An excision and aspiration apparatus adapted to sample a tissue mass includes a receptacle, such as a suction cup, which is adapted to receive a superficial portion only of the total tissue mass. An excision mechanism, such as a cutting wire, excises the superficial portion from the rest of the tissue mass. The excision and aspiration apparatus further includes a suction tube having a receiving channel for collecting the excised superficial portion of the tissue mass, as well as a vacuum source for creating suction within the suction tube that is sufficient to draw the excised superficial portion of the tissue mass into the receiving channel of the suction tube.

A proximal housing for a full-thickness resection device (FTRD) is provided with a plurality of chambers through which fasteners are introduced into a portion of tissue to be resected. The proximal housing has a noncircular cut-out opposite the plurality of chambers to receive a noncircular endoscope. The proximal housing also is provided with a resection cavity into which the tissue to be resected is to be received. In addition, shaft openings are provided through which mounting shafts may be inserted. A noncircular endoscope is also disclosed for insertion into the cut-out whereby the endoscope has passages to house the functions of remote viewing, illumination, insufflation and irrigation.

According to embodiments of the invention, an apparatus for moving a diseased portion of an anatomical structure with respect to a healthy portion of an anatomical structure includes a first vacuum section adapted to apply vacuum force to and hold the healthy portion, and a second vacuum section adapted to apply vacuum force to and hold the diseased portion, wherein the second vacuum section is adapted to withdraw within the first vacuum section.

A minimally invasive surgical procedure is disclosed which includes the steps forming a fold of tissue, extending one or more needles through the fold of tissue, deploying a tissue fastener from an interior lumen of each of the needles, and retracting each of the needles from the fold of tissue such that the tissue fasteners remain deployed in the fold of tissue.

Methods and apparatus for treatment of patent foramen ovale (PFO) provide for applying energy to tissues adjacent the PFO with a catheter device to substantially close the PFO acutely. Apparatus generally includes a catheter device having at least one energy transmission member at or near its distal end configured to apply energy to PFO tissues to acutely, substantially close the PFO. Applied energy may be monoploar or bipolar radiofrequency energy or any other suitable energy, such as laser, microwave, ultrasound, resistive heating or the like. Some embodiments of a catheter device further include one or more tissue apposition members near the distal end for helping bring PFO tissues together, such as a PFO covering member, a vacuum applying member and/or the like. PFO closure via energy-based approaches of the invention may help prevent stroke, treat migraine headache, and possibly treat or prevent other medical conditions.