A lead introducer includes an integrated sheath/needle including a splittable sheath configured to split a into a first portion and a second portion, a needle having a length and a proximal end region, and a hub coupled to the proximal end regions of the splittable sheath and the needle and configured to split into a first portion and a second portion. The needle is permanently attached to either the first portion of the hub or the first portion of the splittable sheath (or both) so that when the hub is split into the first and second portions, the needle remains attached to the first portion of the hub or the first portion of the splittable sheath.

Described herein are devices and methods for applying a tension force to various tissues. The devices may be delivered in minimally invasive fashion and used to manipulate tissues in the nose, ear, and throat. Force may be maintained by the devices for a time period that allows shaping, compression, or approximation of tissues.

The disclosure relates to cannulae, delivery systems, methods of making cannulae, and methods of making delivery systems. A delivery system comprises an elongate outer tubular member defining an outer tubular member lumen, a cannula having a circumferential wall extending between a proximal end and a distal end and defining an interior lumen, and an intraluminal medical device disposed within the outer tubular member lumen distal to the cannula and not about the cannula. A pattern of openings arranged in an interrupted spiral extends circumferentially along the cannula.

Devices, systems, and methods for delivering prosthesis implants into surgically-created implant pockets in a subject and for preventing capsular contracture resulting from surgical insertion of prosthesis implants. The device may include a delivery member operable to wrap around the implant thereby forming a conforming cavity around the implant that conforms to the shape of the implant. The delivery member is also operable to propel the implant from the conforming cavity into the implant pocket in the subject upon the application of mechanical force to the delivery member. The device also includes a shielding member coupled with the delivery member. The shielding member is operable to shield the implant from at least a portion of the dissection tunnel connecting the incision to the implant pocket during delivery of the implant to the implant pocket. The device is capable of shielding the implant from microbial contamination, including contamination by the endogenous flora of the subject, during delivery of the implant into the surgically-created implant pocket.

A voice prosthesis insertion device includes an elongated body having an aperture therein extending axially along the elongated body. The elongated body includes a ring member at one end that is supported by a pair of straps. The elongated body has at least one region that is increasing in cross section. The elongated body further having a collapsible portion defined by a pair of openings in the elongated body. A rod is disposed in the aperture of the elongated body and including a peg adapted to be inserted into an aperture of a tether of a voice prosthesis device. The collapsible portion of the elongated body is flexible to allow the collapsible portion to be longitudinally collapsed to expose the peg of the rod for easy engagement with the strap of the voice prosthesis and the collapsible portion is extendable from the collapsed position to extend over the peg.

A guide wire system configured to guide a medical device (e.g., a medical lead) to a target area within a patient. The guide wire system may be configured to penetrate and pass through a tissue wall in the patient to guide the medical device to the target area. The guide wire system includes a support section configured to expand to substantially maintain a position relative to the tissue wall. The guide wire system includes a pull wire configured to cause the support portion to expand. The expanded support section may provide counter-traction to a distal force on the tissue wall exerted by a medical device during, for example, fixation of the medical device to the target area, or other stages of an implantation. The support section is configured to re-establish an initial configuration for proximal withdrawal from the tissue wall.

Embodiments in the present disclosure relate to an anchoring and centering device for a circulatory support pump. An exemplary apparatus comprises an expandable anchoring device extending along a longitudinal axis, wherein the expandable anchoring device is arranged about a central axis. A distal portion of the expandable anchoring device defines an annulus through which the cardiac pump can be arranged and to which the cardiac pump can be releasable coupled. A proximal portion of the expandable anchoring device is configured to circumferentially expand to an unconstrained configuration that has a cross-sectional diameter greater than a diameter of the annulus. The exemplary apparatus also includes a constraining member arranged over the expandable anchoring device to constrain the expandable anchoring device in a constrained configuration for delivery of the anchoring apparatus.

A catheter tube comprises a tube wall, which surrounds a tube lumen, wherein the tube wall comprises the following: a mesh; and a guide lumen around which the mesh is braided and in which a pull element extends from a proximal portion of the catheter tube to a distal portion of the catheter tube. The pull element is connected in a tension-resistant manner to the tube wall in the distal portion. The guide lumen guides the pull element at least partially around the tube lumen.

A transfer device for a living organism for placing an object in a living organism comprises a plurality of movable units. Each movable unit comprises one or more needles extending in a first direction. Each needle has a cylindrical shape capable of storing the object therein. Each movable unit is movable in the first direction.

An implantable closure device for sealing an opening, such as a puncture, through a biologic tissue membrane, such as the meninges, against leakage of biological fluid. The closure device includes a fluid sealing plug configured to be positioned at least partially within the opening through the biologic tissue membrane. A retainer is configured to secure the fluid sealing plug at least partially within the opening. The retainer includes a proximal retainer portion configured to be disposed proximally on the biologic tissue membrane, a distal retainer portion configured to be disposed distally on the biologic tissue membrane, and a central retainer portion connecting the proximal retainer portion and the distal retainer portion. The central retainer portion is configured to extend through the opening. The fluid sealing plug is coupled to the central retainer portion.