This invention relates to devices and methods for creating, maintaining, controlling, and closing a fluid communication between opposing surfaces of a tissue wall.
In the human body, various organs contain fluids both in liquids and gaseous forms within tissue layers or cavities formed by tissue. These liquids may or may not be under pressure. The tissue walls around these cavities are normally designed to confine these liquids to specific areas of the body. Blood as in the heart and vasculature in order to preserve its volume and transport oxygen to tissue, gastric and intestinal fluids as in the stomach and intestines in order to transport remains of digestion out of the body after nutrients are absorbed, urine in the bladder in order to expel liquid waste from the body, fluid within the eye to maintain its shape and passage of light, are examples of such tissue fluid confining systems. During medical procedures within these cavities it is of extreme importance to control the fluid within. The most common example is cardiopulmonary bypass during open hearts surgery, although, in all procedures associated with the system above emphasis is placed on control of the fluid within the organ. For this control, sometimes extra space is required to conduct these interventions; therefore, highly invasive procedures may be required for surgery within these cavities, especially while maintaining organ function. The most complex example of these being beating heart surgery. For less invasive procedures, especially those within the vascular system, access ports or conduits which allow for fluid communication, control and tissue closure within the organ being repaired are therefore required.
The various conduit and/port devices and systems described herein may be utilized as an accompaniment with any number of surgical procedures to gain access through a variety of possible tissues. For example, the conduit devices and systems may be utilized to provide fluid access across a tissue wall, such as, but not limited to, upon establishing an AAC, upon establishing a port for inter-ventricular repairs (e.g., valve repair, valve replacement, or ablation procedures, etc.), upon establishing valved and/or open conduits (including bypass conduits) to augment native blood vessels in order to treat a variety of vascular conditions (e.g., aortic valvular disease, congestive heart failure, left ventricle outflow tract obstructions (“LVOTO”), peripheral arterial obstructions, small vessel obstructions, etc.), upon providing a conduit across a urinary bladder wall, upon providing a conduit across a gall bladder wall, upon providing a conduit into a thoracic cavity, upon providing a conduit into an abdominal cavity, upon providing a conduit into a cecal cavity, upon providing access into the cornea or eye walls, or upon providing access across or into any other tissue wall structures. Accordingly, the conduit devices and systems described herein may be utilized with any of the aforementioned procedures and/or to gain access through any of the aforementioned tissue walls.
Because of the importance of heart function and the complexities associated to this pressurized system, some of the most complex procedures associated with bodily fluids are performed on this organ. Several of these procedures would benefit from a conduit or port which can maintain a fluid tight seal with tissue surfaces.
Heart valve replacement is the most common open heart cardiovascular surgery procedure, currently most heart valve repair or replacement surgeries are conducted on a heart at rest under cardiopulmonary bypass through a large median sternotomy. This surgery is highly invasive, and therefore, the population that may survive such a procedure is limited to those who are strong surgical candidates. In recent years valves for minimally invasive deployment through the femoral artery or apex of the heart have been developed. These valves may be used in patients that would under other conditions be deemed non-candidates. The use of these valves may also in the future reduce complications associated with cardiopulmonary bypass and large incisions in surgical candidates. For those procedures through the apex of the heart it has been shown that bleeding complications are directly associated with 50% increased mortality, therefore, and access conduit or port which would reduce bleeding complications, decrease incision size and simplify closure would be of great benefit.
Another procedure that would benefit from a fluid tight conduit or port into the heart would be the construction of an alternative conduit between the left ventricle and the aorta (an apicoaortic conduit, or AAC). This procedure creates a double-outlet left ventricle (LV) to treat a variety of complex congenital LV outflow obstruction (fibrous tunnel obstruction, aortic annular hypoplasia, tubular hypoplasia of the ascending aorta, and patients with diffuse septal thickening, severe LV hypertrophy and a small LV cavity) as well as adult-onset aortic stenosis in patients with complicating preoperative conditions (previous failed annular augmentation procedures, previous infection, previous CABG with patent anterior internal mammary artery grafts, and a porcelain ascending aorta). However, the AAC insertion procedure has been poorly accepted, with or without cardiopulmonary bypass, has not been as technically straightforward as direct aortic valve replacement. Nonetheless, several studies have demonstrated that AAC insertion successfully lessens the LV-aortic pressure gradient, preserves or improves ventricular function and maintains normally distributed blood flow through the systemic and coronary circulation.
While there have been several techniques described, the most commonly employed method is the lateral thoracotomy approach with placement of the AAC to the descending aorta or a median sternotomy. The current techniques and technology available to perform AAC insertion were originally designed to be performed on-pump; either with an arrested or fibrillating heart, therefore, highly invasive. While off-pump cases have been described, they can be technically difficult due to the shortcomings of presently available conduits and systems for installing such conduits. For example, because existing conduits require the use of sutures to reliably secure the connector in place, it is often difficult for surgeons or other clinicians to insert such sutures reliably in active cardiac and/or vascular tissue.
Some devices and methods have been devised to install an AAC conduit, such as those described generally in U.S. Patent Publication No. 2006/0089707 which is hereby incorporated by reference herein in its entirety. However, these AAC conduit devices and installation systems rely on the use of a flexible flange that is inserted through a pre-defined aperture in the ventricular apex. Thus, such methods require the use of a haemostatic device (such as an occlusion balloon and/or “umbrella” device) to prevent blood loss from the aperture during installation of the AAC conduit. Other apical conduit devices are described in U.S. Pat. No. 7,846,123, which is also hereby incorporated by reference in its entirety.
Accordingly, improved beating heart fluid tight conduits for heart surgery as such described herein, are desirable.
Various embodiments of the present invention provide an improved system and method for the insertion of a conduit connector or port (such as an AAC conduit) that will significantly simplify the in vivo beating heart treatment of cardiac patients. The connector, port or conduit may be inserted into the beating cardiac apex or other tissue walls (such as other areas of the heart including the anterior, lateral, posterior walls of the left or right ventricle, the left or right atrium, the aortic wall, ascending, transverse, or descending, or other blood vessel walls), such that it may effectively reduce and/or negate the detrimental effects of both cardio-pulmonary by-pass (CPB) and global cardiac ischemia. Additionally, embodiments of such conduits that may be capped as ports and may be used as an access site for intravascular and intracardiac procedures such as valve repair or replacement. Various embodiments of the present invention may also provide general conduit devices (and systems for implanting) suitable for establishing fluid communication between opposing surfaces of tissue walls in a variety of applications, including the establishment of a fluid conduit through the tissue wall of a mammalian stomach or urinary bladder.
In one exemplary embodiment, a system is provided for implanting a conduit device in a tissue wall having a first surface and an opposing second surface. According to some embodiments, the system comprises an outer tube defining a guide aperture extending axially through the outer tube and an attaching device extending from a distal end of said outer tube. The attaching device is configured for advancing along a helical path at least partially through the tissue wall such that at least a portion of the attaching device becomes disposed substantially between the first surface and the opposing second surface of the tissue wall when the outer tube is rotated relative to the first surface of the tissue wall. The attaching device, in some system embodiments, comprises at least one of a helical static coil and a helical elastic spring having a sharpened distal end adapted for piercing the tissue wall as the outer tube is rotated relative to the first surface of the tissue wall. According to some such embodiments, the attaching device may define a radially-expanding helix as the attaching device extends away from the distal end of the outer tube. In such configuration the insertion of the radially expanding helix within the tissue will create inward pressure or contraction of said tissue within the circumference of the coil.
In some embodiments, the system also comprises a ring or flange operably engaged about an outer surface of the outer tube and configured for cooperating with the attaching device such that at least a portion of the tissue wall is secured between the attaching device and the ring so as to operably engage said outer tube with the tissue wall. In some embodiments, various system components, such as the outer tube and the ring, may be configured to conform to and/or establish a substantially fluid-tight seal with at least a portion a surface of the tissue wall. In some embodiments, the system may be configured to cooperate and/or operably engage a tissue wall comprising a substantially curved tissue wall. According to some such embodiments, the ring may comprise a frusto-conical assembly or flange configured for receiving at least a portion of the substantially curved tissue wall so as to form a substantially fluid-tight seal between the frusto-conical assembly and the tissue wall.
In some embodiments, the system further comprises an inner tube configured for insertion into the guide aperture defined by the outer tube. According to such embodiments, the inner tube defines a conduit aperture extending axially therethrough. Furthermore, in some such embodiments, the outer tube may comprise a first securing device operably engaged with a proximal end of the outer tube and the inner tube may comprise a complementary second securing device operably engaged with a proximal end of said inner tube. Thus, according to such embodiments, the second securing device may be configured for selectively operably engaging the first securing device so as to operably engage the inner tube with the outer tube to install and maintain the conduit.
In some embodiments, the system may also comprise a coring or piercing device configured for advancing through the conduit aperture defined by the inner tube and through the tissue wall to define an aperture therein. The coring or piercing device may be further configured for carrying the inner tube through the aperture such that the inner tube extends at least partially through the aperture so as to establish fluid communication between the first and second surfaces of the tissue wall. In the embodiments associated with attaching devices including radially expanding helices, inward compression of the tissue will form a sealing surface against the outer surface in the inner tube.
Various other embodiments of the present invention provide a conduit system including an outer lumen, an inner lumen, and an attaching device. In other embodiments, a multiple access port device adapted for communication with at least one of an outer lumen, an inner lumen, or an attaching device of a conduit system is provided. In yet other embodiments, a system including an inner lumen that is collapsible is provided. Means for closing a conduit system are also provided, including a plug for insertion through an attaching device and a variable radius coiled member associated with an attaching device.
Various other embodiments of the present invention include an outer lumen configured for extension and contraction, as well as universal motion absorption. Further embodiments include an outer lumen comprising a collapsible diaphragm. Still further embodiments comprise expandable delivery systems for endovascular and percutaneous applications.
The various embodiments of the present invention may thus be configured for implanting a conduit device that is adapted for providing a conduit for a medical procedure. Such procedures may include, but are not limited to: bypass; cardiac valve repair or replacement; attachment of a ventricular assist device; establishment of an apicoaortic conduit (AAC) and combinations of such procedures.
Use of this new conduit device, system, and method will significantly improve the ease and safety of conduit insertion (such as the implantation of AAC devices, for example). For example, various embodiments of the present invention may allow the outer tube to be securely operably engaged with the tissue wall (due at least in part to the cooperation of the attaching device and the ring) prior to the removal of a tissue core to define an aperture in the tissue wall. Thus, portions of the system disclosed herein may define a guide aperture extending axially through the outer tube for receiving a coring device that may be configured to be capable of efficiently removing and retrieving a tissue core while substantially simultaneously operably engaging a inner tube in the guide aperture so as to establish fluid communication between first and second opposing surfaces of the tissue wall. As persons of ordinary skill in the art will readily appreciate, the various embodiments of the present invention may also be used in a minimally invasive, endoscopically assisted approach.
Having thus described various embodiments of the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present inventions now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the inventions are shown. Indeed, these inventions may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout. The singular forms “a,” “an,” and “the” include plural referents unless the context clearly dictates otherwise.
Certain embodiments of the invention provide devices, methods and systems for using a conduit device through a tissue wall of a patient, comprising: an outer conduit lumen; an inner conduit lumen adapted for insertion at least partially through the outer lumen; an attaching device in communication with a distal end of one of the outer lumen or the inner lumen, wherein the attaching device is adapted for securing to or inserting at least partially through a tissue wall, and a flow control mechanism configured to permit the passage of medical instruments therethrough. In certain embodiments, the outer lumen comprises one or more flow control mechanisms. In certain embodiments, the inner lumen comprises one or more flow control mechanisms.
The invention provides further embodiments, wherein the attaching device is adapted for releasably attaching to the outer lumen. In certain embodiments, a multiple access port device is provided in communication with at least one of the outer lumen or the inner lumen, wherein the multiple access port device includes a plurality of individual ports in fluid communication with the outer lumen or the inner lumen.
In certain embodiments, the invention provides a system for fluid sealed passage of a medical instrument through a conduit comprising: a medical instrument; a flow control diaphragm valve sized and shaped for receiving the medical instrument therethrough, comprising a first rigid conduit having proximal and distal ends, a flexible conduit attached in fluid communication at a distal end of the first rigid conduit, and a second rigid conduit attached in fluid communication at a distal end of the flexible conduit; wherein twisting rotation of the first rigid conduit relative to the second rigid conduit causes the flexible conduit to collapse inward and selectively move from an open configuration to a closed configuration forming a fluid-tight seal around the medical instrument when inserted therein or forming a fluid-tight closing when the medical instrument is not inserted therein. In certain embodiments, the valve further comprises a locking element to maintain the valve in the closed configuration. In certain embodiments, the system further comprises an insertion sheath connected to the flow control diaphragm valve.
In certain embodiments, the invention provides a system wherein the outer lumen comprises a selectively extendible section to lengthen or shorten the outer lumen. In certain embodiments, the outer lumen comprises telescopically extendible segments. In certain embodiments, the inner lumen is radially expandable in longitudinal cross-section. In certain embodiments, the inner lumen is collapsible and comprises an expanding member and a membrane over an outer surface of the expanding member. In certain embodiments, the inner lumen comprises a medical inserter sheath mounted on a dilator. In certain embodiments, the expandable member is expanded using at least one of: (a) mechanical force; (b) material modification; (c) structure modification; (d) electrical energy; or (e) thermal energy. In certain embodiments, the collapsible inner lumen comprises a flexible tip configured to allow selective sealing of the inner lumen.
The invention also provides a system for using a conduit device through a tissue wall of a patient, comprising: an outer lumen; an inner lumen adapted for insertion at least partially through the outer lumen; an attaching device in communication with a distal end of one of the outer lumen or the inner lumen, wherein the attaching device is adapted for securing to or inserting at least partially through a tissue wall, and in particular a cardiovascular apical cavity, wherein the outer lumen comprises a motion absorbing element to permit relative movement between the attaching device and the outer lumen. In certain embodiments, the motion absorbing element is a portion of the conduit configured as a flexible accordion segment or as two conduit segments connected by a universal ball joint.
In certain embodiments, the invention provides a system for using a conduit device through a tissue wall of a patient, particularly a cardiovascular apical cavity, comprising: an outer lumen; an inner lumen adapted for insertion at least partially through the outer lumen; an attaching device in communication with a distal end of one of the outer lumen or the inner lumen, wherein the attaching device is adapted for securing to or inserting at least partially through a tissue wall, wherein the inner lumen further comprises a steerable tip comprising a guiding tip movably mounted on a distal end of the inner lumen, wherein the tip can be guided by the user in at least two dimensions.
In certain embodiments, the guiding tip comprises a ring guide mounted on a curved deflector element, and wherein said curved deflector element is movable over a range between a proximal straightened position and a distal increasingly deflected position, such that movement to the distal deflected position causes a guide wire extending through the inner lumen and through the ring guide to be directed toward the deflected position. In using such a device, the operator can achieve two or three-dimensional steering by distally and proximally manipulating the deflector element, in combination with rotating the inner lumen and/or axially moving the inner lumen distally or proximally.
The present invention further provides a system for using a conduit device through a tissue wall of a patient, comprising: an outer lumen; an inner lumen adapted for insertion at least partially through the outer lumen; an attaching device in communication with a distal end of one of the outer lumen or the inner lumen, wherein the attaching device is adapted for securing to or inserting at least partially through a tissue wall, wherein the attaching device further comprises a plug adapted for insertion through the attaching device to substantially seal the attaching device and prevent fluid flow through the attaching device, wherein the plug further comprises an extended surface extending distally from the plug, wherein the extended surface is adapted for insertion through a puncture in the tissue wall.
In certain embodiments, the plug has a flexibly sealable distal tip for selective access to the tissue from within the inner lumen. In certain embodiments, the attaching device further comprises means for exerting an inward radial force against the tissue, wherein, when the attaching device is implanted, the inward radial force urges the tissue inward toward the extended surface of the plug. In certain embodiments, the means for exerting an inward radial force comprises at least one of: (a) a radially expanding coil; (b) a conical flange: (c) one or more arm or barb members. In certain embodiments, the plug further comprises radial threads that engage corresponding radial threads on the attaching device to seal the tissue wall.
In certain embodiments of the invention, the attaching device further comprises a variable radius coiled member adapted to exist in a relaxed state having a narrow section with an inner diameter less than other sections of the variable radius coiled member, wherein when changing from an expanded state to a relaxed state, the narrow section diameter decreases, and wherein, when the attaching device is implanted, decreasing the narrow section diameter urges the tissue in an inward radial direction. In certain embodiments, changing from the expanded state to the relaxed state results from removing a plug from the attaching device, wherein prior to removal the plug exerts an outward radial force on the narrow section expanding the diameter of the narrow section.
In certain embodiments, the invention provides a system for providing access to a cardiovascular apical cavity comprising an attaching device adapted for securing to or inserting at least partially through a cardiovascular apical tissue wall, and at least one suture disposed on the device, wherein upon release of the attaching device from the tissue wall, the at least one suture is utilized to facilitate closing of the tissue wall. In certain embodiments, the attaching device uses a helical path when attaching to the securing tissue In certain embodiments, the attaching device further comprises at least one pledget in communication with the at least one suture, wherein, during removal of the attaching device from the tissue wall, the at least one pledget and the at least one suture are utilized to facilitate closing of the tissue wall.
In certain embodiments, the invention provides a system for using a conduit device through a tissue wall of a cardiovascular apical cavity of a patient, comprising: an inner lumen adapted for at least partial insertion through the tissue wall of the patient and providing fluid communication therebetween, wherein the inner lumen is a collapsible inner lumen. In certain embodiments, the system comprises a flow control mechanism configured to permit the passage of medical instruments therethrough, and does not require the use of a haemostatic device. In certain embodiments, the collapsible inner lumen comprises an expanding member and a membrane over the outer surface of the expanding member. In certain embodiments, the collapsible inner lumen is adapted for insertion through a trans-cutaneous or endovascular access system when in a collapsed state. In certain embodiments, the collapsible inner lumen is adapted for receiving at least one medical instrument therethrough when in an expanded state.
In certain embodiments the invention provides a device for closing a conduit system, comprising: an attaching device adapted for securing to or inserting at least partially through a tissue wall, wherein the attaching device has a passage defined therethrough to allow fluid communication through the attaching device; and a plug adapted for insertion into the passage of the attaching device to substantially seal the attaching device and prevent fluid flow through the attaching device.
In certain embodiments, the invention provides systems and methods for delivering a medical instrument through a cardiovascular apical cavity tissue wall of a patient comprising: a) securing an attaching device to the cardiovascular apical cavity tissue wall, wherein the attaching device is adapted for securing a blood flow control mechanism configured to sealably permit the passage of medical instruments therethrough; b) puncturing the tissue wall; and c) dilating the punctured tissue for delivery of the medical instrument therethrough; wherein steps a) and b) may be performed in any order.
These and many other embodiments of the invention will be readily apparent to one of skill in the art in view of the present disclosure. Although some embodiments of the invention described herein are directed to a conduit device (see
It should be further understood that various embodiments of the conduit device described herein may also be utilized to establish fluid communication between opposing surfaces of a variety of tissue walls and/or anatomical structures. For example, in some embodiments, the conduit device and system for implanting described herein may be used to establish a conduit (and consequently fluid communication) between opposing surfaces of a wall of an anatomical structure that may include, but is not limited to: a urinary bladder; a gall bladder; a diaphragm; a thoracic cavity; an abdominal cavity; an intestinal structure; a cecal cavity; and other tissue wall structures.
It should be understood that the various conduit device components described herein (see, for example, the components shown generally throughout
As shown generally in
The attaching device 15 may comprise, in some embodiments, a helical static coil having a sharpened distal end adapted for piercing the tissue wall 850 as the outer tube 10 is rotated relative to the first surface 855 of the tissue wall 850. In other embodiments, the attaching device 15 may comprise a helical elastic spring having a sharpened end adapted for piercing the tissue wall 850 as the outer tube 10 is rotated relative to the first surface 855 of the tissue wall 850. In some embodiments, as shown in
In other embodiments, as shown generally in
As described herein, the system may further comprise a ring 30 operably engaged about an outer surface of the outer tube 10. As shown generally in
As shown generally in
In order to ensure that the ring 30 forms a substantially fluid-tight seal with the first surface 855 of the tissue wall 850 about the aperture defined therein, some embodiments (as shown in
As shown, for example, in
In some conduit device 1 embodiments, as shown generally in
In some embodiments, the seal testing aperture 36 may also serve an alternative function for rotationally securing the ring 30 relative to and the first surface 855 of the tissue wall 850. For example, a clinician may insert a needle and/or other elongate spike through the seal testing aperture 36 defined in the ring 30 and substantially into the tissue wall 850. The interaction of the needle and/or spike with the ring 30 (via the seal testing aperture 36) and the tissue wall 850 may thus reduce a chance that the ring 30 (and the helical attaching device 15 extending from the outer tube 10) are rotatable relative to the tissue wall 850 such that the ring 30 and the helical attaching device 15 may be less prone to “backing out” of the tissue wall 850 once the seal is established between the ring 30 and the first surface 855 of the tissue wall 850.
In some additional embodiments, as shown generally in
Referring to
It is appreciated that the conduit device embodiments described herein are only example conduit device configurations and that many other device configurations may be utilized with various system components described. For example, a conduit device may not necessarily require an attaching device, an inner tube, an outer tube, and/or a coring member, as described, but may simply include a tube body and an attaching device, or may be delivered utilizing other delivery instruments and/or other techniques. Thus, additional aspects of the system and device components may be utilized with any number of conduit device configurations, as generally described below.
Delivery Techniques
As shown generally in
As shown in
In some embodiments, wherein the attaching device comprises a conical and/or “radially-expanding” helix, the attaching device 15 may act to compress at least a portion of the tissue wall 850 radially inward and towards an outer surface of the inner tube 40 so as to establish a substantially fluid-tight seal between the outer surface of the inner tube 40 and the portion of the tissue wall 850 that has been urged radially inward by the conical and/or radially-expanding helix of the attaching device 15. Furthermore, in embodiments wherein the attaching device 15 comprises a conical and/or “radially-expanding” helix, the attaching device 15 may act to compress at least a portion of the tissue wall 850 radially inward such that the portion of the tissue wall 850 may be more readily received by ring 30 (which may comprise a frusto-conical structure configured for receiving the compressed portion of the tissue wall 850). As shown in
As shown in
As shown in
Referring again to
As described generally herein with regard to the various system embodiments of the present invention, the conduit device 1 installation process may advantageously allow a clinician to visually confirm that the tissue core 850a removed by the coring cylinder 65 has been completely and cleanly removed from the aperture defined in the tissue wall 850. For example, in some embodiments, at least a portion of the handle 63 may comprise a transparent material such that the tissue core 850a received within the tissue core chamber 62 may be directly visible by a clinician and/or an endoscopic imaging device from a position substantially outside the handle 63. As shown in
With reference to
Other flow control mechanisms may be utilized, such as, but not limited to, duck bill valves, globe valves, single or multiple leaflet valves, breast pump valves, diaphragm valves, and the like. For example, the delivery system with an inner lumen 100 is shown in
According to one embodiment, an additional diaphragm valve may be included at or near the proximal end of the delivery system 100.
In use, rotation of a first conduit 205 with respect the second conduit 210 causes the flexible conduit 215 to twist and collapse within itself, therefore reducing inner diameter of the passage therethrough. In one embodiment, complete closure of the passage may be achieved by increased turning of the conduits 205, 210 relative to each other. In another embodiment, if an instrument, lumen, or other medical instrument is inserted through the conduit, then the flexible conduit 215 may close onto the instrument, lumen, or other device and create a fluid seal therearound.
With reference to
With reference to
According to one embodiment shown in
As shown in
According to one embodiment shown in
In yet another embodiment, such as shown in
According to the embodiment such as shown in
According to another embodiment, the extendable body section may include multiple tubular members in threaded communication. For example, an outer tubular member may have threads formed on an inner surface and an inner tubular member may have complementary threads formed on an outer surface. Turning one of the outer or inner tubular member in a first direction with respect to the other tubular member will thus cause the extendable body section to expand in length and turning one of the outer or inner tubular member in a second direction opposite the first direction with respect to the other tubular member will thus cause the extendable body section to retract in length. In a further example, the extendable body can be constructed from an accordian-like corrugated or extendible tube that may change its axial length by changing the angular relations between the different segments of the tube.
It is appreciated that, according to various embodiments, the extendable body section 110 may only comprise a portion of the outer lumen 105, whereas another portion of the outer lumen 105 may have a fixed length or is not otherwise adjustable. Moreover, it is appreciated that other aspects of the delivery system 100 may likewise include adjustable members to adjust relative lengths, such as an inner lumen, conduit, or instrument insertable through the outer lumen 105.
At
At
In use, a guide wire is initially inserted into the ventricle, followed by a dilator 510 that carries the inner lumen 515. Thus, the dilator 510 includes an inner passage 505 that is adapted to pass over the guide wire. According to this embodiment, which may differ from various other embodiments, the inner lumen 515 can be delivered over the dilator 510 and inserted into the tissue wall prior to securing the attaching device 120 thereto. Upon positioning the inner lumen 515 through the tissue wall as desired, the outer lumen 520 carrying the attaching device 120 is advanced over the inner lumen 515 and secured to the tissue wall via the attaching device 120 (such as according to any means described herein or in the referenced patents or applications). According to one embodiment, a flow control mechanism, such as a collapsible diaphragm 135, as described with reference to
Blood or other fluid flow through the inner lumen 515 may be controlled by a flow control mechanism, such as a duck bill valve 525 (or other valve mechanism, as described herein) at or near the proximal end of the inner lumen 515. The duck bill valve 525, or other valve mechanism, may therefore allow selective delivery of instruments or other therapeutic means through the inner lumen 515, while still limiting fluid loss through the proximal end of the inner lumen 515. Upon completion of the procedure, the inner lumen 515 may be retrieved and either the attaching device 120 or the tissue wall may be closed. For example, a small coil or other device for urging the tissue in an inward radial direction may be utilized to seal the tissue wall or a plug, cap, or other closure device may be secured to the attaching device 120 if the attaching device is left implanted. After removal of the inner lumen 515, the collapsible diaphragm 135 (or other flow control mechanism) may be utilized to limit or prevent fluid flow proximally through the outer lumen 510. Thus, a coil or other closure device delivery instrument may be inserted through the outer lumen 510 while the collapsible diaphragm 135 still serves to limit blood or other fluid flow through the outer lumen 510 while sealing the tissue wall or cap. It is appreciated that the delivery system 100 illustrated and described with reference to
The multiple access port device 1400 may further include one or more flow control mechanisms, which may be in operable communication with one or more of the individual ports 1405a-1405n and/or with the converging portion of the device 1400. The flow control mechanisms may be any mechanism allowing selective flow through the respective passage, such as, but not limited to, clamp valves, duck bill valves, globe valves, single or multiple leaflet valves, breast pump valves, diaphragm valves, and the like. In addition, one or more de-airing orifices 1415, as are known, may be included with the multiple access port device 1400 to prevent introducing air into the patient's vasculature during use. In other embodiments, however, the de-airing orifice may be associated with the outer lumen 810 or another portion of the system. Although the multiple access port device 1400 is shown and described as being attached to the outer lumen, in other embodiments, a multiple access port device 1400 may be attached directly to the attaching device or attached to the inner lumen.
Moreover, a collapsible lumen may further facilitate sealing a tissue puncture when inserted therethrough and expanded to its expanding state by creating an outward radial force against the tissue walls. It is thus possible that, in embodiments using a collapsible/expandable inner lumen, an attaching device need not be a radially expanding coiled device or other device that urges tissue in an inward radial direction because the collapsible/expandable inner lumen creates the pressure by urging itself in an outward radial direction when in an expanded state. It is appreciated that, in some embodiments, an attaching device, an outer lumen, and/or any other aspects of the system may likewise be collapsible to allow delivery by trans-cutaneous access.
According to various embodiments, an attaching device may be closed and/or the tissue wall puncture may be substantially sealed to close the puncture, to prevent fluid flow therethrough, and/or to allow multiple subsequent accesses.
In the embodiment shown by
It is appreciated that, in other embodiments similar to that shown in
Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.
This application is continuation of U.S. application Ser. No. 13/982,642, which is a U.S. National Phase under 35 U.S.C § 371 of International Application PCT/US2012/023476, filed Feb. 1, 2012, which claims priority to U.S. Provisional Application No. 61/438,370, filed Feb. 1, 2011, and U.S. Provisional Application No. 61/438,415, filed Feb. 1, 2011, each of which is incorporated herein in its entirety by reference.
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Number | Date | Country | |
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20170042572 A1 | Feb 2017 | US |
Number | Date | Country | |
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61438370 | Feb 2011 | US | |
61438415 | Feb 2011 | US |
Number | Date | Country | |
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Parent | 13982642 | US | |
Child | 15074360 | US |