The invention is an implantable magnetic anastomosis device having an exoskeleton that directs self-assembly. The design allows the device to be delivered in a linear configuration using a minimally-invasive technique, such as endoscopy or laparoscopy, whereupon the device self-assembles into, e.g., a polygon. A coupled set of polygons define a circumscribed tissue that can be perforated, or the tissue can be allowed to naturally necrose and perforate. The device can be used to create anastomoses in a variety of tissues, such as tissues found in the gastrointestinal, renal/urinary, and reproductive tracts. New procedures for using anastomoses, e.g., surgical bypass are also disclosed.

A surgical tool has an elongate tubular housing having an annular clamping region formed around an opening in the tubular housing. A vacuum source is operably engaged with the elongate tubular housing for providing a vacuum within the elongate tubular housing for drawing the damaged or diseased portion of a luminal body, such as an intestine, into the tubular housing. An elongate rod is provided having an annular clamping element shaped so that the intestine may be firmly clamped between the annular clamping element and the annular clamping region of the elongate tubular housing, so that the damaged or diseased portion of the intestine is entirely within the elongate tubular housing.

An anastomosis device includes magnets coupled to a wire capable of changing shape from a straight wire into a coil when deployed within a body. The coil exerts compressive force upon layers of tissue caught between loops of the coil. The compressive force is enhanced by attractive forces between magnets coupled with adjacent loops of the coil and causes the coil to cut through the tissue layers, creating an anastomosis. One end of the wire is preferably provided with a connecting member, such as a screw or a nut, for connecting with a delivery device. Positioned on or around the anastomosis device is an expandable drainage mechanism, such as a stent.

Disclosed embodiments include apparatuses and methods for deploying a coilable filament on opposing sides of a surface. An apparatus includes a needle mechanism configured to extend and withdraw the needle. A coil mechanism is configured to advance a stylet through the needle to extend a coilable filament at a distal end of the stylet. An interlock mechanism is configured to control operations of the needle mechanism and the coil mechanism, including moving the needle and the stylet in concert to extend the needle and coilable filament to a distal side of the surface, separately advancing the stylet to extend a first segment of the coil on the distal side of the surface, withdrawing the needle to the proximal side of the surface, and separately further advancing the stylet to deploy a second segment of the coil along the proximal side of the surface.

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.

A system for endoscopically forming an anastomosis between two naturally adjacent points in the digestive tract. The system utilizes elongate magnetic devices that, when connected across a tissue boundary, necrose tissue until an anastomosis forms and the devices are passed naturally. Despite the elongate shape of the devices, the resulting anastomosis is substantially round. As such, round anastomoses can be formed having increased diameters merely by increasing the lengths of the devices, obviating the need for wider endoscopes.

Methods and apparatus for creating an anastomosis or fistula between the gallbladder and an adjacent organ are disclosed. First, a parent magnet, typically a permanent magnet, is deployed in the stomach, small intestine, or another organ adjacent to the gallbladder, and a mating daughter material is deployed in the gallbladder in order to create a magnet-compression anastomosis. The gallbladder may then be ablated or otherwise functionally inactivated through the anastomosis. Another aspect of the invention relates to an all-in-one surgical kit that contains all the necessary specialized tools for a surgeon to perform the procedure.

The invention features delivery systems for delivering a gastrointestinal device into the gastrointestinal tract of a patient and anchoring the gastrointestinal device with an anchor (e.g., a disintegrable anchor). Also provided are methods of delivering such gastrointestinal devices using the delivery systems described herein. The methods and delivery systems of the invention can be used for treatment of metabolic diseases, such as type 2 diabetes, non-alcoholic steatohepatitis (NASH), non-alcoholic fatty liver disease (NAFLD), obesity, and related comorbidities thereof.

A device for anastomosis of a tubular structure comprises first and second hollow members having a rigid part and an elastic part, and a connection member for interlocking the first and second members. The elastic parts are essentially circular rings, and are made of a polymeric, a biocompatible and/or biodegradable material. The rigid parts have an outer surface that is partly semi-circular in cross section, wherein the diameter at a non-connecting end is larger than or equal to the diameter at a connecting end, which ends in an edge. The first and second members are connected to each other so that a distance is formed between the elastic parts. A cavity is formed between the rigid parts and the connection member and the tubular structure, when arranged in the device.

The present disclosure provides modular magnetic anastomosis devices that can be implemented in digestive surgery or in any circumstance of anastomosis between adjacent organs or two hollow viscera. The device is minimally invasive and easily and quickly delivered using laparoscopic or endoscopic procedures.