An apparatus for insertion into a body through a working channel of an endoscope includes a catheter including a dilator, a guide tube disposed in a lumen of the catheter, and a handle including a puncturing actuator operatively coupled to the proximal end of the guide tube. The dilator may be a cautery device and/or a balloon. The apparatus may also include a stylet needle that includes a cutting distal end for puncturing tissue and extends through a lumen in the guide tube. The handle may further include a stopper detachably coupled to the puncturing actuator to fix a position of the puncturing actuator on the handle, and moveable on the handle independently of the puncturing actuator when detached from the puncturing actuator. The disclosed embodiments also include a method for forming a passageway in a wall of a hollow body organ using the apparatus.

An apparatus for insertion into a body through a working channel of an endoscope includes a catheter including a dilator, a guide tube disposed in a lumen of the catheter, and a handle including a puncturing actuator operatively coupled to the proximal end of the guide tube. The dilator may be a cautery device and/or a balloon. The apparatus may also include a stylet needle that includes a cutting distal end for puncturing tissue and extends through a lumen in the guide tube. The handle may further include a stopper detachably coupled to the puncturing actuator to fix a position of the puncturing actuator on the handle, and moveable on the handle independently of the puncturing actuator when detached from the puncturing actuator. The disclosed embodiments also include a method for forming a passageway in a wall of a hollow body organ using the apparatus.

The disclosure provides insertion tools and articles that facilitate entry of a medical device, such as a balloon catheter, into the body. In embodiments the insertion tools have an elongate hollow body (50) that is able to protect a portion of a medical device, such as a balloon of a balloon catheter, during an insertion procedure. In one embodiment the insertion tool has an elongate hollow body (131), a tapered distal end (135), and a locking mechanism (133) at the proximal end which can secure a portion of a balloon catheter. An opening at the distal end can allow passage of the balloon in a folded uninflated state.

The disclosure provides insertion tools and articles that facilitate entry of a medical device, such as a balloon catheter, into the body. In embodiments the insertion tools have an elongate hollow body (50) that is able to protect a portion of a medical device, such as a balloon of a balloon catheter, during an insertion procedure. In one embodiment the insertion tool has an elongate hollow body (131), a tapered distal end (135), and a locking mechanism (133) at the proximal end which can secure a portion of a balloon catheter. An opening at the distal end can allow passage of the balloon in a folded uninflated state.

The invention relates to a method for filling an inflatable catheter balloon of a device for transanally introducing an infusion into the rectum or colon of a patient by means of a filling device, wherein a fill volume or a filling pressure prevailing in the catheter balloon is increased in two or more steps until there occurs a gradual, user-controllable, pneumatically initiated expansion of portions of the bowel wall, thus triggering a coordinated defecation reflex, wherein the timing and intensity of the triggering stimulus can be determined to the greatest possible extent by the user.

A cryoablation catheter, comprising a balloon (1) and a delivery catheter (2) passing through the balloon (1). The delivery catheter (2) is provided with a fluid inflow cavity (21) and a fluid outflow cavity (22) therein. The fluid inflow cavity (21) extends into the balloon (1), and a side wall of the fluid inflow cavity (21) is provided with a spray head (211) that injects a liquid into the balloon (1). The spray head (211) has a number of spray holes (2111, 2112) circumferentially arranged on the exterior of the fluid inflow cavity (21). An end of the fluid outflow cavity (22) has a cross section (24) that seals the fluid outflow cavity (22), and a side wall of the fluid outflow cavity (22) is provided with a reflow hole (221) in communication with the balloon (1). A fluid flows from the fluid inflow cavity (21) through the nozzle holes (2111, 2112) into the balloon (1). The nozzle holes (2111, 2112) are evenly distributed outside the fluid inflow cavity (21), so that the interior of the balloon (1) is uniformly filled with the refrigeration fluid, ensuring the uniformity of heat exchange at each part of the balloon (1) in an axial direction. The fluid then flows out from the reflow hole (221). The structural design can effectively improve the heat exchange efficiency of the fluid, and the production and processing processes are relatively simple.

A cryoablation catheter, comprising a balloon (1) and a delivery catheter (2) passing through the balloon (1). The delivery catheter (2) is provided with a fluid inflow cavity (21) and a fluid outflow cavity (22) therein. The fluid inflow cavity (21) extends into the balloon (1), and a side wall of the fluid inflow cavity (21) is provided with a spray head (211) that injects a liquid into the balloon (1). The spray head (211) has a number of spray holes (2111, 2112) circumferentially arranged on the exterior of the fluid inflow cavity (21). An end of the fluid outflow cavity (22) has a cross section (24) that seals the fluid outflow cavity (22), and a side wall of the fluid outflow cavity (22) is provided with a reflow hole (221) in communication with the balloon (1). A fluid flows from the fluid inflow cavity (21) through the nozzle holes (2111, 2112) into the balloon (1). The nozzle holes (2111, 2112) are evenly distributed outside the fluid inflow cavity (21), so that the interior of the balloon (1) is uniformly filled with the refrigeration fluid, ensuring the uniformity of heat exchange at each part of the balloon (1) in an axial direction. The fluid then flows out from the reflow hole (221). The structural design can effectively improve the heat exchange efficiency of the fluid, and the production and processing processes are relatively simple.

Systems (1100) for treating a blood flow passage are discloses herein. In one example, a treatment device includes an expandable element (1104) configured to be positioned within the passage and a reinforcing element (1102). The expandable element may have an expanded configuration in which the expandable element defines a lumen (1108) therethrough. The reinforcing element may be positioned within the lumen of the expandable element. The reinforcing element may be coupled to the expandable element such that expansion of the expandable element causes the reinforcing element to radially expand, thereby creating a perfusion lumen through the device.

Systems (1100) for treating a blood flow passage are discloses herein. In one example, a treatment device includes an expandable element (1104) configured to be positioned within the passage and a reinforcing element (1102). The expandable element may have an expanded configuration in which the expandable element defines a lumen (1108) therethrough. The reinforcing element may be positioned within the lumen of the expandable element. The reinforcing element may be coupled to the expandable element such that expansion of the expandable element causes the reinforcing element to radially expand, thereby creating a perfusion lumen through the device.

Providing a method for producing a balloon catheter, that is capable of uniformly heating and cooling the entire mold and less likely to cause temperature unevenness. A method for producing a balloon catheter which comprises a shaft extending in a longitudinal direction and a medical resin balloon provided at a distal end portion of the shaft, comprising the steps of inserting a resin tubular body (10) into a mold (20), and placing the mold (20) inside a thermal jacket (30) wherein a porous metal body (50) is disposed outside the mold (20) and inside the thermal jacket (30).