This disclosure provides novel hydrogels that can undergo multiple gel-sol transitions and methods of making and using such hydrogels, particularly in anastomosis procedures. The peptide hydrogels comprising a fibrillar network of peptides that are in an amphiphilic β-hairpin conformation. The peptides comprise photo-caged glutamate residues with a neutral photocage that can be photolytically selectively uncaged to disrupt the fibrillar network and trigger an irreversible gel-sol phase transition of the hydrogel. Isolated peptides for making the disclosed hydrogels are provided, as are methods of using the peptide hydrogels in anastomosis procedures.

This document relates to the apparatus and methods used in the minimally invasive creation of arteriovenous fistula (AVF). In particular, the invention relates to the creation of an AVF using catheters and an alignment methodology that is based upon detection of asymmetric electric fields. The invention finds particular application in vascular access (VA) in the hemodialysis (HD) population.

Described here are devices, systems, and methods for forming a fistula between two blood vessels. Generally, the systems may comprise a first catheter and a second catheter, which may comprise one or more fistula-forming elements. The first and second catheters may comprise one or more magnetic elements, which may be used to assist in bringing the first and catheters in closer proximity to facilitate fistula formation. In some variations, the magnetic elements may have magnetization patterns such that the flux generated by the magnetic elements is locally concentrated. In some instances, the system may comprise a magnetic control device, which may comprise a magnet, and may be used to increase or create an attractive force between the first and second catheters.

Described here are devices, systems, and methods for forming a fistula between two blood vessels. Generally, the systems may comprise a first catheter and a second catheter, which may comprise one or more fistula-forming elements. The first and second catheters may comprise one or more magnetic elements, which may be used to assist in bringing the first and catheters in closer proximity to facilitate fistula formation. In some variations, the magnetic elements may have magnetization patterns such that the flux generated by the magnetic elements is locally concentrated. In some instances, the system may comprise a magnetic control device, which may comprise a magnet, and may be used to increase or create an attractive force between the first and second catheters.

Devices, systems, and methods for reducing stress on a blood vessel are disclosed herein. A damping device configured in accordance with embodiments of the present technology can include an anchoring member coupled to a flexible, compliant damping member including a generally tubular sidewall having an outer surface, an inner surface defining a lumen configured to direct blood flow, a first end portion and a second end portion, and a damping region between the first and second end portions. The inner and outer surfaces of the damping member can be spaced apart by a distance that is greater at the damping region than at either of the first or second end portions. When blood flows through the damping member during systole, the damping member absorbs a portion of the pulsatile energy of the blood, thereby reducing a magnitude of the pulse pressure transmitted to a portion of the blood vessel distal to the damping device.

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.

Disclosed are devices and methods suitable for application of a curable fluid composition to a bodily organ, such as to a lower portion of a bodily organ. The device comprises a monolithic piece of material having a lower surface, two spaced-apart sides, and two spaced-apart walls connecting the two spaced-apart sides. A receptacle for containing the curable fluid composition is defined by the lower surface, the two sides, and the two walls. At least a portion of the height of the two walls is less than the height of at least a portion of the two sides. The device is deployable underneath the bodily organ such that a lower portion of the bodily organ is supported by at least a portion of each of the two walls.

Disclosed are devices and methods suitable for application of a curable fluid composition to a bodily organ, such as to a lower portion of a bodily organ. The device comprises a monolithic piece of material having a lower surface, two spaced-apart sides, and two spaced-apart walls connecting the two spaced-apart sides. A receptacle for containing the curable fluid composition is defined by the lower surface, the two sides, and the two walls. At least a portion of the height of the two walls is less than the height of at least a portion of the two sides. The device is deployable underneath the bodily organ such that a lower portion of the bodily organ is supported by at least a portion of each of the two walls.

A system is configured to bring about anastomosis between two lumens in a patient or between two sections of a single lumen in a patient. The anastomosis system includes a first tissue-compressing element, a second tissue-compressing element, and an energy source. The energy source can be a thermal energy source or laser energy source. Tissue is interposed between the elements. Magnetic material incorporated into the tissue-compressing elements facilitates the alignment of the elements as well as compression of the interposed tissue. The energy source can deliver energy to tissue. This delivery of energy can cause local changes to the tissue that can help maintain positional stability of the implants, can bring about immediate patency of the anastomosis and can otherwise facilitate achieving desired outcomes for the patient.

A method is provided for operating a powered surgical stapler having a motor unit, a controller. and a stapling assembly having a closure member, a staple driver member, and a knife member. The controller receives a user input that indicates a tissue gap to be defined by the stapling assembly in a closed state. Based on the user input, the controller controls the motor unit to actuate the closure member to transition the stapling assembly to the closed state to define the tissue gap and clamp tissue therein. The controller then controls the motor unit to actuate the staple driver member to drive staples into the clamped tissue. In response to determining that the staple driver member has reached a predetermined longitudinal position, the controller controls the motor unit to initiate actuation of the knife member to cut the clamped tissue.