Methods and devices are configured for neurointerventional procedures. The methods and devices enable safe and rapid access to the cerebral or intracranial arteries for the introduction of interventional devices such as to treat stroke and/or other disease conditions. The methods and devices include a vascular access and retrograde flow system that can be used safely and rapidly in the neurointerventional procedures.

A hemostasis device configured to apply a compressive force to a puncture site of a patient's vessel, such as an artery of the foot, is disclosed. The hemostasis device may include a compression member having a plurality of tabs and an inflatable bladder. A plurality of bands may be used to position and maintain the compression member over the puncture site until hemostasis is achieved are releasably coupled to the plurality of tabs. A first band can wrap around the ankle, a second band can wrap around the foot, and a third band can extend between two toes or around a toe. The hemostasis device may also comprise an inflation port in fluid communication with the inflatable bladder.

An implantable closure device for sealing an opening, such as a puncture, through a biologic tissue membrane, such as the meninges, against leakage of biological fluid. The closure device includes a fluid sealing plug configured to be positioned at least partially within the opening through the biologic tissue membrane. A retainer is configured to secure the fluid sealing plug at least partially within the opening. The retainer includes a proximal retainer portion configured to be disposed proximally on the biologic tissue membrane, a distal retainer portion configured to be disposed distally on the biologic tissue membrane, and a central retainer portion connecting the proximal retainer portion and the distal retainer portion. The central retainer portion is configured to extend through the opening. The fluid sealing plug is coupled to the central retainer portion.

An introducer sheath is disclosed configured to be percutaneously inserted into a biological lumen and can shorten the time required for hemostasis at a wound site and lessen the physical burden on the patient after withdrawal of the introducer sheath. The introducer sheath includes a catheter body to be percutaneously introduced into a biological lumen, a hub configured to be connected to the proximal side of the catheter body, and a drug part that has a hemostatic agent capable of treating a wound site in biological tissue. The drug part is disposed at the proximal side of an outer surface of the catheter body.

Vascular closure devices and methods for closing a blood vessel puncture site disposed at a distal end of a tissue tract are described. A combination of the body's own natural mechanism with chemical and/or biological agents is relied upon to accelerate the hemostatic process. Included are steps of introducing a closure device through the tissue tract and deploying an expansible member at a distal end of the device within the blood vessel to occlude the puncture site. A sealing member disposed proximal the expansible member is then displaced by retracting and tensioning a coil spring so as to expose a chemical and/or biological region or release region of the device. The retraction and tensioning of the coil spring is limited by a coupling member. Exposure of blood and tissue to the chemical and/or biological sealing member promotes the clotting processing to accelerate the occlusion process in the tract.

A closure device for sealing a percutaneous puncture in a wall of a body passageway, the closure device including at least one of a toggle configured to engage an interior surface of the body passageway or a plug configured to engage an exterior surface of the body passageway and a guide wire configured to extend from an outside of the body to inside the body passageway, wherein at least one of the toggle and the plug is associated with the guide wire.

A device for closing an aperture in a vessel wall including a covering member positionable inside the vessel against the internal opening of the aperture and having a dimension to prevent egress of fluid through the aperture. The covering member has a proximal surface and a distal surface, the distal surface having a concave surface and the proximal surface having a raised surface, wherein four openings are positioned in the raised surface. First and second retainers are positionable external of the vessel and first and second connecting members advance the respective first and second retainers toward the covering member.

A device for closing an aperture in a vessel wall including a covering member positionable inside the vessel against the internal opening of the aperture and having a dimension to prevent egress of fluid through the aperture. The covering member has a proximal surface and a distal surface, the distal surface having a concave surface and the proximal surface having a raised surface, wherein four openings are positioned in the raised surface. First and second retainers are positionable external of the vessel and first and second connecting members advance the respective first and second retainers toward the covering member.

The present invention relates to a vascular closure device, comprising a self-expanding tubular vascular closure element, a retaining element surrounding the vascular closure element, the retaining element being arranged to hold the vascular closure element in the lumen of the retaining element in a configuration where the vascular closure element is not fully self-expanded, a tether that is threaded through the lumen of the retaining element, the tether being arranged so that, upon application of a first force to the tether which is greater than a threshold force, the tether disintegrates the retaining element so as to allow the vascular closure element to freely expand. It also relates to a system for delivering such a vascular closure device and to a method of closing a vascular access hole using a corresponding device.

An amnion tissue delivery system for delivering amnion tissue into a location within a patient is described. The location within a patient may be a tube, vessel, lumen, orifice, fistula, aneurysm, or chamber. The amnion tissue delivery system employs a catheter and extendable element, such as a removable stent-like structure, in a configuration such that extension of the extendable section deploys the amnion tissue at the desired location. A method for delivery of amnion tissue within a patient is also described. The method includes placing the catheter within the patient using a minimally invasive, endoluminal and/or extraluminal procedure to position tissue, followed by deploying the extendable element to deliver the amnion tissue at the desired location.