Abstract: The present invention provides a method of forming a three-dimensional structure of unidirectionally aligned cells. The method comprises providing a substrate with a microchannel. The microchannel is defined by at least a pair of opposing lateral walls and a base. In at least a portion of the microchannel the distance between the pair of opposing lateral walls is within the micrometer range. A first plurality of cells is seeded in the microchannel and the cells are allowed to proliferate up to at least a density of at least 90%. Thereby contact guidance cues are provided by the pair of opposing lateral walls of the microchannel, such that the cells align unidirectionally. Thereby a first layer of aligned cells is also formed at the base of the microchannel. A second plurality of cells is seeded in the microchannel, which already comprises a first layer of aligned cells.

Abstract: An implantable stent having surface features adapted to promote an organized growth pattern of infiltrating cells when implanted in a tubular organ is provided. The surface features comprise depressions, pores, projections, pleats, channels or grooves in the stent body and are designed to increase turbulence or stagnation in the flow of a liquid, such as blood through the stent, and/or to promote the growth of infiltrating cells in an organized pattern. Alternatively, the invention stent can be populated with living cells prior to implant and can be heatable from an external source of energy, thereby inducing production of therapeutic bioactive agents from ingrowing cells. The invention also provides an implantable heatable stent for transcutaneously monitoring the flow of fluid through a lumen into which the stent is implanted by measuring the rate at which the heated stent cools in response to blood flow when the source of heat is removed.

Abstract: The present invention provides intravascular prostheses and methods of production and use. An implantable device for treating a vascular disease or disorder includes an intravascular prosthesis containing an inhibitor of smooth muscle cell proliferation and a growth factor. The device can be coated with a biodegradable drug-eluting polymer that is impregnated with the inhibitor of smooth muscle cell proliferation and the growth factor. The device is useful for treating or preventing a vascular disease or disorder such as restenosis, by simultaneously inhibiting vessel blockage and enhancing recovery of the vessel wall following an intravascular intervention.

Abstract: Disclosed herein are vascular cell encapsulation devices that can deliver cell type(s) for the treatment of a disease or disorder.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote engraftment of a hybrid lower limb artery bypass vascular graft following implantation into a mammal's body by placing the hybrid lower limb artery bypass vascular graft in a system embodiment according to the invention prior to implantation of the hybrid lower limb artery bypass vascular graft into the mammal's body.

Abstract: The invention is directed to apparatus and methods for seeding an implantable medical device, such as a vascular prosthesis, with cells, such as endothelial cells. The invention supports techniques for seeding a luminal surface of the device with axial centrifugation. Cells are introduced in suspension into the lumen of the device, and the device is subjected to centrifugation around a longitudinal axis defined by the lumen. Axial centrifugation causes the cells to concentrate toward the luminal surface. Shortly after axial centrifugation, the seeded device can be presented for implantation in a patient.

Abstract: A modified polyurethane including a lipid substituent pendant from at least one urethane nitrogen and/or at least one carbon atom of the modified polyurethane, methods of preparing modified polyurethanes and the use thereof as an implantable biomaterial.

Abstract: Systems and methods are provided for controlling the diameter of a mammalian hybrid coronary bypass graft. The system includes a controller having at least one input for receiving information and feedback information and an output for outputting control signals, including at least one steady flow system control signal; and a pressure/flow loop subsystem coupled to the controller. The pressure/flow loop subsystem includes a specimen holder, an external flow loop system coupled to the specimen holder, a steady flow system, and an output for outputting the feedback information. The pressure/flow loop subsystem receives the control signals and is capable of adjusting a diameter of a specimen in accordance with the control signals, when the specimen holder contains the specimen.

Abstract: A method of preparing an implantable biological device having a first tissue part and a second tissue part includes exposing the first tissue part to a first preparation method and preventing exposure of the second biological tissue part to the first preparation method. Preventing exposure of the second biological tissue part to the first preparation method may be achieved using an embedding technique, a coating technique, a covering technique, or physical isolation. The method may further include exposing the second tissue part to a second preparation method and preventing exposure of the first biological tissue part to the second preparation method. An apparatus for preparing an implantable biologic device includes an enclosure having first and second chambers separated by a partition member wherein a substantial portion of the first tissue part is within the first chamber and a substantial portion of the second tissue part is within the second chamber.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid hemodialysis access graft or a hybrid femoral artery bypass graft by placing the hybrid hemodialysis access graft or the hybrid femoral artery bypass graft in a system embodiment according to the invention under conditions effective to promote endothelial cells to form a confluent monolayer on the surface of the hybrid graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid lower limb artery bypass vascular graft by placing the hybrid lower limb artery bypass vascular graft in a system embodiment according to the invention under conditions effective to promote stem cells to form a confluent monolayer on the hybrid vascular graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems include a pressure/flow system having an external flow loop system for generating a flow loop, a specimen having a region arranged in the flow loop, and a controller, where the pressure/flow system is capable of adjusting at least two dynamic conditions at the region or a diameter of the specimen. Embodiments of methods can prepare a hybrid carotid bypass graft intended for implantation into a mammal by placing the hybrid carotid bypass graft in a system embodiment according to the invention prior to implantation of the hybrid carotid bypass graft into the mammal.

Abstract: The present invention relates to a process for manufacturing a porous coating with structures in the micro or nano-size domain characterized by the following steps: -providing a support having a surface, -depositing on said surface one mono-layer of temporary particles, -depositing a coating on said temporary particles in such a way that the thickness of said coating is less than the particle diameter, -eliminating said temporary particles and thereby obtaining a porous coating, the pores of said coating corresponding to the spaces previously occupied by the temporary particles and at least a part of the pores communicating with the external environment, -applying a coating fixation step, characterized by the fact that said temporary particles are deposited on said surface in such a way that, after particle deposition, more than 50% of the temporary particles are in contact with a maximum of two adjacent particles and otherwise are separated by an empty space.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holders where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid hemodialysis access graft or a hybrid femoral artery bypass graft by placing the hybrid hemodialysis access graft or the hybrid femoral artery bypass graft in a system embodiment according to the invention under conditions effective to promote stem cells to form a confluent monolayer on the hybrid graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote engraftment of a hybrid hemodialysis access graft or a hybrid femoral artery bypass graft following implantation into a mammal's body by placing the hybrid hemodialysis access graft or the hybrid femoral artery bypass graft in a system embodiment according to the invention prior to implantation of the hybrid graft into the mammal's body.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid lower limb artery bypass vascular graft by placing the hybrid lower limb artery bypass vascular graft in a system embodiment according to the invention under conditions effective to promote endothelial cells to form a confluent monolayer on the surface of the hybrid vascular graft.

Abstract: A method of yielding a functional human hybrid hemodialysis access graft is provided. The method includes conditioning a hybrid synthetic tubular structure having stem cells and/or endothelial cells on at least one surface to yield the functional human hybrid hemodialysis access graft. Specifically, the method includes placing the hybrid synthetic tubular structure in a system capable of producing three dimensional dynamic conditions for a sufficient time to yield said functional human hybrid hemodialysis access graft.

Abstract: A method of yielding a functional human hybrid coronary bypass graft is provided. The method includes conditioning a hybrid synthetic tubular structure having stem cells and/or endothelial cells on at least one surface to yield the functional human hybrid coronary bypass graft. Specifically, the method includes placing the hybrid synthetic tubular structure in a system capable of producing three dimensional dynamic conditions for a sufficient time to yield said functional human hybrid coronary bypass graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid carotid bypass vascular graft by placing the hybrid carotid bypass vascular graft in a system embodiment according to the invention under conditions effective to promote stem cells to form a confluent monolayer on the hybrid vascular graft.

Abstract: A cellular stent carries living therapeutic cellular material for implantation into a human or animal body and allows either localized or systemic delivery of the therapeutic products, while promoting engraftment, either on a tissue surface or its interior. The cells are contained within wells in the stent that are enclosed by inner and outer membranes that seal the cellular material within the stent until it is to be released. The outer membrane is preferably in the form of a thin, hard plastic sheet having a plurality of score lines, perforations, or other lines or weakening provided therein. The membrane may be embedded in a softer perimetral mount which retains it in position until the seal is to be broken. Rupture of the outer membrane ensures penetration of the cells into the interior of tissue or an organ in which the stent is implanted.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can coat a hybrid hemodialysis access graft or a hybrid femoral artery bypass graft with a confluent monolayer of endothelial cells by immobilizing a plurality of endothelial cells on the hybrid hemodialysis access graft or the hybrid femoral artery bypass graft and placing the hybrid graft in a system embodiment according to the invention under conditions effective to promote the endothelial cells to form a confluent monolayer on the hybrid graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can prepare a hybrid hemodialysis access graft or a hybrid femoral artery bypass graft intended for implantation into a mammal by placing the hybrid graft in a system embodiment according to the invention prior to implantation of the hybrid graft into the mammal.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid carotid bypass vascular graft by placing the hybrid carotid bypass vascular graft in a system embodiment according to the invention under conditions effective to promote stem cells to differentiate into endothelial cells on a surface of the hybrid carotid bypass vascular graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can coat a hybrid lower limb artery bypass vascular graft with a confluent monolayer of endothelial cells by immobilizing a plurality of endothelial cells on the hybrid lower limb artery bypass vascular graft and placing the hybrid lower limb artery bypass vascular graft in a system embodiment according to the invention under conditions effective to promote the endothelial cells to form a confluent monolayer on the surface of the hybrid vascular graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote engraftment of a hybrid carotid bypass vascular graft following implantation into a mammal's body by placing the hybrid carotid bypass vascular graft in a system embodiment according to the invention prior to implantation of the hybrid carotid bypass vascular graft into the mammal's body.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can promote endothelialization of a hybrid lower limb artery bypass vascular graft by placing the hybrid lower limb artery bypass vascular graft in a system embodiment according to the invention under conditions effective to promote stem cells to differentiate into endothelial cells on a surface of the hybrid lower limb artery bypass vascular graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can prepare a hybrid lower limb artery bypass vascular graft intended for implantation into a mammal by placing the hybrid lower limb artery bypass vascular graft in a system embodiment according to the invention prior to implantation of the hybrid lower limb artery bypass vascular graft into the mammal.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can coat a hybrid graft with a confluent monolayer of endothelial cells by immobilizing stem cells on a hybrid carotid bypass vascular graft, placing the hybrid graft in a system embodiment according to the invention under conditions effective to promote the stem cells to form a confluent monolayer on the surface of the hybrid vascular graft and in an environment to promote the stem cells to differentiate into endothelial cells.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holder, where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in die specimen holder. Embodiments of methods can promote endothelialization of a hybrid carotid bypass vascular graft by placing the hybrid carotid bypass vascular graft in a system embodiment according to the invention under conditions effective to promote endothelial cells to form a confluent monolayer on the surface of the hybrid vascular graft.

Abstract: Hybrid synthetic grafts and embodiments of systems and methods for producing hybrid vascular grafts that can yield implantable grafts that combine synthetic grafts with living cells. Embodiments of systems can include a pressure/flow loop subsystem having an external flow loop system coupled to a specimen holders where the pressure/flow loop subsystem is capable of adjusting at least two dynamic conditions in the specimen holder or a diameter of a specimen in the specimen holder. Embodiments of methods can coat a hybrid carotid bypass vascular graft with a confluent monolayer of endothelial cells by immobilizing a plurality of endothelial cells on the hybrid carotid bypass vascular graft and placing the hybrid carotid bypass vascular graft in a system embodiment according to the invention under conditions effective to promote the endothelial cells to form a confluent monolayer on the surface of the hybrid vascular graft.

Abstract: Methods for ameliorating stent graft migration and endoleak using treatment site-specific platelet gel compositions in combination with stent grafts are disclosed. Also disclosed are platelet gel compositions directly to treatment sites before, during or after stent graft implantation. Additional embodiments include medical devices having platelet gel coatings and/or platelet gel delivery devices useful for treating aneurysms.

Abstract: Disclosed herein are materials and methods suitable for treating and managing plaque disease, including vulnerable plaque. An implantable material comprising cells, such as but not limited to endothelial cells, and a biocompatible matrix can reduce progression or deterioration of a plaque-associated lesion situated on the interior lumen of said blood vessel. The implantable material is implanted directly on an exterior surface of a blood vessel at or adjacent or in the vicinity of the site of a lesion on an interior lumen. Alternatively, the implantable material is deposited on an exterior surface at or adjacent or in the vicinity of the site of a lesion on an interior lumen by an intraluminal delivery device which traverses or penetrates the vessel wall or by a percutaneous delivery device which enters the perivascular space. Both modes of administration can be preceded by or coincident with an imaging step.

Abstract: The present invention is directed toward a stent having a plurality of axially spaced serpentine bands, each serpentine band having an axis circumferentially oriented around the longitudinal axis of the stent. The serpentine bands have a plurality of struts spaced along the axis of the serpentine band forming alternating peaks and troughs. The serpentine bands are interconnected via a plurality of interconnecting struts to form a plurality of cells defined by axially adjacent serpentine bands and circumferentially adjacent interconnecting struts. When the stent is in its unexpanded state, each serpentine comprises a plurality of slits, each slit being non-linear and continuous from a first end to a second end and being formed in at least a portion of each of three consecutively connected struts. Upon expansion of the stent to its expanded state, each of the slits expands in size to form an intra-columnar cell (ICC).

Abstract: A medical device having an elongate flexible tube extending between a proximal end and a a distal end. The device has a lumen extending between the proximal and distal ends. The lumen contains therapeutic cells and is sized to receive a plunger. The plunger is movable through at least a portion of the lumen. The device further includes an actuator at the proximal end of the elongate flexible tube, and a delivery member at the distal end of the elongate flexible tube.

Abstract: An apparatus and method to treat vulnerable plaque. In one embodiment, the apparatus has a medical device to treat an occlusive plaque, and is also adapted to release a biologically active agent to treat vulnerable plaque located downstream from the occlusive plaque. In an alternative embodiment, the apparatus has an expandable tube attached to the inner surface of a stent, and a layer of endothelial cells seeded on the inner surface of the expandable tube. The expandable tube shields a vulnerable plaque from a body lumen.

Abstract: An implantable stent having surface features adapted to promote an organized growth pattern of infiltrating cells when implanted in a tubular organ is provided. The surface features comprise depressions, pores, projections, pleats, channels or grooves in the stent body and are designed to increase turbulence or stagnation in the flow of a liquid, such as blood through the stent, and/or to promote the growth of infiltrating cells in an organized pattern. Alternatively, the invention stent can be populated with living cells prior to implant and can be heatable from an external source of energy, thereby inducing production of therapeutic bioactive agents from ingrowing cells. The invention also provides an implantable heatable stent for transcutaneously monitoring the flow of fluid through a lumen into which the stent is implanted by measuring the rate at which the heated stent cools in response to blood flow when the source of heat is removed.

Abstract: Processes for producing a tissue graft comprising acellularizing or devitalizing a tubular tissue to produce a tissue matrix. The tissue matrix is then populated with at least some viable cells. The processing and the populating steps are performed in a closed system, such as a bioreactor. Tissue grafts produced using the inventive processes may be capable of withstanding physiological stress and strain conditions present at a site into which the tissue graft is implanted.

Abstract: The present invention relates to artificial vascular grafts, methods for manufacturing and uses for them. The grafts are coated on their lumen with UP50. The grafts comprise an inner surface on which cells genetically altered to express or over-express one or more cell adhesion factors and one or more cell proliferation factors are seeded and cultured.

Abstract: Disclosed is a smooth muscle cell specific promoter, the SM22? gene promoter as well as the murine cDNA and genomic SM22? nucleic acid sequences. Also disclosed are methods of preventing restenosis following balloon angioplasty and methods of treating asthma based on inhibition of smooth muscle cell proliferation by expressing cell cycle control genes, or contraction inhibiting peptides in smooth muscle cells, under the control of the SM22? promoter.

Abstract: An improved prosthetic graft for the bypass, replacement or repair of vessels and organs that are in contact with blood flow is disclosed. The prosthetic graft includes a porous prosthetic implant and adherent cells adhered to the outer surface of the implant. The adherent cells are transfected with at least one recombinant nucleic acid molecule encoding at least one protein that enhances patency of the graft. The prosthetic graft has a long-term patency and success rate that is superior to other previously described prosthetic grafts designed for such use. Also disclosed are methods of making and using such a graft.

Abstract: The invention is a tissue engineered blood vessel (TEBV) made from a cultured fibroblast sheet rolled into a multilayer vessel which has sufficient burst strength to withstand physiological blood pressure without the inclusion of smooth muscle cells or synthetic scaffolding. The TEBV is made in a bioreactor having an enclosed chamber, a sheet growth module, a rollable mandrel, and a clamp for holding the sheet to the mandrel for rolling.

Abstract: A covered stent assembly comprising a tubular, expandable stent having a metallic framework covered with a cylinder of biocompatible, non-thrombogenic expandable material, such as heterologous tissue. In a preferred embodiment, the metallic framework is positioned coaxially within a cylinder of bovine pericardial tissue. A catheter may be used to deliver the stent assembly to a desired region in the lumen of a patient. The metallic framework is then expanded to seat the assembly within the lumen.

Abstract: A medical implant made from multiple layers of non-synthetic, natural tissues is provided. The medical device includes openings that extend radially through the wall of the medical implant. One advantage of the medical implant is that a synthetic support structure is not needed. As a result, problems associated with implanting a foreign material into a body may be avoided.

Abstract: The invention concerns a device and methods for providing implants, cells or tissues, for example for grafts or in vitro research cultures, of tissue engineering or cellular therapy. The invention is particularly adapted to produce, in sufficient amount, specific cell populations with high proliferation and/or differentiation potential, adapted for use in tissue engineering, in repair surgery or therapy, particularly for humans. The invention also concerns a method for preparing such a device and its uses, in particular for treating tissue loss, and kits, tranplants, tissues or biological preparations.

Abstract: Implantable medical devices comprising a support frame and a graft member attached to the support frame. The support frame can define one or more structural features that substantially prevent migration of the graft member along the support frame.

Abstract: The present invention relates to a method for promoting blood vessel formation in tissues and organs. In particular, the method relates to implantation or attachment of an engineered three-dimensional stromal tissue to promote endothelialization and angiogenesis in the heart and related tissues. The three-dimensional stromal tissue of the present invention may be used in a variety of applications including, but not limited to, promoting repair of and regeneration of damaged cardiac muscle, promoting vascularization and healing during cardiac surgery, promoting blood vessel formation at anastomosis sites, and promoting vascularization and repair of damaged skeletal muscle, smooth muscle or connective tissue.

Abstract: The present invention encompasses methods and apparatus for minimizing the risks inherent in endovascular grafting for blood vessel therapy and repair. The invention involves delivering adult stem cells, embryonic stem cells, progenitor cells, fibroblasts, or smooth muscle cells to the diseased blood vessel.

Abstract: An improved prosthetic graft for the bypass, replacement or repair of vessels and organs that are in contact with blood flow is disclosed. The prosthetic graft includes a porous prosthetic implant and adherent cells adhered to the outer surface of the implant. The adherent cells are transfected with at least one recombinant nucleic acid molecule encoding at least one protein that enhances patency of the graft. The prosthetic graft has a long-term patency and success rate that is superior to other previously described prosthetic grafts designed for such use. Also disclosed are methods of making and using such a graft.

Abstract: An improved method of implanting cells in the body of a patient includes positioning viable cells on a support structure. One or more blood vessels may be connected with the support structure to provide a flow of blood through the support structure. A support structure may be positioned at any desired location in a patient's body. The support structure may be configured to replace an entire organ or a portion of an organ. An organ or portion of an organ may be removed from a body cells and/or other tissue is removed to leave a collagen matrix support structure having a configuration corresponding to the configuration of the organ or portion of an organ. Alternatively, a synthetic support structure may be formed. The synthetic support structure may have a configuration corresponding to a configuration of an entire organ or only a portion of an organ.

Abstract: The present invention is directed to novel, less invasive and improved methods of tissue-engineering of constructs that require an endothelial surface such as blood vessels and heart valves. The constructs of the present invention possess long-term patency. The method of the present invention is particularly suited for making small diameter vessels to replace clogged or damaged coronary blood vessels, for making trileaflet heart valve conduits to replace damaged or malformed pulmonic and aortic valves, and for other vascular structures that require an endothelial surface.