Abstract: A venturi pump can provide suction through a catheter during an intravascular treatment. The venturi pump can have a supply port, exhaust port, and vacuum inlet such that a fluidic flow from the supply port to the exhaust port produces suction at the vacuum inlet due to the Venturi effect. A device or assembly can include the venturi pump, a flow regulator, and a sealable entrance sized to receive the catheter. The flow regulator can be manipulated to adjust suction through the vacuum inlet of the venturi pump. The device or assembly can have an exit and a passageway between the entrance and the exit to allow a pull wire, Intermediate Catheter, or other clot retrieval system elongated member to pass therethrough and be manipulated during the intravascular treatment.

Abstract: Systems and methods for delivering a catheter to a location of interest in the vasculature, the method including selectively positioning a guidewire at the location, positioning a self-expanding sheath within a lumen of the catheter, advancing the catheter and the self-expanding sheath in tandem over the guidewire, and distally moving a distal end of the self-expanding sheath out from an inner lumen of the catheter thereby causing the self-expanding sheath to move from a collapsed state within the catheter to an expanded state outside the catheter.

Abstract: A braid for treating an aneurysm can include a first radially expandable segment operable to move from a collapsed state within a microcatheter to a deployed state distal of the microcatheter. The first radially expandable segment can be capable of radially expanding to form an outer occlusive sack in the aneurysm in the deployed state. The braid can also include a second radially expandable segment operable to move from the collapsed state within the microcatheter to the deployed state distal of the microcatheter, wherein the second radially expandable segment is capable of radially expanding inside the outer occlusive sack to form an inner occlusive sack in the outer occlusive sack in the deployed state. An expansion mechanism can be included and be disposed at a proximal end of the first and second radially expandable segments.

Abstract: An embolic implantation system configured to deliver an embolic implant intravascularly to a treatment site includes an elongated delivery tube to which the embolic implant is detachably attached by a flexible loop extending through a retaining ring or opening on the embolic implant and an elongated detachment member or pull wire extending through the delivery tube and flexible loop. The pull wire has a bump near its distal end that inhibits the pull wire from moving further distally when the bump presses distally against the flexible loop and/or retaining ring. The flexible loop and retaining ring thereby serve as a distal obstruction obstructing distal movement of the bump and thereby distal movement of the pull wire into the implant.

Abstract: A device for capturing an obstruction in a vasculature can include a first elongated member, an expandable element, an invertible element, and a gap positioned between the expandable element and the invertible element sized to be placed across the obstruction. The expandable element and the invertible element can be positioned near the distal end of the first elongated member. The expandable element can expand from a collapsed delivery configuration to an expanded configuration. The invertible element can expand from a collapsed delivery configuration to an expanded configuration, and the invertible element can invert from the expanded configuration to an inverted configuration, thereby forming a pocket. The pocket can envelope at least a portion of the gap and can thereby capture an obstruction that is in the gap.

Abstract: A method of constructing a detachment system for delivering an implantable medical device to a target location of a body vessel is presented. The method includes forming a compressible portion on a distal tube, engaging an implantable medical device with an engagement system, extending the engagement system through the distal tube such that the implantable medical device is distal of a distal end of the distal tube, applying a force to the engagement system to compress the compressible portion to a compressed state, fixing the engagement system to the distal tube to maintain the compressed state of the compressible portion, and joining a proximal end of the distal tube to a distal end of a proximal tube. The engagement system can include a loop wire that is fixed to the distal tube and engages the medical device.

Abstract: A method for implanting a stent by providing an implantation system including a catheter, an expandable element, and a delivery wire, moving a first portion of the expandable element to exit the catheter, and maintaining a second portion of the expandable element within the catheter to establish a partially implanted configuration. Then moving the delivery wire independent of the expandable element in the partially implanted configuration, and enlarging a circumference of the expandable element in response to the moving the delivery wire.

Abstract: An aneurysm intrasaccular implant is provided having one or more coated regions. The implant includes a braided mesh movable from a delivery configuration having a single-layer tubular shape sized to traverse a catheter to an implanted configuration sized to be implanted in an aneurysm sac. The braided mesh can include an anti-thrombogenic coating defining a first section along the length of the braided mesh. The braided mesh can include a cell adhesion coating defining a second section along the length of the braided mesh. In the delivery confirmation, the first section can be positioned distal to the second section within the catheter. The second section is invertible to the implanted configuration such that the second section is positioned within the aneurysm sac and the first section is positioned to occlude an aneurysm neck.

Abstract: A delivery member is provided for delivering and deploying an intravascular medical device. The delivery member includes a flexible distal portion including a wound wire coil surrounded by a flexible sleeve and inhibited from extending lengthwise by a stretch resistant member positioned through the lumen of the coil. The delivery member can include hypotubes positioned on either side (distally and proximally) from the wound wire coil to which the stretch resistant member and the wound wire coil can be attached.

Abstract: A vascular flow diverter includes a tubular mesh framework which includes a mesh cover and an opening. The tubular mesh framework is collapsible and configured to expand from a collapsed shape to a tubular shape when the vascular flow diverter is deployed. The mesh cover conforms to the shape of the tubular mesh, is surrounded by the tubular mesh framework, and is less porous than the tubular mesh framework. The opening is located within the mesh cover. A delivery wire passes through the opening in order to guide the flow diverter into place over an aneurysm.

Abstract: A method is disclosed, including joining a balloon to a resilient inner body of a balloon assist device, the balloon comprising an axial length shorter than an axial length of the inner body; expanding a slit in the resilient inner body of the balloon assist device; inserting a catheter through the slit; and releasing the slit to contract the balloon assist device around the catheter.

Abstract: An assembly at a proximal end of an intravascular delivery system can allow the proximal end of a pull wire to move independently of a delivery tube. The assembly can generally include the pull wire, the delivery tube, a feature to prevent the proximal end of the pull wire from becoming inaccessible due to distal movement of the pull wire, and a feature to protect the proximal end of the pull wire from inadvertent, premature manipulation. When the intravascular delivery system is navigating tortuous vasculature, the proximal end of the pull wire can move distally in relation to the proximal end of delivery tube, relieving stress on the distal end of the pull wire. The proximal end of the pull wire can be protected from inadvertent manipulation during delivery and made available for manipulation once the distal end of the delivery system is in place.

Abstract: A braid for treating an aneurysm can include a first radially expandable segment operable to move from a collapsed state within a microcatheter to a deployed state distal of the microcatheter. The first radially expandable segment can be capable of radially expanding to form an outer occlusive sack in the aneurysm in the deployed state. The braid can also include a second radially expandable segment operable to move from the collapsed state within the microcatheter to the deployed state distal of the microcatheter, wherein the second radially expandable segment is capable of radially expanding inside the outer occlusive sack to form an inner occlusive sack in the outer occlusive sack in the deployed state. An expansion mechanism can be included and be disposed at a proximal end of the first and second radially expandable segments.

Abstract: An intravascular treatment device is presented having an expandable frame made up of circular struts, straight struts, and bent struts forming a frame with circumference that varies over the length of the frame. Radiopaque markers can be positioned on the bent struts to indicate outer circumferences of the frame along the length of the frame. The device can be a stent or a clot retriever. If the device is a clot retriever, the proximal end of the expandable frame can be attached to a guide wire and the distal end of the expandable frame can be free to slide over the guide wire when the frame moves from a collapsed state to an expanded state and vice versa.

Abstract: The present disclosure relates to a method of occluding an aneurysm, including expanding, in an aneurysm, a first radially expandable mesh segment of an expandable braid by distally moving the braid from a collapsed state within a microcatheter to a deployed state distal of the microcatheter within the aneurysm, the first radially expandable mesh segment comprising a proximal end and an open distal end, wherein in the deployed state the first radially expandable mesh segment comprises an outer occlusive sack in the aneurysm that is sealable against a neck of the aneurysm; and further distally pushing the braid, as the outer occlusive sack is forming, thereby expanding a second radially expandable mesh segment inside of the outer occlusive sack to form an inner occlusive sack in the outer occlusive sack in the deployed state.

Abstract: The present disclosure relates to a self-expanding braided implant, including a distal implant end and a proximal implant end, the braided implant being invertible about the distal implant end. Translation of the braided implant distally causes the braided implant to invert and fold into itself thereby forming an occlusive sack configured to occlude the aneurysm.

Abstract: The present disclosure relates to a self-expanding braid for treating an aneurysm. The braid can include a lumen with a proximal end opposite a distal end. Translating the braid can cause a distal segment of the braid to expand and form an outer occlusive sack while a segment proximal the distal segment can invert into the outer occlusive sack like a tube sock. The braid can then be detached from its delivery system.

Abstract: A detachment system for delivering an implantable medical device to a target location of a body vessel has a generally hollow distal tube. The distal tube includes a proximal end, a distal end, and a compressible portion of the tube itself, between the proximal and distal ends which is axially movable from a compressed to an elongated condition. A generally hollow proximal tube has a proximal end and a distal end. A coupling joins the proximal and distal tubes. An engagement system engages and deploys the implantable medical device engaged at the distal end of the distal tube. The engagement system moves the compressible portion to the compressed condition when engaging the implantable medical device, and deploys the implantable medical device and releases the compressible portion to the elongated condition.

Abstract: A detachment system for delivering an implantable medical device to a target location of a body vessel has a generally hollow distal tube. The distal tube includes a proximal end, a distal end, and a compressible portion of the tube itself, between the proximal and distal ends which is axially movable from a compressed to an elongated condition. A generally hollow proximal tube has a proximal end and a distal end. An engagement system engages and deploys the implantable medical device engaged at the distal end of the distal tube. The engagement system moves the compressible portion to the compressed condition when engaging the implantable medical device, and deploys the implantable medical device and releases the compressible portion to the elongated condition.

Abstract: An embolic device deployment system having a lumen with proximal and distal ends. An embolic device having a proximal retaining ring and an expandable member having a contracted and expanded state, with two apertures. The expandable member is disposed in the lumen in the expanded state. An engagement member has a distal loop extending through the retaining ring and a proximal loop extending into the lumen. The detachment member slides within the lumen and another of the apertures and is disposed through the loops. It comprises a bump on the detachment member between the loops. When the detachment member is in the distal loop and the distal loop is disposed within the retaining ring, the embolic device is in an engaged position. Pulling the detachment member withdraws it from the distal loop. The bump contacts the proximal loop to assist in the disengagement of the distal loop from the retaining ring to release the embolic device.