Exemplary embodiments of the present disclosure relate to devices, systems, and methods for tissue resection in a body lumen of a patient, and may include an elongate body having a cavity at a distal end and a tissue retractor extendable distally from the distal end of the elongate body. The tissue retractor may include an expansion mechanism. The expansion mechanism may include a plurality of arms each having a first end coupled around a distal cap and expandable radially outward from the distal cap such that an anchoring mechanism on a second end of the arms is engageable with selected tissue for resection of the body lumen. The tissue resection device may further include a tissue resecting device.

Embodiments of the present disclosure are directed to implantable sealing devices, delivery apparatuses, and methods of their use, for closing surgical openings or defects in a sidewall of a vessel in a subject. In several embodiments, the disclosed implantable sealing devices, delivery apparatuses, and methods can be used to close a surgical opening in a sidewall of the heart.

An auto-graft bio-synthetic mesh and a method of application for wound closure is described. The mesh is utilized for wound closure wherein an abdominal incision is effected through the peritoneum and the rectus abdominal sheath of the rectus muscle such as when repairing ventral or paracoslostomy hernias. The mesh comprises a flexible patch of woven fibers and wherein the patch is one of a substantially circular patch or a patch having a substantially circular delineation thereon whereby to provide guidance for the formation of stitches in at least one circle to secure the patch to the peritoneal peritoneum and the rectus abdominal sheath of the rectus muscle. The patch is secured by applying stitches all about an outer circular edge of the patch and an inner circle thereof. A suture clip for joining portions of bodily soft tissue is also described.

Drill guides allow an implant to be partially inserted after the holes are drilled and before the drill guide has been removed from the surgical location.

A surgical fastener applying apparatus includes an anvil half-section and a cartridge-receiving half-section including an elongated channel member having a pair of opposed openings defined through sidewalls thereof. A disposable assembly including a single use loading unit and a single use firing unit is configured to be releasably supported within the cartridge-receiving half-section. The disposable assembly includes a stationary housing for supporting the firing unit which includes a distal extension for supporting the single use loading unit. The stationary housing includes a pair of flared tabs configured to be releasably received within the openings of the cartridge-receiving half-section to releasably engage the disposable assembly within the cartridge-receiving half-section.

An implant 801 for closing an opening in tissue such as a fistula or a sinus comprises a coil having a substantially uniform outer diameter. The coil forms an internal passage having a diameter that tapers from a distal end to a proximal end. The implant 801 may be delivered using a non-tapered driver coil 820.

Collapsible tube embodiments may be used to promote hemostasis at surgical sites or any other suitable location. In some cases, vascular closure device embodiments may include collapsible tube embodiments in order to promote hemostasis at a surgical site during a vascular closure procedure.

The present disclosure relates to medical devices. More particularly, this disclosure describes a vascular device allowing large bore transseptal access with subsequent atrial re-access by preplacing closures/tissue approximating sutures prior to creating a septostomy. Generally, the device may include a delivery catheter for puncturing and cutting the interatrial septum. An anchor of the delivery catheter may secure the suture in an atrium to a septum wall, for example, the left atrium. Incisions may be made by an expandable cutting implement which may use mechanical or radio frequency (RF) energy without interfering with the suture. A therapeutic instrument may be advanced through the tissue plane after the incisions are made by the cutting implement. Closure of the incision may be performed with the previously placed sutures.

A medical device and methods for hemostasis in a living body are disclosed. The medical device including a base configured to arranged on an upper surface of the tissue in the living body; a plurality of levers, each of the plurality of levers having a needle arranged on a lower surface thereof and configured to puncture the tissue in the living body, and wherein the plurality of lever are configured to be received with a slot or track of the base; and at least one tie, the at least one tie configured to hold together the plurality levers and needles upon compressing the tissue in the living body upon moving the plurality of levers inward in the slot or track of the base.

Surgical clips and surgical applicators used in performing rapid tissue closure in either minimally invasive surgeries or traditional open procedures are provided. In one example approach, a surgical clip comprises opposing sides extending from a top portion and terminating at tips positioned below the top portion. The resting position of the clip is its closed position. Edges of the top portion and the opposing sides form opposing faces perpendicular to the opposing sides. The opposing faces are angled inwardly towards each other at a region of the faces adjacent to the top portion. Grooves are formed in each of the opposing sides. The grooves are configured to engage inwardly turned tracks of a clip applicator such that, when a force is applied to the clip, the opposing sides bend outwardly away from each other to place the clip in an intermediate open position.