Abstract: A method for generating fluid flow images of a region of interest is disclosed. The method includes: scanning the region of interest to acquire a set of 4D-Flow magnetic resonance images, wherein the set comprises an anatomical magnitude image, a first velocity component image, a second velocity component image, and a third velocity component image; isolating the anatomical magnitude image, the first velocity component image, the second velocity component image, and the third velocity component image from the set of 4D-Flow magnetic resonance images; converting the first, second, and third velocity component images into a velocity vector field; modeling a location of an anatomical wall within the region of interest; calculating at least one flow dynamics parameter for the region of interest; and generating a visual representation of the anatomical wall and the at least one flow dynamics parameter.

Abstract: Described is an apparatus for transcatheter detachment of a stent from a delivery device. A braided suture with an opening is inserted through a restraining hole in a glide (the opening is secured on one side by a knot or a series of knots) and a release line is inserted through the braided suture opening. The braided suture is thus prevented from pulling through the restraining hole while the release line is through the opening. The braided suture is free to pass through the restraining hole after the release line is pulled out of the opening and thereafter pulled free of stent holes formed through a stent, thereby detaching the stent at a desired location.

Abstract: Described is a transcatheter mitral valve. The mitral valve includes a saddle-shaped annulus frame with two prongs extending therefrom. Two leaflets are attached with the frame and prongs to form a bi-leaflet mitral valve. The frame is collapsible to a collapsed configuration that allows for delivery and implantation at a mitral position. When at the mitral position, the mitral valve expands into an open configuration and is secured in place by a fixture, such as clamps that extend from the frame.

Abstract: The disclosure relates to method of processing three-dimensional images or volumetric datasets to determine a configuration of a medium or a rate of a change of the medium, wherein the method includes tracking changes of a field related to the medium to obtain a deformation or velocity field in three dimensions. In some cases, the field is a brightness field inherent to the medium or its motion. In other embodiments, the brightness field is from a tracking agent that includes floating particles detectable in the medium during flow of the medium.

Abstract: The disclosure relates to a method of automatically producing a three-dimensional (3D) segmentation of a heart chamber, the method comprising: obtaining data sets from cardiac magnetic resonance imaging (MRI) or ultrasound, generating a 3D segmentation of the heart chamber from the data sets using an active contour method, modifying the 3D segmentation by adding a plurality of intra-chamber structures; and identifying an enclosing myocardium using the 3D segmentation generated by the method.

Abstract: Disclosed is an imprinter device comprising an array of adjacent applicators that are arranged so that longitudinal axes of each of the adjacent applicators are parallel to each other, wherein the applicators are configured to make contact with and conform to a surface of a three dimensional (3D) object. In some embodiments, the applicators move independently of each other with respect to the surface of the object, and wherein the applicators are configured to apply a material over the object while in proximity to the surface of the object. Also disclosed are methods of conformal coating a surface of an object.

Abstract: A scaffold to form tissue membranes, comprising: at least one layer of mesh having a first side and a second side, the layer of mesh being either a woven wire metal mesh or a flat metal sheet that is acid-etched such that the layer of mesh includes a network of holes passing directly through the mesh from the first side to the second side; and at least one layer of cells at each side of the mesh enclosing the layer of mesh, such that the at least one layer of cells on the first side interacts with the at least one layer of cells on the second side through the network of holes to provide for structure integration.

Abstract: Described is a scaffold that is strong enough to resist forces that exist inside a body, while possessing biocompatible surfaces. The scaffold is formed of a layer of mesh (e.g., Stainless Steel or Nitinol) that is tightly enclosed by a multi-layer biological matrix. The biological matrix can include three layers, such a first layer (smooth muscle cells) formed directly on the metal mesh, a second layer (fibroblast/myofibroblast cells) formed on the first layer, and a third layer (endothelial cells) formed on the second layer. The scaffold can be formed to operate as a variety of tissues, such as a heart valve or a vascular graft. For example, the mesh and corresponding biological matrix can be formed as leaflets, such that the scaffold is operable as a tissue heart valve.

Abstract: First and second structures are connected by helical fibers. The orientation between the first and second structures are changed, and by doing so, the positions of the helical fibers are correspondingly changed. The position of change of the helical fibers can be used for a pumping effect, or to change some other fluidic characteristics. One other fluidic characteristic, for example, may use the movement of the helical fibers as a valve.

Abstract: In accordance with certain embodiments of the present disclosure, a nursing bottle is provided. The bottle includes a body having a hollow interior and defining an upper opening. The bottle further includes a nipple joined to the body and disposed over the upper opening. The bottle also includes a means for generating negative pressure within a portion of the interior of the body.

Abstract: Described is a scaffold that is strong enough to resist forces that exist inside a body, while possessing biocompatible surfaces. The scaffold is formed of a layer of mesh (e.g., Stainless Steel or Nitinol) that is tightly enclosed by a multi-layer biological matrix. The biological matrix can include three layers, such a first layer (smooth muscle cells) formed directly on the metal mesh, a second layer (fibroblast/myofibroblast cells) formed on the first layer, and a third layer (endothelial cells) formed on the second layer. The scaffold can be formed to operate as a variety of tissues, such as a heart valve or a vascular graft. For example, the mesh and corresponding biological matrix can be formed as leaflets, such that the scaffold is operable as a tissue heart valve.

Abstract: A tubular braided mesh scaffold for fabrication of heart valves is described. The tubular braided scaffold can be formed of a shape memory metal, such as Nitinol, and pinched or pressed to form a leaflet shape. When heat treated, the braided mesh scaffold holds and retains its valve-like shape.

Abstract: In accordance with one embodiment of the present disclosure, a prosthetic valve is provided. The prosthetic valve includes an annulus, a pair of leaflets, and a pair of support elements. The annulus has a generally saddle-shape formed by a movable pair of first portions separated from each other by a movable pair of second portions. The pair of leaflets extend from the annulus and are separated from each other by the pair of support elements. The first portions of the annulus and the second portions of the annulus are configured to move back and forth from being generally concave to being generally convex such that any movement of the first portions of the annulus occurs at generally the same time as any movement of the second portions of the annulus.

Abstract: Improved catheter devices for delivery, repositioning and/or percutaneous retrieval of percutaneously implanted heart valves are described, including a medical device handle that provides an array of features helpful in conducting a percutaneous heart valve implantation procedure while variously enabling radial expansion or contraction and/or lateral positioning control over the heart valve during the medical procedure.

Abstract: Embodiments described herein address the need for improved catheter devices for delivery, repositioning and/or percutaneous retrieval of the percutaneously implanted heart valves. One embodiment employs a plurality of spring-loaded arms releasably engaged with a stent frame for controlling expansion for valve deployment. Another embodiment employs a plurality of filaments passing through a distal end of a pusher sleeve and apertures in a self-expandable stent frame to control its state of deployment. With additional features, lateral positioning of the stent frame may also be controlled. Yet another embodiment includes plurality of outwardly biased arms held to complimentary stent frame features by overlying sheath segments. Still another embodiment integrates a visualization system in the subject delivery system. Variations on hardware and methods associated with the use of these embodiments are contemplated in addition to those shown and described.

Abstract: First and second structures are connected by helical fibers. The orientation between the first and second structures are changed, and by doing so, the positions of the helical fibers are correspondingly changed. The position of change of the helical fibers can be used for a pumping effect, or to change some other fluidic characteristics. One other fluidic characteristics, for example, may use the movement of the helical fibers as a valve.

Abstract: In accordance with one embodiment of the present disclosure, a method for deformation mapping of a tissue is provided. The method includes utilizing a device to measure transient three-dimensional deformations in a tissue sample. The device comprises a non-contacting, high-speed stereo imaging apparatus and a mechanism for digital image correlation. The method further includes identifying regions of the tissue that are prone to damage based upon the deformations.

Abstract: Described is a heart valve leaflet manufactured from a mesh material. The mesh material may have an ability to capture circulatory/stationary/migratory cells of the body to become biologically active. In some cases, the mesh material is coated with a bioactive material, such as a molecule that binds to a cell adhesion molecule (CAM), a growth factor, an extracellular matrix molecule, a subendothelial extracellular matrix molecule or a peptide. The mesh has a stiffness that is comparable to a native heart valve leaflet, such that it functionally mimics a native heart valve.

Abstract: The present invention relates to a heart valve and, more particularly, to a mold and process shaping and securing cells and tissue layers as they are grown in three-dimensions into a heart valve.

Abstract: An expandable stent that can transform between a collapsed state and an expanded state is described. The stent includes a first cross-sectional shape and a second cross-sectional shape. The first cross-sectional shape is a non-convex shape when the stent is in the collapsed state. Alternatively, the second cross-sectional shape is a convex shape when the stent is in an expanded state. The stent can be formed of super elastic Nitinol, which allows it to be shape set in the desired shape. Due to its shape setting properties and the non-convex cross-section, the stent is capable of dramatically reducing its cross-sectional radial profile which is beneficial in a variety of procedures.