary construction), downward to a
point coinciding with respective free ends or distal edges of the
leaflet membranes 1610. The valve prosthesis system 1600 may
further include a delivery structure 1618 that, in addition to
having cables 1620 and a delivery tube 1622 structurally and
functionally similar to corresponding aspects of the delivery
structure 104, further includes a tower 1624 extending downward
from the hub 1608.
[0092] Among other functions that may be provided thereby, the
tower 1624 may at least participate in defining a central axis 1625
of the valve prosthesis system 1600, and may further introduce an
axial (e.g., vertical or lengthwise) separation between an
elevation (e.g., generally indicated at 1626 in FIG. 20) at which
the legs 1606 meet the hub 1608 and an elevation (e.g., generally
indicated at 1628 in FIG. 20) at which the cables 1620 extend,
and/or are deployed, outward from the central axis 1625. As shown
in FIGS. 16-20, such an arrangement may have the advantage of
displacing and/or routing the cables 1620 generally away from an
elevation (e.g., generally shown at 1630 in FIG. 18) occupied by
the leaflet membranes 1610, and/or by the sutured seams 1614
disposed therebetween. More particularly, such an arrangement may
advantageously reduce and/or eliminate a risk of the cables 1620
abrading or cutting the leaflet membranes 1610 and/or the sutures
of the sutured seams 1614 during a process of deploying, adjusting
a position of, and/or otherwise implanting the valve prosthesis
1602. Such a risk does not necessarily exist with respect to any
particular embodiment of a heart valve prosthesis in accordance
with the present embodiment. For example, embodiments in accordance
with the present disclosure of the heart valve prosthesis 102 shown
and described herein with reference to FIGS. 1, 2, 3A-3B, and 4A-4I
exist in which such a risk is either remote, or for all practical
purposes, non-existent. Nevertheless, it is contemplated that such
a risk may exist with respect to at least some heart valve
prosthesis embodiments in accordance with the present disclosure,
including, for example, embodiments in which the particular
dimensions of, or the particular materials specified for, the
sutures of the sutured seams 1614, and/or the leaflet membranes
1610, are optimized for purposes of providing maximum functionality
and/or durability in situ, but wherein such optimization
unfortunately has the effect of leaving such components at
increased risk of damage from frictional interaction with the
cables 1620 during prosthesis implantation. In such circumstances,
at least, the use of a tower 1624, or of another component
structurally and/or functionally similar thereto, to introduce an
appropriate axial separation between the cables 1620 and the
leaflet membranes 1610, and/or between the cables 1620 and the
sutured seams 1614, may provide a particular advantage.
[0093] As is particularly evident in FIG. 20, such an arrangement
may further permit additional energy and/or spring force to be
built up within the resilient element 1604 by imparting significant
flexure to the resilient element 1604 where the legs 1608 meet the
hub 1606. For example, and as sequentially illustrated in FIGS.
16-20, a sufficient amount of flexure may be imparted thereby to
the resilient element 1604 to cause the hub 1606 to be raised to an
elevation substantially entirely above those of the respective
positioning elements 1632 during a corresponding process of
deployment from a catheter 1634, in which the positioning elements
1632 may be overturned or inverted relative to the flexible ring
1616 and the hub 1608 in preparation for placement of the valve
prosthesis 1602 with respect to a patient's diseased heart valve.
Such elevated placement of the hub 1608 relative to the positioning
elements 1632 may further persist in the final in situ
configuration of the valve prosthesis 1602 within the diseased
heart valve (not specifically shown), such that an elevation of the
hub 1608 may be and/or remain even with or above that of the
corresponding annulus A (see FIG. 2 for comparison). Still further,
in such circumstances, the legs 1608 may assume a final
configuration relative to the hub 1606 such that: i) the legs 1608
either effectively no longer extend vertically upward from the hub
1608; or ii) an extent to which the legs 1608 continues to so
extend upward from the hub 1606 is substantially reduced; and/or
iii), the legs 1608 have substantially completely been overturned
relative to the flexible ring 1616 so as to extend substantially
completely downwardly from the hub 1608. Any one or all of these
arrangements of the legs 1608 of the resilient element 1604
relative to the hub 1606 thereof and/or relative to the flexible
ring 1616 may have the advantageous effect of reducing an
occurrence of or an extent of eddies or turbulence in the flow of
blood past or through the resilient element 1604. In such
circumstances, a risk of undue tissue damage in the associated
blood flow volume may be reduced. More particularly, to the extent
such eddies and/or turbulence may be attenuated as described above,
an extent and/or magnitude of a shear force characteristic of the
flow of blood through the heart valve prosthesis 1602, and
potentially associated with and/or causing such tissue damage, may
be beneficially adjusted, limited, and/or reduced.
[0094] A variation of the valve prosthesis system 100 is embodied
by a valve prosthesis system 2100 illustrated in FIG. 21. The valve
prosthesis system 2100 may include a valve prosthesis 2102 and a
delivery structure 2104. The valve prosthesis 2102 may be a
variation of the above-discussed valve prosthesis 102, and the
delivery structure 2104 may be a variation of the above-discussed
delivery structure 104. The delivery structure 2104 may include an
outer catheter 2106, a guide wire 2108, and a tool 2110 for
allowing a surgeon/clinician to move the valve prosthesis 2102
within and relative to the outer catheter 2106 along the guide wire
2108. For the sake of convenience, the valve prosthesis 2102 is
shown twice in FIG. 21, once in a folded/compressed configuration
(e.g., suitable for insertion into the outer catheter 2106 at a
receiving end 2112 thereof), and once in an expanded configuration
(e.g., after deployment from the outer catheter 2106 at a
discharging end 2114 thereof).
[0095] Referring now to FIG. 22, the valve prosthesis 2102 is shown
in the folded/compressed configuration shown in FIG. 21 for
movement within the outer catheter 2106 along the guide wire 2108.
The valve prosthesis 2102 may include a sleeve 2200 extending
downward to at least some extent from a hub 2202 of a resilient
element 2204. The delivery structure 2104 may further include a
cable guide tube 2206 for accommodating the guide wire 2108 and a
set of deployment cables 2208, and a delivery tube 2210 including a
central lumen 2212.
[0096] The delivery structure 2104 may still further include a
fitting 2214. The fitting 2214 may extend entirely through the hub
2202 and the sleeve 2200 such that at least an upper portion 2216
of the fitting 2214 is disposed above the hub 2202, and at least a
lower portion 2218 of the fitting 2214 is disposed below the sleeve
2200. The fitting 2214 may include a central lumen 2220 via which
the guide wire 2108 and the deployment cables 2208 may pass through
the fitting 2214 (and, thereby, through the hub 2202). The upper
portion 2216 of the fitting 2214 may be sized and shaped (e.g., via
external circumferential ribs 2222) for press-fit insertion within
the central lumen 2212 of the delivery tube 2210, and/or to receive
a corresponding end of the cable guide tube 2206 for press-fit
termination thereof within the central lumen 2220. The lower
portion 2218 of the fitting 2214 may form a tower 2224. The tower
2224 may be a variation of the above-described tower 1624 (FIG.
16).
[0097] The delivery tube 2210 and the fitting 2214 may be keyed to
each other to prevent relative rotation therebetween. For example,
an end of the delivery tube 2210 adjacent the hub 2202 may include
one or more slots 2226, and the fitting 2214 may include one or
more complementary radially-protruding tabs (not separately shown)
to mate with the slots 2226 upon the fitting 2214 being press-fit
within the central lumen 2212 of the delivery tube 2210. Other
anti-rotation solutions and/or features are possible.
[0098] The cable guide tube 2200 may have multiple components,
including an internal length of metal tubing 2228, and an external
length of shroud-type tubing 2230. The internal length of metal
tubing may be thin-walled and braided for stiffness and/or
resistance to kinking. The external length of shroud-type tubing
may be sized, shaped and configured to facilitate formation of a
press-fit termination within the central lumen 2220 of the fitting
2214.
[0099] In FIG. 23, the valve prosthesis 2102 is shown after having
emerged from the discharging end 2114 of the outer catheter 2106,
and after the surgeon/clinician has permitted the positioning
elements 2300 to overturn relative to a flexible ring 2302 and/or
relative to the hub 2202 (e.g., via an internally-generated spring
force), and/or has utilized the tool 2110 (FIG. 21) and the cables
2208 to cause or assist in causing the positioning elements 2300 to
overturn relative thereto. As described above with reference to the
valve prosthesis 1602 of FIGS. 16-20, the tower 2224 may
beneficially extend a point of radial distribution of the cables
2208 axially downward to an elevation below that at which a
plurality of legs 2302 of the resilient element 2204 meet the hub
2202 thereof. In embodiments, the sleeve 2200, which may be
funnel-shaped and swaged to the hub 2202, may facilitate this
function by providing lateral support to the cable deployment tower
2224.
[0100] Referring now to FIG. 24, the delivery structure 2104 may
further include one or more additional cables 2400. The cables 2400
may function to axially secure the delivery tube 2210 to the hub
2202, and/or to the sleeve 2200, until such time as the valve
prosthesis 2102 is determined to be properly positioned and
oriented relative to the patient's diseased heart valve. More
particularly, each instance of a cable 2400 may form a
corresponding loop around a portion of the sleeve 2200, and include
lengths 2402 passing upward therefrom. For example, one such length
2402 may pass through the central lumen 2212 (FIG. 22) of the
delivery tube 2210, and the other such length 2402 may pass upward
within a space (not separately shown) between the delivery tube
2210 and the outer catheter 2106 (FIG. 21). Such cables 2400 may
further be withdrawn from the delivery structure 2104 when no
longer needed (e.g., upon the valve prosthesis 2102 being
determined to be properly positioned and oriented relative to the
patient's diseased heart valve). The delivery tube 2210 and the hub
2202 may now no longer axially secured to each other, and the
fitting 2214 and the delivery tube 2210 may remain axially secured
to each other. In such circumstances, the surgeon/clinician may
elect to withdraw the delivery tube 2210 from the patient's body
via the outer catheter 2106 (FIG. 21) by pulling upward and outward
on the delivery tube 2210. As the tower 2224 may be part of the
fitting 2214, the surgeon/clinician may, by pulling upward on the
delivery tube 2210, further withdraw the tower 2224 upward from and
out of the hub 2202. The sleeve 2200 may travel outward of the
patient's body along with the delivery tube 2210.
[0101] Another variation of the valve prosthesis system 100 is
embodied by a valve prosthesis system 2500 illustrated in FIG. 25.
The valve prosthesis system 2500 may include a valve prosthesis
2502 and a delivery structure 2504. The valve prosthesis 2502 may
be a variation of the above-discussed valve prosthesis 102, and the
delivery structure 2504 may be a variation of the above-discussed
delivery structure 104. The delivery structure 2504 may include an
outer catheter 2506 and a guide wire 2508 for allowing a
surgeon/clinician to move the valve prosthesis 2502 within and
relative to the outer catheter 2506 via an appropriate tool (e.g.,
tool 2110 of FIG. 1) along the guide wire 2508. The valve
prosthesis 2502 is shown in a folded/compressed configuration for
movement within the outer catheter 2506 along the guide wire
2508.
[0102] The delivery structure 2504 may further include a set of
deployment cables 2510, a delivery tube 2512 including a central
lumen 2514, and a fitting 2516. The fitting 2516 may extend
entirely through a hub 2518 of a resilient element 2520 of the
valve prosthesis 2502 such that at least an upper portion 2522 of
the fitting 2516 is disposed above the hub 2518, and at least a
lower portion 2524 of the fitting 2516 is disposed below the hub
2518. The fitting 2516 may include a central lumen 2526 via which
the guide wire 2508 and the deployment cables 2510 may pass through
the fitting 2516 (and, thereby, through the hub 2518). The upper
portion 2522 of the fitting 2516 may be sized and shaped (e.g., via
external circumferential ribs 2528) for press-fit insertion within
the central lumen 2514 of the delivery tube 2512. The lower portion
2524 of the fitting 2516 may form a tower 2530. The tower 2530 may
be a variation of the above-described tower 1624 (FIG. 16).
[0103] In FIG. 26, the valve prosthesis 2502 is shown after having
emerged from the outer catheter 2506 (FIG. 22), and after the
surgeon/clinician has permitted the positioning elements 2600 to
overturn relative to a flexible ring 2602 and/or relative to the
hub 2518 (e.g., via an internally-generated spring force), and/or
has utilized an appropriate tool (e.g., tool 2110 of FIG. 21) and
the cables 2510 to cause the positioning elements 2600 to overturn
or invert relative thereto. As described above with reference to
the valve prosthesis 1602 of FIGS. 16-20, the tower 2530 may
beneficially extend a point of radial distribution of the cables
2510 axially downward to an elevation below that at which a
plurality of legs 2604 of the resilient element 2520 meet the hub
2518 thereof.
[0104] Referring now to FIG. 27, the fitting 2516 may further
includes multiple instances of an outwardly-biased, inwardly
deflectable finger 2700 extending from a point on the cable
deployment tower 2530 below the hub 2518, through a corresponding
cutout in the hub 2518, and upward to a point on the fitting 2516
above the hub 2518. When each such finger 2700 is in its outwardly
biased position, corresponding interlocking features (not
separately shown) formed in the hub 2518 and the fingers 2700 may
cooperate to secure the valve prosthesis 2502 axially relative to
the fitting 2516. Each such finger 2700 may be further deflectable
radially inwardly into an accommodating cavity 2702 formed in the
fitting 2516. The delivery structure 2504 may further include a
collar 2704 that may be disposed around the fitting 2516 between
each such finger 2700 and its corresponding cavity 2702, such that
whenever the collar 2704 is so positioned, the finger 2700 may be
prevented from being deflected into its corresponding cavity 2702.
The delivery structure 2504 may still further include one or more
cables 2706 forming a corresponding loop around each such finger
2700 so as to be useable to pull or retract each such finger 2700
into its corresponding cavity 2702 in the absence of the collar
2704. The delivery structure 2504 may yet further include one or
more cables 2708 forming corresponding loops around a flange 2710
of the collar 2704 so as to be useable to pull the collar 2704
upward and away from the fingers 2700 such that the collar 2704
ceases to block inward deflection of the fingers 2700. Accordingly,
upon the valve prosthesis 2502 being determined to be properly
positioned and oriented relative to the patient's diseased heart
valve, a surgeon/clinician may pull or otherwise manipulate the
cables 2708 to displace the collar 2704 upward and away from the
fingers 2700, and pull or otherwise manipulate the cables 2706 to
deflect the fingers 2700 inward toward the cavities 2702, and out
of engagement with the hub 2518. The hub 2518 and the fitting 2516
may now no longer being axially secured relative to each other, and
the fitting 2516 and the delivery tube 2512 (FIG. 25) may remain
axially secured relative to each other. In such circumstances, the
surgeon/clinician may elect to withdraw each of the fitting 2516
and the delivery tube 2512 from the patient's body via the outer
catheter 2506 by pulling upward on the delivery tube 2512. As the
tower 2530 may be part of the fitting 2516, the surgeon/clinician
may, by pulling upward on the delivery tube 2512, withdraw the
tower 2530 upward from and outward of the hub 2518.
[0105] Still another variation of the valve prosthesis system 100
is embodied by a valve prosthesis system 2800 illustrated in FIGS.
28 and 34. The valve prosthesis system 2800 may include a valve
prosthesis 2802 and a delivery structure 2804. The valve prosthesis
2802 may be a variation of the above-discussed valve prosthesis
102, and the delivery structure 2804 may be a variation of the
above-discussed delivery structure 104.
[0106] The delivery structure 2804 may include a release tube 2806
having a distal end 2808 adjacent the valve prosthesis 2802, a
locking sleeve 2810 positioned adjacent the valve prosthesis 2802
and coupled to the release tube 2806 at the distal end 2808
thereof, and a tower 2812 extending through and beyond the valve
prosthesis 2802. The tower 2818 may be a variation of the
above-discussed tower 1624.
[0107] The delivery structure 2804 may further include a tool 2814.
The tool 2814 may be configured to permit and/or facilitate a
surgeon/clinician, among other functions described in more detail
hereinafter, to move the valve prosthesis 2802 within and relative
to an outer catheter (not shown) along a guide wire (not shown), to
deliver and/or deploy the valve prosthesis 2802 adjacent a
patient's diseased heart valve, to position the deployed valve
prosthesis 2802 relative to such heart valve before and during a
prosthesis implantation procedure, and/or to cause the valve
prosthesis 2802 to be released after deployment and positioning
thereof in situ., allowing the valve prosthesis 2802 to remain in
place and the delivery structure 2804 to be entirely withdrawn from
the patient's body.
[0108] The tool 2814 may include a body 2816 having a proximal end
2818 directed away from the patient and a distal end 2820 directed
toward the patient, a gripping handle 2822 disposed between the
proximal end 2818 and the distal end 2820, a prosthesis
manipulation mechanism 2824 mounted with respect to the body 2816
at the proximal end 2818 thereof, and a prosthesis release
mechanism 2826 mounted with respect to the body 2816 at the distal
end 2820 thereof The prosthesis deployment mechanism 2824 may
include an actuation arm 2828 movably mounted the body 2816, a
cable mount 2830, and an attachment fitting 2832 for attaching the
cable mount 2830 to the actuation arm 2828 for movement therewith
relative to the body 2816. The cable mount 2830 may include a port
2834 for receiving and/or discharging a guide wire (not shown), and
multiple instances of an attachment fitting 2836 for attaching a
respective cable (not shown) to the cable mount 2830 for movement
therewith relative to the body 2816. The prosthesis release
mechanism 2826 may include an attachment fitting 2838 for attaching
the release tube 2806 to the tool 2814, and an actuation wheel 2840
movably mounted to the body 2816 for moving the release tube 2806
and the locking sleeve 2810 relative to the body 2816, and/or
relative to the valve prosthesis 2802.
[0109] As shown in FIGS. 29 and 31, the valve prosthesis 2802 may
include a hub 2900 and a resilient element 2902 coupled to the hub
2900. The resilient element 2902 may include a hub flange 2904 at
which the resilient element 2902 may be coupled to the hub 2900 and
multiple instances of a leg 2906 that may extend radially outward
from the hub flange 2904. One or more of the multiple instances of
a leg 2906 may be of unitary construction with the hub flange 2904.
In FIGS. 29 and 31, the valve prosthesis 2802 is shown after having
emerged from an outer catheter (not shown), and after the
surgeon/clinician has utilized the tool 2814 (FIG. 25) to pull
corresponding deployment cables (not shown) relative to the valve
prosthesis 2802 so as to overturn positioning elements (not shown)
relative to a flexible ring (not shown), and/or relative to the hub
2900, and/or relative to the hub flange 2904. In addition to
including the release tube 2806, the locking sleeve 2810 attached
to the proximal end 2808 of the release tube 2806, and the cable
deployment tower 2812 extending through and beyond the hub 2900 and
the resilient element 2902 of the valve prosthesis 2802 as
discussed above with reference to FIGS. 28 and 34, the delivery
structure 2804 includes a cable guide tube 2908 disposed within the
release tube 2806. As shown in FIGS. 30 and 31, the cable guide
tube 2908 includes an interior wall 3000 defining a central lumen
3002, an exterior wall 3004 defining an outer surface 3006 and,
with a series of radially-extending interior walls 3008, defining
multiple instances of a peripheral lumen 3010 arranged in a regular
pattern around the central lumen 3002.
[0110] Referring now to FIG. 32, the hub 2900 of the valve
prosthesis 2802 includes a body 3200 including a wall 3202. The
wall 3202 is cylindrical in shape so as to define a central lumen
3204 passing through the body 3200, the central lumen 3204 being
sized and shaped so as to receive and accommodate the cable
deployment tower 2812. Each of the hub 2900 and the cable
deployment tower 2812 may be fabricated from stainless steel, and
the inner diameter of the central lumen 3204 of the hub 2900 and
the outer diameter of the cable deployment tower 2812 may be
controlled relative to each other such that a relatively precise
lateral fit exists between the two parts while also permitting
relatively free movement of the cable deployment tower 2812 in the
axial direction relative to the hub 2900 for purposes of pulling
the cable deployment tower 2812 free of the valve prosthesis 2802
upon the latter being implanted within a patient's diseased heart
valve (not shown) (e.g., wherein the only available reaction force
is that which is provided by the cardiac tissue with which the
valve prosthesis 2802 is engaged).
[0111] The wall 3202 of the hub 2900 extends axially to define the
central lumen 3204. At an intermediate position along an axial
extent of the hub 2900, an annular ledge 3206 extends outward from
the wall 3202. The hub flange 2904 of the resilient element 2902
attaches to the hub 2900 at the circumferential skirt 3206. At an
upper end of the axial extent of the hub 2900, the body 3200
further includes a coupling interface 3208. The coupling interface
3208 includes an annular protrusion 3210 extending outward from the
wall 3202, which as shown in FIG. 32, may be have a rounded
profile.
[0112] Still referring to FIG. 32, the delivery structure 2804
further includes a guide wire sleeve 3212, a fitting 3214, and a
resilient element 3216. The guide wire sleeve 3212 is disposed
within the cable deployment tower 2812. The fitting 3214 joins,
within the release tube 2806, the cable guide tube 2908 (on one
side of the fitting 3214) with the cable deployment tower 2812 and
the guide wire sleeve 3212 (on an opposite side of the fitting
3214). Referring now to FIG. 33, the resilient element 3216
includes a distal end 3300 that includes a collar 3302 that at
least partially defines a central lumen 3304 through the resilient
element 3216, and a proximal end 3306 featuring a coupling
interface 3308. The coupling interface 3308 is peripherally
segmented and includes multiple instances of an outwardly biased
and inwardly deflectable spring finger 33 10. Each such spring
finger 3310 includes a depression 3312 having a segmented annular
shape and sectional profile to match that of the annular protrusion
3210 (FIG. 32) of the coupling interface 3208 of the hub 2900.
[0113] Referring again to FIG. 32, the resilient element 3216 may
be affixed to the cable deployment tower 2812 such that the latter
is lodged within the central lumen 3304 of the former. The locking
sleeve 2810 includes an axially narrowed distal end 3218 near which
the locking sleeve 2810 is lodged within the proximal end 2808 of
the release tube 2806, and an axially expanded proximal end 3220
extending toward the valve prosthesis 2802. The proximal end 3220
of the locking sleeve 2810 is of a large enough interior diameter
to surround and extend over the proximal end 3306 (FIG. 33) of the
resilient element 3216. The relative dimensions of the resilient
element 3216 and the locking sleeve 2810 are such that the locking
sleeve 2810 is capable of deflecting the spring fingers 3310 (FIG.
33) of the resilient element 3216 inward. If at this time the
coupling interface 3308 (FIG. 33) of the resilient element 3216 and
the coupling interface 3208 of the hub 2900 overlap each other
(e.g., axially), the hub 2900 and the resilient element 3216 will
become axially coupled, and may be moved axially within an outside
catheter (not shown) together as a unit. Additionally, upon the
valve prosthesis 2802 being properly positioned and oriented with
respect to a patient's diseased heart valve, such an arrangement
enables a surgeon/clinician to release the valve prosthesis 2802 by
causing the release tube 2806 to retract away from the valve
prosthesis 2802 and the resilient element 3216 such that the spring
fingers 3310 deflect radially outward and lose their grip on the
annular protrusion 3210 of the hub 2900. At this time, and as
described in greater detail above, the cable deployment tower 2812
can be smoothly withdrawn from within the hub 2900, and the
delivery structure 2804 completely withdrawn from the patient via
the external catheter (not shown).
[0114] Turning now to FIG. 35, the tool 2814 includes a central
lumen 3500 extending through an entire axial length of the tool
2814. The central lumen 3500 is adapted to accommodate, at least, a
guide wire (not shown).
[0115] Referring now to FIG. 36, the body 2816 of the tool 2814
includes a central cavity 3600, and the actuation arm 2828 of the
prosthesis deployment mechanism 2824 is disposed within and moves
relative to the central cavity 3600. Cables (not shown) passing
through the actuation arm 2828 may pass into the cable mount 2830
and extend into one or more passages in communication therewith and
terminating in an attachment fitting 2832, at which the cable (not
shown) may be axially secured to the cable mount 2830, and by
extension, to the actuation arm 2828. In the specific example of
FIG. 28, up to six separate cables may be so accommodated and
axially coupled to the cable mount 2830. Other numbers of cables
accommodated by a cable mount with more or fewer attachment
fittings are possible.
[0116] In some embodiments of the present disclosure, the cable
guide tube 2908 may extend through the tool 2814, e.g., at least to
an extent of the prosthesis deployment mechanism 2824. In at least
some circumstances in accordance with embodiments of the present
disclosure, a surgeon/clinician may not necessarily require the
cable guide tube 2908 to be or remain axially fixed with respect to
the tool 2814. In such circumstances, the tool 2814 may include no
particular securing mechanism with respect to the cable guide tube
2908, in which case a proximal end of the cable guide tube 2908 may
extend into the tool 2814, wherein neither the proximal end nor or
any other portion of the cable guide tube 2908 will necessarily be
lodged in a corresponding fitting, or terminated in any particular
way, facilitating axial relative motion between the cable guide
tube 2908 and the tool 2814. By contrast, and in at least some
circumstances in accordance with the present disclosure, a
surgeon/clinician requiring the cable guide tube 2908 to at least
temporarily be or remain axially fixed with respect to the tool
2814. In such circumstances, the surgeon/clinician may rely on an
overall or locally substantial static or dynamic friction within
the delivery structure 2804 (e.g., between the cable guide tube
2908 and other portions of the delivery structure 2804, such as the
release tube 2806). Alternatively, and/or in addition, the tool
2814 may further include a clamp or fitting (not shown) or other
similar mechanism or securing means to at least temporarily secure
(e.g., axially fix) the cable guide tube 2908 with respect to the
tool 2814, e.g., with respect to the body 2816 of the tool 2814,
and/or to the prosthesis deployment mechanism 2824 thereof. Other
configurations are possible.
[0117] Referring again to FIG. 28, once the required cables (not
shown) are secured to the cable block 2830, and provided the
locking sleeve 2810 is in place over the spring fingers 3310 (FIG.
33) of the resilient element 3216 (FIG. 32) and the annular
protrusion 3210 of the hub 2900 (FIG. 32), and the valve prosthesis
2802 is free of the outer catheter (not shown) and is positioned
adjacent a patient's diseased heart valve, a surgeon/clinician may
grasp the gripping handle 2822 with one hand, grasp the actuation
arm 2828 with the other hand, and pull the actuation arm 2828
outward of the body 2816 to move the cables outward of the valve
prosthesis 2802 to cause the valve prosthesis to assume the proper
shape for insertion into the valve (e.g., see, e.g., FIGS. 4F and
20). In some embodiments of the present disclosure, once the valve
prosthesis 2802 assumes such proper valve insertion shape, the
actuation arm 2828 may be rotated relative to the body 2830 to
engage a catch (not separately shown) that preserves the existing
axial positions of the actuation arm 2828 and the body 2830
relative to each other, enabling the surgeon/clinician to focus on
proper placement of the valve prosthesis 2802 relative to the
diseased valve without being concerned that the valve prosthesis
2802 will abruptly revert to a previously held shape or assume any
other shape that is not intended.
[0118] Referring to FIG. 37, the prosthesis release mechanism 2826
may further include an attachment sleeve 3700 that is spring biased
outward of the proximal end 2820 of the tool 2814 but is moveable
axially relative to the body 2816. The attachment sleeve 3700
receives the release tube 2806 and the attachment fitting 2838,
wherein the attachment fitting 2838 cooperates with the attachment
sleeve 3700 to axially secure a distal end 3702 of the release tube
2806 relative to the attachment sleeve 3700. The prosthesis release
mechanism 2826 further includes one or more anti-rotation pins 3704
emerging from the attachment sleeve 3700 and interacting with an
axially-extending channel 3706 formed in the body 2816 of the tool
2814 so as to prevent rotation of the attachment sleeve 3700
relative to the body 2816 but permit the attachment sleeve 3700 to
translate axially relative thereto. The actuation wheel 2840may be
coupled to the body 2816 of the tool 2814 via screw threads and may
be adapted to contact the pins 3704 and urge the pins 3704 axially
inward relative to the body 2816. This may cause the release tube
2806 to retract away from the valve prosthesis 2802, such that the
resilient element 3216 (FIG. 32) is uncovered by the locking sleeve
2810, the spring fingers 3310 separate from the hub 2900, and the
delivery structure 2804 is no longer capable of axially urging the
valve prosthesis 2802. As described above, in such circumstances,
the delivery structure 2804 may be withdrawn from the patient,
leaving the valve prosthesis 2802 in place relative to the diseased
heart valve.
[0119] Although implementations of the invention have been
described in detail above, those skilled in the art will readily
appreciate that many additional modifications are possible without
materially departing from the novel teachings and advantages of the
invention. Any such modifications are intended to be included
within the scope of the invention as defined in the following
claims.
* * * * *