Method and apparatus for mapping the shape and dimensions of a 3-dimensional body, by applying to the 3-dimensional body a stretchable covering configured and dimensioned such that in its stretched condition it tightly engages and conforms to the shape and dimensions of the 3-dimensional body to be mapped. The stretchable covering carries a plurality of reference devices, such as bands and/or markers which are at know or determinable reference locations in an initial condition of the covering, and which change their locations in the stretched condition of the stretchable covering according to the shape and dimensions of the 3-dimensional body covered thereby. The locations of the markers on the stretchable covering are determined after the stretchable covering has been applied to the 3-dimensional body, and are utilized to produce a map of the shape and dimensions of the 3-dimensional body.

The tissue construct with viable cells in an extracellular matrix made of fibrin is produced with a special method, in which a matrix material and cells are shaped into a hollow body, in particular a tubular hollow body, by means of a rotational casting method in a hollow mould (1), the method comprising the following steps: (a) introduction of cells of at least one cell type and/or a fibrinogen preparation into the rotating hollow mould (1) with the aid of an applicator (4), said applicator (4) being displaced along the rotational axis during the introduction and step (a) being performed one or more times; (b) continuation of the rotation process until the fibrinogen solidifies into a dimensionally stable matrix, obtaining a primarily solidified tissue construct; (c) removal of the tissue construct from the mould. The construct can also he obtained in a relatively short time from autologous materials.

A blood vessel dissecting device includes: a dissecting device which, when inserted into a living body along a blood vessel, dissects tissue in a direction of alignment of the dissecting device with the blood vessel; and a cutting device which, when inserted into the living body along the blood vessel, cuts tissue surrounding the blood vessel in a direction of alignment of the cutting device with the blood vessel. A blood vessel dissecting method includes: inserting a dissecting device into a living body along a blood vessel so as to dissect tissue in a direction of alignment of the dissecting device with the blood vessel; and inserting a cutting device into the living body along the blood vessel while guiding the cutting device with the dissecting device so as to cut tissue surrounding the blood vessel in a direction of alignment of the cutting device with the blood vessel.

The present invention provides a connective tissue body formation substrate which can form a film connective tissue having a desired thickness and both surfaces in a desired surface condition without prolonging the time required for formation of the connective tissue. Specifically, two tissue formation surfaces 2a and 2b are faced with each other with a tissue formation space 3 being interposed therebetween. A slit 9 is formed in the tissue formation surface 2b so that the tissue formation space 3 communicates with an outside of the substrate. A connective tissue body formation substrate 1 is installed in an environment where a biological tissue material is present. A connective tissue intrudes into the tissue formation space 3 from the slit 9. Both surfaces of the film connective tissue are formed so as to match the substrate surface.

The invention relates to the technical filed of tissue engineering and 3D printing, particularly relates to an artificial tissue progenitor and a method for preparing the same. In particular, the invention relates to an artificial tissue progenitor comprising a solid support and a plurality of microcapsules, wherein at least one microcapsule is attached to the solid support, and the microcapsule comprises a cell and a biocompatible material encapsulating the cell, to a method for preparing the artificial tissue progenitor, to a kit and a package useful for preparing the artificial tissue progenitor, to an artificial tissue obtained by culturing the artificial tissue progenitor, such as an artificial lumen, to a lumen implant or a lumen model containing the artificial tissue progenitor or the artificial lumen, to use of the artificial tissue progenitor in the manufacture of an artificial tissue, a lumen implant or a lumen model, and to use of the artificial tissue in the manufacture of a lumen implant or lumen model.

The present invention relates to a device for coating the inside of an artificial blood vessel and, to explain more specifically, to a device for coating the inside of an artificial blood vessel inserted into the body of a human for a medical purpose, which is configured to be able to selectively coat just the inside of a lumen of the artificial blood vessel with a bioactive substance for inhibiting neointimal hyperplasia, in order to prevent a side effect, such as angiostenosis or inflammation, from occurring in an area connecting the artificial blood vessel and a blood vessel in the body.

Medical systems, devices and methods for creation of autologous tissue valves within a mammalian body are disclosed. One example of a device for creating a valve flap from a vessel wall includes an elongate tubular structure having a proximal portion and a distal portion and a longitudinal axis; a first lumen having a first exit port located on the distal portion of the elongate tubular structure; a second lumen having a second exit port located on the distal portion of the elongate tubular structure; a recessed distal surface on the distal portion of the elongate tubular structure, wherein the recessed distal surface is located distally to the first exit port; and an open trough on the recessed distal surface extending longitudinally from the first exit port.

Medical systems, devices and methods for creation of autologous tissue valves within a mammalian body are disclosed. One example of a device for creating a valve flap from a vessel wall includes an elongate tubular structure having a proximal portion and a distal portion and a longitudinal axis; a first lumen having a first exit port located on the distal portion of the elongate tubular structure; a second lumen having a second exit port located on the distal portion of the elongate tubular structure; a recessed distal surface on the distal portion of the elongate tubular structure, wherein the recessed distal surface is located distally to the first exit port; and an open trough on the recessed distal surface extending longitudinally from the first exit port.

Embodiments of the present disclosure are directed to apparatuses and methods for fabricating tubular structures from a combination of fibrous materials for use in, for example, tissue engineering scaffold applications. These materials may also be useful in other biological or non-biological applications in which such tubular fibrous structures may be applicable, examples including conventional medical devices, filters, fiber optics, cable wraps, geotextiles, batteries, fuel cells, armor, and other diverse applications.

One aspect of the invention provides a method for preparing a vein graft. The method includes: applying a tissue passivation agent to a resected anatomical vessel; placing the resected anatomical vessel in a chamber; and allowing the tissue passivation agent to cross-link while the resected anatomical vessel is in the chamber.