A prosthetic graft assembly (40, 120) is disclosed for placement of a patient's aortic arch and repair of the descending aorta in a procedure which requires only a sternotomy. The assembly includes a descending graft element (40) which includes an eversible cuff (52) which can be wrapped over a cut end (26) of the descending aorta (18). Distal perfusion can be re-established prior to aortic arch replacement. A second prosthetic element (120), optimised to the patient, is fitted with a replacement for the aortic arch and attached to the descending aorta graft (40). An introducer assembly (30) having a transparent or translucent sheath (70) enables the descending aortic graft element (40) to be deployed without the use of x-rays.

Provided is a medical tubular body delivering device that can prevent kinking and efficiently deploy a medical tubular body, while maintaining the reinforcing effect without reducing operability. The device has an outer tube through which the medical tubular body is disposed; a guidewire insertion member provided proximal to the medical tubular body; and an inner insertion member provided in the outer tube, and the guidewire insertion member has a penetration passage; a guidewire tube is provided in the penetration passage; the inner insertion member is partially fixed to the guidewire insertion member; a first protection member is provided outside a part of the inner insertion member proximal to a fixing portion; and at least a part of the inner insertion member between a proximal end of the fixing portion and a distal end of a region where the first protection member is provided is covered by a second protection member.

Provided is a medical tubular body delivering device that can prevent kinking and efficiently deploy a medical tubular body, while maintaining the reinforcing effect without reducing operability. The device has an outer tube through which the medical tubular body is disposed; a guidewire insertion member provided proximal to the medical tubular body; and an inner insertion member provided in the outer tube, and the guidewire insertion member has a penetration passage; a guidewire tube is provided in the penetration passage; the inner insertion member is partially fixed to the guidewire insertion member; a first protection member is provided outside a part of the inner insertion member proximal to a fixing portion; and at least a part of the inner insertion member between a proximal end of the fixing portion and a distal end of a region where the first protection member is provided is covered by a second protection member.

Delivery systems with telescoping capsules for delivering prosthetic heart valve devices and associated methods are disclosed herein. A delivery system configured in accordance with embodiments of the present technology can include, for example, a delivery capsule having a first housing, a second housing slidably disposed within a portion of the first housing, and a prosthetic device constrained within the first and second housings. The delivery capsule can further include first and second chamber defined in part by the first and second housings. During deployment, fluid is delivered to the first chamber to move the first housing distally over the second housing, thereby releasing a portion of the prosthetic device. Subsequently, fluid is delivered to the second chamber such that the first and second housings move together in the distal direction to release a second portion of the prosthetic device.

Delivery systems with telescoping capsules for delivering prosthetic heart valve devices and associated methods are disclosed herein. A delivery system configured in accordance with embodiments of the present technology can include, for example, a delivery capsule having a first housing, a second housing slidably disposed within a portion of the first housing, and a prosthetic device constrained within the first and second housings. The delivery capsule can further include first and second chamber defined in part by the first and second housings. During deployment, fluid is delivered to the first chamber to move the first housing distally over the second housing, thereby releasing a portion of the prosthetic device. Subsequently, fluid is delivered to the second chamber such that the first and second housings move together in the distal direction to release a second portion of the prosthetic device.

A tubular prosthetic device for implantation into a body lumen includes a first part including a tubular lumen and a second part including an attachment member. The second part is secured to the first part via various configurations, where the device is capable of being reduced to a diameter less than the diameter of traditional devices, for ease of use during implantation. Methods of using the device are also provided.

A tubular prosthetic device for implantation into a body lumen includes a first part including a tubular lumen and a second part including an attachment member. The second part is secured to the first part via various configurations, where the device is capable of being reduced to a diameter less than the diameter of traditional devices, for ease of use during implantation. Methods of using the device are also provided.

A prosthetic valve prosthesis including a stent body and a valve leaflet assembly is disclosed. The stent body includes a first stent and a second stent. The first stent is provided with a connecting end. The second stent includes several stent rods, and the several stent rods are fixed to the connecting end of the first stent respectively. The valve leaflet assembly is provided with a first valve leaflet fixing portion, and the valve leaflet assembly is fixed to the connecting end of the first stent by the first valve leaflet fixing portion.

A stent comprises a framework that includes a sequence of cells that each occupy a discrete segment of the stent length, and each of the cells includes a plurality of struts with ends connected at respective vertices. An adjacent pair of the cells are attached to one another by a plurality of T-bars that each include a column defining a long axis that extends parallel to the stent axis, and a top bar attached to one end of the column. An opposite end of the column is attached to a first cell, and the top bar is attached at opposite ends to a second cell of the adjacent pair of cells. The column has a minimum width perpendicular to the long axis that is wider than a maximum width of each of the struts, and the column defines at least one slot. The top bar includes a curved edge on an opposite side from the column, and the curved edge straddles the long axis.

A stent comprises a framework that includes a sequence of cells that each occupy a discrete segment of the stent length, and each of the cells includes a plurality of struts with ends connected at respective vertices. An adjacent pair of the cells are attached to one another by a plurality of T-bars that each include a column defining a long axis that extends parallel to the stent axis, and a top bar attached to one end of the column. An opposite end of the column is attached to a first cell, and the top bar is attached at opposite ends to a second cell of the adjacent pair of cells. The column has a minimum width perpendicular to the long axis that is wider than a maximum width of each of the struts, and the column defines at least one slot. The top bar includes a curved edge on an opposite side from the column, and the curved edge straddles the long axis.