Abstract: An implant having an implant body, a gripper, an elastic pouch, and an elongate member. The pouch can be coupled to the gripper, can have a first part and a second part, can have a contracted state toward which the pouch is elastically biased, and can be reversibly stretchable into a stretched state. The elongate member can have a first end portion coupled to the implant body, a second end portion fastened to the second part of the pouch, and a mid-portion extending (i) from the second end portion, through the pouch to the first part of the pouch, and (ii) out of the pouch to the first end portion. In at least one state of the gripper, the mid-portion can be slidable through the gripper and into the pouch. Other embodiments are also described.

Abstract: A delivery system for delivering a prosthesis includes a sheath, a slide shaft having a threaded outer surface, and a handle. The handle includes an internal spring assembly for selectively engaging and disengaging the handle with the threaded outer surface of the slide shaft. The internal spring assembly includes at least one spring arm, a head coupled to the spring arm and having a circumferentially rounded threaded inner surface, and a ring slidably disposed over the spring arm. When the ring is in a first longitudinal position, the threaded inner surface of the head is spaced apart from the threaded outer surface of the slide shaft. When the ring is in a second longitudinal position, the threaded inner surface of the head is threadedly engaged with the threaded outer surface of the slide shaft. The handle may include a resilient cover to provide the internal spring assembly with a biased or nominal operational position.

Abstract: A delivery device for a collapsible prosthetic heart valve may include an operating handle having a housing and a carriage movable relative to the housing, and a catheter assembly. The catheter assembly may have an inner shaft around which a compartment is defined, an outer shaft surrounding at least a portion of the inner shaft, a distal sheath fixedly connected to the outer shaft, and a spline tube surrounding at least a portion of the inner shaft. The spline tube may have thinner portions having a first maximum thickness in a radial direction of the inner shaft and thicker portions having a second maximum thickness in the radial direction that is greater than the first maximum thickness. The spline tube and the outer shaft may together define one or more channels that provide liquid communication between the operating handle and the compartment.

Abstract: Methods for delivering a prosthetic valve comprise introducing the prosthetic heart valve into a body of a patient. The prosthetic valve is mounted within a delivery sheath of a delivery apparatus in a radially compressed state. The prosthetic valve is advanced through the body to a delivery location. A motor is actuated to cause the delivery sheath to retract to expose the prosthetic valve and the prosthetic valve expands to a radially expanded state at the delivery location. The methods can also include releasing the prosthetic valve from the delivery apparatus and removing the delivery apparatus from the patient.

Abstract: A prosthesis secures a replacement valve in a heart. The prosthesis includes a radially expandable inflow section and outflow section, and migration blocker rods. The inflow section has a tapered shape and is implanted within an atrium of a heart adjacent a native valve annulus. The outflow section couples to the inflow section, and is configured to be implanted through the native valve annulus and at least partially within a ventricle of the heart. The migration blocker rods extend circumferentially around at least a portion of the outflow section and hold native leaflets of the heart valve. In a contracted configuration, the prosthesis may be implanted through a catheter into the heart. In an expanded configuration, the tapered shape of the inflow section in the atrium cooperates with the migration blockers in the ventricle to hold the prosthesis against the native valve annulus.

Abstract: A stent attachment and deployment mechanism is utilized to prevent the distal end of an endoprosthesis comprising fixation barbs or other fixation mechanism from deploying prior to the remaining sections of the fixation device. With this stent attachment and deployment mechanism accurate deployment may be achieved.

Abstract: A delivery device used for delivering a heart valve, a blood vessel stent, and the like. The device includes a first stopper and a connecting unit. The connecting unit is provided opposite to the first stopper and can move relative to the first stopper. The connecting unit includes an axial connecting portion and at least two axial shafts. The axial shaft is connected to the connecting portion and faces the first stopper. The connecting unit is used to form, together with the first stopper, an enclosed and locked space.

Abstract: Implantable medical devices for connecting tissue layers or occluding body conduits and tissue structures include apposition portions, a central region, and a covering material. The methods of using the devices include endoscopic deployment, and the devices may include self-expanding frameworks that facilitate a secure connection between the tissue structures. In some embodiments, one or more tethers are used to longitudinally contract the device in situ.

Abstract: A system may include an endoluminal prosthesis and a guide wire. The prosthesis may include a tubular body including a graft material wall, a proximal end opening, a distal end opening, and a lumen extending longitudinally therein. The prosthesis may include first and second fenestrations in the graft material wall. The first and second fenestrations may be spaced from one another circumferentially about the tubular body. The guide wire may have a first end and a second end both extending from a region proximal of the proximal end opening. The guide wire may enter the proximal end opening, exit the first fenestration, partially traverse an exterior surface of the prosthesis, enter the second fenestration, and exit the proximal end opening. One or more of the fenestrations may include a branch.

Abstract: A delivery system (200) for delivering a lumen stent (100).

Abstract: Described here are devices, systems, and methods for closing the left atrial appendage. The methods described here utilize a closure device for closing the left atrial appendage and guides or expandable elements with ablation or abrading elements to ablate or abrade the left atrial appendage. In general, these methods include positioning a balloon at least partially within the atrial appendage, positioning a closure assembly of a closure device around an exterior of the atrial appendage, inflating the balloon, partially closing the closure assembly, ablating the interior tissue of the atrial appendage with the inflated balloon, removing the balloon from the atrial appendage, and closing the atrial appendage with the closure assembly.

Abstract: An intravascular device for treating atherosclerotic occlusive disease can include an annular band defining a longitudinal axis between proximal and distal ends. The annular band can have a plurality of barbs on its outer periphery. One or more intravascular devices may be applied in positions along a plaque accumulation site as needed to stabilize the site and/or hold pieces of plaque out of the way of blood flow. The barbs may be pressed into the plaque and/or blood vessel walls.

Abstract: A prosthetic heart valve includes a frame, a valve member, and a sealing member. The frame is expandable from a collapsed state to an expanded state. The frame has inflow and outflow ends, a lumen extending between the ends, and a plurality of struts defining a plurality of cells. The valve member is disposed within the lumen of the frame and is movable between open and closed configurations. The sealing member is mounted inside of the frame. When the frame is in the expanded state and the valve member is in the closed configuration, portions of the sealing member can protrude outwardly through the cells of the frame and extend beyond an exterior surface of the struts of the frame.

Abstract: Disclosed is an implanted device, comprising a device base body and an active drug, wherein the device base body is pure zinc and/or a zinc alloy, the zinc content in the device base body is 0.1-100%, and the active drug comprises anti-allergic drugs. After the implantation of the implanted device into the human body, the surrounding tissues of the implant would not have a clear hypersensitive reaction due to the presence of the anti-allergic drugs, and the implanted device can be used to be implanted into the body for supporting organ chambers, to fill the hollow chambers of the organs and tissues or as orthopaedic implants etc.

Abstract: Valve delivery catheter assemblies including components that limit trauma to the expanded prosthetic valve and body channels as the distal tip of the catheter is withdrawn through the expanded valve and thereafter from the body. Catheter assemblies according to the present invention can include a handle assembly, an introducer sheath, and a distal tip assembly. The handle assembly can include a fixed main handle and two or more rotating handles that allow a user to control the distal tip assembly of the catheter. A safety button can be included on the handle assembly to allow for precise and consistent positioning of the prosthetic valve in the body. A valve retaining mechanism can be included to assist in retaining the prosthetic valve prior to deployment.

Abstract: A method of fabricating packaged electronic components with improved yield and at lower unit cost; the method comprising the steps of obtaining an active membrane layer on a carrier substrate, depositing a front electrode onto a front of the active membrane layer, obtaining an inner front section including at least a silicon handle or wafer, attaching an inner front end section to an outer surface of the front electrode, detaching the carrier substrate from a back surface of an active membrane on the opposite surface from the front surface on which the front electrode is deposited, patterning the active membrane layer into an array of at least one island of membrane, selectively removing the front electrode and bonding layer, selectively applying an inner passivation layer, and selectively depositing a back electrode layer on the thus exposed back surface of the active membrane.

Abstract: According to one aspect of the present disclosure, a method and technique for manufacturing a stent are disclosed. The stent is a non-metallic stent having a furled small-diameter state and an expanded large-diameter state where the stent, in the furled small-diameter state, includes a plurality of central lobes arranged at spaced-apart intervals and extending longitudinally defining a stent axis, the plurality of central lobes defining a cylindrical plane of the stent. The stent also includes at least one peripheral lobe formed on at least one of the plurality of central lobes, the peripheral lobe oriented along the cylindrical plane.

Abstract: The invention relates to deployable magnetic compression devices and systems and methods for the deployment of such magnetic compression devices. The magnetic compression devices are particularly useful for creating anastomoses, e.g., in the gastrointestinal tract. The devices are especially useful for minimally-invasive delivery, e.g., using endoscopic techniques. The systems, devices, and methods can be used to treat a variety of gastrointestinal and metabolic diseases, such as diabetes, obesity, and cancer.

Abstract: A stent includes a cylindrical main body portion, a linkage portion, and a marker attachment portion. The main body portion extends in an axial direction. The linkage portion extends from an end of the main body portion in the axial direction. The marker attachment portion is linked to the main body portion through the linkage portion. The linkage portion includes a bent portion tilting the marker attachment portion outward in a radial direction of the main body portion.

Abstract: A method of treating a diseased native valve includes advancing a replacement heart valve to native valve annulus. The heart valve includes an expandable frame and a valve body. The frame is formed with a plurality of cells and the valve body is formed with a plurality of leaflets configured to allow blood flow in a first direction. The frame is expanded from a radially compacted configuration to an expanded configuration at the native valve annulus. The replacement heart valve also includes one or more openings covered by one or more flaps and blood is allowed to flow through the openings in the first direction.

Abstract: The present invention is directed to an intraluminal guiding device having an expandable guiding member so as to facilitate and overcome the difficulties associated with obtaining contra-lateral leg access of a bifurcated stent or a bifurcated stent graft with a second guidewire and a method for treating abdominal aortic aneurysms with such a device. The guiding device comprises a pre-loaded second wire positioned within the contra-lateral leg which facilitates access to said leg in accordance with the present invention.

Abstract: The present embodiments provide an endoluminal prosthesis deployment system and method for deploying the prosthesis for cannulation of branch vessels. The prosthesis includes an anterior fenestration and a posterior opening. A guide is disposed to exit the prosthesis lumen through a lateral fenestration, enter through the anterior fenestration, and exit the prosthesis lumen through the posterior opening. A sheath can be preloaded over the branch wire at the lateral fenestration for vessel cannulation, such as in renal arteries. The sheath can include another branch wire that extends from the lateral fenestration to another lateral fenestration. An end of the guide is retracted after partial expansion of the prosthesis, and another sheath is inserted over the retracted guide and moved through the posterior opening and to the anterior fenestration. A separate branch guide wire is then directed through the sheath for vessel cannulation, such as the SMA.

Abstract: Medical devices and delivery systems for delivering medical devices to a target location within a subject. In some embodiments the medical devices can be locked in a fully deployed and locked configuration. In some embodiments the delivery systems are configured with a single actuator to control the movement of multiple components of the delivery system. In some embodiments the actuator controls the independent and dependent movement of multiple components of the delivery system.

Abstract: The present disclosure relates to delivery devices for transcatheter stented prosthesis loading, delivery and implantation. The delivery devices provide a loaded delivery state in which the stented prosthesis is loaded and compressed over the delivery device. The compression of the stented prosthesis can be adjusted with one or more elongate tension members, which extend around the stented prosthesis and proximately to an actuation and release assembly that can be provided as part of a handle assembly. The delivery device can be manipulated to adjust tension in the tension members to permit the stented prosthesis to compress, self-expand, and ultimately release from the shaft assembly. In some embodiments, the tension in one or more tension members is adjusted with one or more actuation and release assemblies.

Abstract: Delivery devices for a stented prosthetic heart valve. The delivery device includes a spindle, at least one cord, and a lateral control feature. The cord is tensioned to crimp the prosthesis to a compressed condition for delivery to a target site. Tension is lessened to allow the prosthesis to self-expand. In a tethered and expanded state in which the prosthesis has self-expanded and is connected to the spindle by the cord, the lateral control feature directs the spindle to a prescribed location relative to the prosthesis appropriate for a functional evaluation of the prosthesis. In some embodiments, the spindle is directed to a center of the prosthesis; in other embodiments, the spindle is held at a commissure of the prosthesis. The lateral control features of the present disclosure assume numerous forms.

Abstract: Delivery devices for a stented prosthetic heart valve. The delivery device includes a spindle, at least one cord, and a covering feature associated with the spindle for selectively covering at least a portion of a stented prosthetic heart valve tethered to the spindle in a delivery state. In some embodiments, the covering feature includes a tip mounted to the spindle. The tip can include an overhang region for selectively covering a portion of the stented prosthetic heart valve. In other embodiments, the tip can include a tip body and a compressible foam bumper. In yet other embodiments, the covering feature includes an outer sheath arranged to selectively cover the stented prosthetic heart valve. The outer sheath can be elastic and stretchable for recapturing a partially expanded prosthesis, for example by including one or more windows covered by a stretchable covering layer.

Abstract: A method, device, or system for treating eye disorders or conditions, comprising restoring or increasing blood flow or blood flow rate in an artery that supplies blood to or in the eye, thereby increasing the amount of oxygen that reaches the eye or a portion thereof.

Abstract: A medical device for temporary deployment into a bodily lumen is provided. The medical device comprises: a guide wire cannula having a proximal end and a distal end; a tip attached to the proximal end of the guide wire cannula; a pusher having a proximal and a distal end, the pusher having a through-bore disposed around the guide wire cannula; and a temporary stent assembly having a proximal end attached to the tip and a distal end adjacent to the proximal end of the pusher. The temporary stent assembly comprises a covered portion. The covered portion has a proximal sealing zone, a distal sealing zone and a recess between the proximal and distal sealing zones.

Abstract: Devices for palliating gastrointestinal strictures using rapid exchange type enteral stent placement catheters. The catheter may include an inner member and an outer member, with the two members being slidable with respect to one another. In various device embodiments, a ramp for directing a guidewire out from within the catheter is provided using portions of the outer member or a shaped mandrel. The inner member may take a number of forms, including a tubular distal portion, a skived or integrally attached elongate midsection, and a proximal portion. A mandrel can be used in a portion proximal of the guidewire ramp, with the mandrel taking one of several disclosed forms.

Abstract: Described are methods and systems for transcervical access of the cerebral arterial vasculature and treatment of cerebral occlusions, including ischemic stroke. The methods and devices may include methods and devices which may provide aspiration and passive flow reversal, those which protect the cerebral penumbra during the procedure to minimize injury to brain, as well as distal catheters and devices to remove an occlusion. The methods and devices that provide passive flow reversal may also offer to the user a degree of flow control. Devices and methods which provide a way to securely close the access site in the carotid artery to avoid the potentially devastating consequences of a transcervical hematoma are also described.

Abstract: A stent delivery device includes a shaft with an internal lumen and a balloon connected to the shaft. The stent delivery device includes a cover configured to advance or retract in the axial direction of the shaft between a covering position where the cover covers the deflated balloon and a retracted position where the cover is spaced apart from the balloon. The stent delivery device includes a drive unit configured to apply a driving force for advancing or retracting the cover. The lumen of the shaft is configured to allow a working fluid to flow through the lumen to inflate the balloon. The balloon and drive unit are operated by the injecting and discharging of the working fluid. The inflation and deflation of the balloon and the advancing and retracting of the cover are performed in conjunction with each other.

Abstract: A device (100) for repairing an aneurysm by deployment within the aneurism comprises a graft tube, at least part thereof having an inflatable wall (102, 104) whereby the tube can be deployed in an artery and be inflated to grip at least part of the arterial wall.

Abstract: A stent with a common connection interface, and a method and platform used to create a stent with a common connection interface is described. A common connection interface used to connect a stent to a pusher is described.

Abstract: In some examples, a splittable sheath includes a sheath body defining a lumen configured to receive an expandable balloon of a catheter, and a tab extending from a proximal end or a distal end of the sheath body. The tab includes a major surface having an outer edge defining a serpentine shape. Outward movement of the tab relative to a central longitudinal axis of the sheath body causes splitting of the sheath body.

Abstract: An intermixed particulate bioresorbable material including cathodic particles and anodic particles bound to each other, wherein the anodic and cathodic particles are made respectively of an anodic and a cathodic material, the anodic and cathodic materials forming a galvanic couple. The anodic and cathodic particles are present in a predetermined ratio and the anodic particles, cathodic particles and predetermined ratio are such that bioresorption of the bioresorbable material is promoted by galvanic corrosion between the anodic and cathodic materials. Also, a medical device, manufactured using the bioresorbable material and a method of manufacturing the bioresorbable material and the medical device.

Abstract: A medical lumen-expansion balloon may include a generally cylindrical central body between first and second body end portions, a low-profile unexpanded first state and a radially-expanded second state, wherein the first body end portion is constrained by fiber material such that it will not expand longitudinally and circumferentially beyond a predetermined size, and the central body is constrained by fiber material so as to be circumferentially substantially noncompliant, but is longitudinally compliant, such that it will elongate with increased volume but will not substantially radially expand.

Abstract: A prosthesis can comprise an expandable frame, a plurality of distal anchors and a plurality of proximal anchors. The anchors can extend outwardly from the frame. The frame can be configured to radially expand and contract for deployment within a body cavity. The frame and anchors can have one of many different shapes and configurations. For example, when the frame is in an expanded configuration, the proximal anchors can extend a significant distance away from the exterior of the frame, such as a length equal to or greater than about one half the diameter of the frame. As another example, the anchors can have looped ends.

Abstract: A delivery sheath includes an outer tubular layer and an initially folded inner tubular layer. When an implant passes therethrough, the outer tubular layer expands and the inner tubular layer unfolds into an expanded lumen diameter. The sheath may also include selectively placed longitudinal support rods that mediate friction between the inner and outer tubular layers to facilitate easy expansion, thereby reducing the push force needed to advance the implant through the sheath's lumen.

Abstract: A deployment system for a self expanding stent includes a catheter assembly with a tip attached to a distal end segment of an elongate tube. The tip includes a proximal portion molecularly joined to a distal portion, which has a lower durometer hardness than the proximal portion. The proximal portion includes an anchor surface in contact with the distal portion, and oriented perpendicular to a central axis of the elongate tube. The elongate tube may be formed from a thermosetting polyimide, and the overmolded tip may be made from two different colored and different hardnesses of polyether block amide material. The tip is overmolded onto an untreated external surface of the elongate tube.

Abstract: Systems and methods of adjusting the diameter of an endoluminal prosthesis that allows for controlled radial deployment of the endoluminal prosthesis and the ability to revise the positioning of the endoluminal prosthesis after unsheathing. The endoluminal prosthesis includes a stent graft having a tubular graft wall, a stent, a main strand, a proximal strand, and a distal strand.

Abstract: A method and process for at least partially forming a medical device. The present invention is generally directed to a medical device that is at least partially made of a novel alloy having improved properties as compared to past medical devices. The novel alloy used to at least partially form the medical device improves one or more properties (e.g., strength, durability, hardness, biostability, bendability, coefficient of friction, radial strength, flexibility, tensile strength, tensile elongation, longitudinal lengthening, stress-strain properties, improved recoil properties, radiopacity, heat sensitivity, biocompatibility, improved fatigue life, crack resistance, crack propagation resistance, etc.) of such medical device.

Abstract: A prosthetic assembly configured for endovascular placement within an aortic arch and method of use thereof. The prosthetic assembly includes a proximal aortic stent-graft prosthesis configured to be positioned within a proximal portion of the aortic arch adjacent to the brachiocephalic artery, a distal aortic stent-graft prosthesis configured to be positioned within a distal portion of the aortic arch adjacent to the left subclavian artery, a first branch stent-graft prosthesis configured to be positioned within the brachiocephalic artery and a second branch stent-graft prosthesis configured to be positioned in one of the left common carotid and the left subclavian artery. When deployed, a proximal end of the first branch stent-graft prosthesis is disposed within a lumen of the proximal aortic stent-graft prosthesis to proximally displace the ostium of the brachiocephalic artery.

Abstract: Methods and devices are disclosed for passing Chronic Total Occlusion (CTO) from subintimal location and re-entry into a true-lumen of the patient using transient fenestration approach. The transient fenestration is induced by balloon dilatation within the CTO, and a guidewire quickly trails into a true lumen.

Abstract: Apparatus and methods are described herein for use in the delivery and deployment of a prosthetic mitral valve into a heart. In some embodiments, an apparatus includes a catheter assembly, a valve holding tube and a handle assembly. The valve holding tube is releasably couplable to a proximal end portion of the catheter assembly and to a distal end portion of the handle assembly. The handle assembly includes a housing and a delivery rod. The delivery rod is configured to be actuated to move distally relative to the housing to move a prosthetic heart valve disposed within the valve holding tube out of the valve holding tube and distally within a lumen of the elongate sheath of the catheter assembly. The catheter assembly is configured to be actuated to move proximally relative to the housing such that the prosthetic valve is disposed outside of the lumen of the elongate sheath.

Abstract: A delivery catheter includes an inner shaft having an atraumatic distal catheter tip. The inner shaft is configured to carry the implant thereon. The catheter tip includes a region that is fixed to the inner shaft and a region that is deformable and not fixed to the inner shaft. An outer shaft surrounds the inner shaft and is displaceable relative thereto. An implant capsule at a distal end of the outer shaft is configured to encase the implant and to release the implant at the target site via relative displacement of the inner and outer shafts. A plunger is axially displaceable with respect to the catheter tip in response to movement of the outer shaft to apply axial compressive force to the catheter tip and deform the region that is deformable and expand that region radially.

Abstract: A device for closing the left atrial appendage. The device has a flexible and elongate pulling element fixed to a flexible material layer connected fixed to a self-expanding stent. The closure implant can be drawn back into the lumen of a catheter by the pulling element, and in so doing the stent framework can be transferred into a compressed state. The device enables a monitored and controllable release of the closure implant.

Abstract: Systems and methods for screening a subject for a therapy are described. A mechanical stimulation device positioned near at target location of a blood vessel to provide a mechanical stimulus to the blood vessel. The mechanical stimulus increases strain in one or more regions of the blood vessel, such as by modifying the cross-sectional geometry and/or area of the blood vessel to have different regions of different curvature A baroreflex or related physiological response in response to the mechanical stimulation is detected. In response to the detected response, it is determined whether the subject is appropriate for the therapy and/or which of a plurality of implants with different geometries and/or cross-sectional areas is most optimally suited for deployment in the subject.

Abstract: Various aspects of the present disclosure are directed toward prosthesis that may include a first graft component and a second graft component coupled to the first graft component. The prosthesis may also include a gap or a space between the first graft component and the second graft component.

Abstract: Delivery systems with telescoping capsules for delivering prosthetic heart valve devices and associated methods are disclosed herein. A delivery system configured in accordance with embodiments of the present technology can include, for example, a delivery capsule having a first housing, a second housing slidably disposed within a portion of the first housing, and a prosthetic device constrained within the first and second housings. The delivery capsule can further include first and second chamber defined in part by the first and second housings. During deployment, fluid is delivered to the first chamber to move the first housing distally over the second housing, thereby releasing a portion of the prosthetic device. Subsequently, fluid is delivered to the second chamber such that the first and second housings move together in the distal direction to release a second portion of the prosthetic device.

Abstract: A delivery device for a collapsible medical device may include a handle and a delivery assembly having a compartment for receiving the medical device. A catheter member may extend from the handle to the delivery assembly. The catheter member may have a first portion with a first compliance value and a second portion with a second compliance value different from the first compliance value. An internally threaded member may be fixedly connected to the delivery assembly. An externally threaded member may have a first portion operatively connected to the actuation member and a second portion threadedly coupled to the internally threaded member so that manipulation of the actuation member causes axial movement of the compartment relative to the catheter member.