Methods, apparatuses, and systems are described for stent delivery and positioning for transluminal application. The method may include positioning the stent in an undeployed configuration through an access site in a wall of a first body lumen. In some cases, the method may include retracting an outer sheath proximally and past an anchoring component disposed at a distal portion of an inner tubular member based on positioning the stent. A distal portion of the stent may be disposed between the anchoring component and the outer sheath while the stent is in the undeployed configuration. The method may further include deploying the distal portion of the stent from the outer sheath and within the first body lumen and expanding a proximal portion of the stent from within the outer sheath such that upon fully exiting the outer sheath, the proximal portion expands to a deployed configuration within a second body lumen.

Apparatuses, and systems are described for stent designs for transluminal application. The stent may include a stent body having a diameter and a length in a deployed configuration. The stent may include a helical wrapping pattern that is at least partially covered with a material. The helical wrapping pattern may be configured to reduce a foreshortening of the stent body upon deployment from an undeployed configuration to the deployed configuration to less than ten percent of a length of the stent body in the undeployed configuration. In some cases, the stent may include a first anchoring member coupled with a distal portion of the stent body and a second anchoring member coupled with a proximal portion of the stent body. The first and second anchoring members may be configured to increase a diameter of the stent.

A stent which has a cylindrical tubular shape in which wires cross each other and are woven includes first regions each including a horizontal folding crossing portion in which the wires are folded in an axial direction and cross each other and a vertical folding crossing portion in which the wires are folded in a circumferential direction and cross each other. The first region is a region in which the horizontal folding crossing portion and the vertical folding crossing portion are arranged in the circumferential direction, and the first regions are arranged at intervals in the axial direction.

An stent delivery system may include a delivery device and a tubular body having a lumen sized to slidably fit about an outer diameter of the delivery device and a drainage stent having an anchoring mechanism, wherein the delivery device includes a constraining member configured to engage an external portion of the tubular body at the proximal end of the delivery device. A method of delivering a stent may include inserting a tubular body into the port of an endoscope, inserting a stent delivery device and a stent having an anchoring mechanism into the tubular body, wherein the delivery device includes a constraining member configured to engage and retain the tubular body at the proximal end of the delivery device, advancing the drainage stent distally through the tubular body, sliding the tubular body proximally, and engaging an external portion of the tubular body with the constraining member.

Stents comprising a first region and a second region are provided, where at least the second region comprises one or more phase transforming cellular materials configured to move the outlet between an open configuration and a closed configuration in response to certain triggers. Such stents can also comprise one or more analog for a shape memory alloy (ASMA) unit cells on an inner surface of the first region such that, in response to resistive forces, the ASMA unit cells exert controllable motion to clear the stent. Methods of treatment of cancer, jaundice, and other diseases are also provided.

According to one aspect, a method for removing material from a body lumen is disclosed. The method may include positioning a first medical device within the body lumen; and expanding an expandable member at a distal portion of the first medical device from a retracted state to an expanded state. The expandable member may abut the body lumen in the expanded state. The method may further include providing fluid to a fluid lumen of the first medical device, wherein the fluid is deployed into the body lumen; applying an ultrasound signal to the first medical device from a second medical device; and moving the first medical device distally through the body lumen while the expandable member is in an expanded state, to remove material from the body lumen.

Medical stent designs are disclosed. An example stent includes a tubular scaffold having a proximal end and a distal end. The tubular scaffold includes a first filament extending between the proximal end and the distal end, the first filament including a first biodegradable region positioned adjacent to a second biodegradable region. Further, the first biodegradable region includes a first biodegradable material, the first biodegradable material having a first rate of degradation. The second biodegradable region includes a second biodegradable material, the second biodegradable material having a second rate of degradation, wherein the first rate of degradation is different from the second rate of degradation.

A catheter includes a first region having a first outer diameter; a second region having a second outer diameter larger than the first outer diameter; and a transition region connecting with the first region and the second region, the transition region having an outer diameter being equal to or larger than the first outer diameter and equal to or smaller than the second outer diameter, wherein the outer diameter of the transition region gradually decreases from the second region toward the first region, and part of an outer circumferential surface of the transition region is formed in a shape having a step portion.

Medical stent designs are disclosed. An example stent includes a tubular scaffold having a proximal end and a distal end. The tubular scaffold includes a first filament extending between the proximal end and the distal end, the first filament including a first biodegradable region positioned adjacent to a second biodegradable region. Further, the first biodegradable region includes a first biodegradable material, the first biodegradable material having a first rate of degradation. The second biodegradable region includes a second biodegradable material, the second biodegradable material having a second rate of degradation, wherein the first rate of degradation is different from the second rate of degradation.

The present disclosure relates generally to the field of medical devices and establishing fluid communication between body lumens. In particular, the present disclosure relates to devices and methods for placing the muscularis layers of first and second body lumens in contact to establish a long term or permanent open flow or access passage therebetween.