{"search_session":{},"preferences":{"l":"en","queryLanguage":"en"},"patentId":"US_7011623_B2","frontPageModel":{"patentViewModel":{"ref":{"entityRefType":"PATENT","entityRefId":"159-633-873-224-158"},"entityMetadata":{"linkedIds":{"empty":true},"tags":[],"collections":[{"id":8906,"type":"PATENT","title":"Univ Pennsylvania Patent Portfolio","description":"","access":"OPEN_ACCESS","displayAvatar":true,"attested":false,"itemCount":24238,"tags":[],"user":{"id":91044780,"username":"Cambialens","firstName":"","lastName":"","created":"2015-05-04T00:55:26.000Z","displayName":"Cambialens","preferences":"{\"usage\":\"public\",\"beta\":false}","accountType":"PERSONAL","isOauthOnly":false},"notes":[{"id":8221,"type":"COLLECTION","user":{"id":91044780,"username":"Cambialens","firstName":"","lastName":"","created":"2015-05-04T00:55:26.000Z","displayName":"Cambialens","preferences":"{\"usage\":\"public\",\"beta\":false}","accountType":"PERSONAL","isOauthOnly":false},"text":"
Search applicants and owners= \"Univ Pennsylvania\", \"Pennsylvania Univ\", \"Univ Penns*\", \"Penn* Univ\", \"University of Pennsylvania\", \"Pennsylvania University\".
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Search applicants and owners= \"Univ Pennsylvania\", \"Pennsylvania Univ\", \"Univ Penns*\", \"Penn* Univ\", \"University of Pennsylvania\", \"Pennsylvania University\".
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excising the blood vessel from its native site, and\n
subjecting the excised vessel to a precisely controlled, and real-time monitored, ex vivo mechanical environment for a time sufficient to remodel the vessel by increasing the diameter, length, or wall thickness of the vessel, or any combination thereof."],"number":1,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 1, wherein the excised vessel is a small artery or a vein."],"number":2,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 1, further comprising applying pressure, shear, and strain to the vessel under controlled conditions within the mechanical environment, wherein transmural pressure drop regulates wall thickness, longitudinal tension regulates length, and flow-induced shear stress regulates inner diameter of the remodeled vessel."],"number":3,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 3, further comprising controlling the mechanical environment by an ex vivo perfusion system, and supplying the mechanical environment with a traditional cell or organ culture system, thereby providing regulated temperature, pO2, pCO2 and nutrients."],"number":4,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 1, wherein length of the remodeled vessel is increased at least 100% over its native length when excised, and wherein more than 50% of the increased length is retained after recoil when the remodeled vessel is removed from the controlled mechanical environment."],"number":5,"annotation":false,"title":false,"claim":true},{"lines":["A method of physically remodeling a small blood vessel to be used in vivo as a vascular graft in a patient in need of such a graft, comprising the steps of:\n
excising the blood vessel from its native site; and\n
subjecting the excised vessel to a controlled, real-time monitored, ex vivo mechanical environment for a time sufficient to increase diameter, length, or wall thickness of the vessel, or any combination thereof;\n
removing the remodeled vessel from the ex vivo mechanical environment; and\n
surgically inserting the remodeled vessel in vivo as a vascular graft (artery or vein) into the patient."],"number":6,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 6, wherein the excised vessel is a small artery or a vein."],"number":7,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 6, wherein the excised vessel is autologous to the patient."],"number":8,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 6, further comprising applying pressure, shear, and strain to the vessel under controlled conditions within the mechanical environment, wherein transmural pressure drop regulates wall thickness, longitudinal tension regulates length, and flow-induced shear stress regulates inner diameter of the remodeled vessel."],"number":9,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 6, further comprising controlling the mechanical environment is controlled by an ex vivo perfusion system, and supplying the mechanical environment with a traditional cell or organ culture system, thereby providing regulated temperature, pO2, pCO2 and nutrients."],"number":10,"annotation":false,"title":false,"claim":true},{"lines":["The method of claim 6, wherein length of the remodeled vessel is increased at least 100% over its native length when excised, and wherein more than 50% of the increased length is retained after recoil when the remodeled vessel is removed from the controlled mechanical environment."],"number":11,"annotation":false,"title":false,"claim":true},{"lines":["An ex vivo perfusion system for exposing one or more viable, excised, small blood vessels, which is/are arterial or venous, to precisely controlled flow and pressure regimes, wherein the system comprises:\n
a pump means, which when activated, continuously pushes fluid through the system;\n
a housing means, comprising a medium-filled chamber, within which chamber the excised vessel is housed, and the excised vessel is cannulated with two sliding tubes that can be moved apart in a controlled manner to expand the length of the vessel, wherein when activated, the chamber housing the vessel is perfused with cell culture medium supplemented with serum and antibiotics, and wherein temperature, pH, pO2, pCO2, and nutrients are maintained at levels sufficient to maintain the viability of the vessel;\n
a reservoir within which the culture medium is pooled, having a gas exchange port, which permits gas exchange within the medium;\n
a controller means to control pressure within the chamber housing the excised blood vessel;\n
an in-line probe means to measure and report pressure within the system;\n
a data measurement means attached to the in-line probe means for digitizingthe measured pressure data; and\n
a computer node attached to the data measurement means to record, analyze and store the digital data."],"number":12,"annotation":false,"title":false,"claim":true},{"lines":["The ex vivo perfusion system of claim 12, wherein the system further comprises:\n
as the pump means, a pulsatile blood pump, which when activated, continuously pushes fluid through the system;\n
as the housing means, an enclosed Plexiglas cylinder, which forms the housing comprising a medium-filled chamber, cannulated on each end, within which chamber the excised vessel is cannulated with two sliding stainless-steel tubes, wherein the chamber housing the vessel is perfused with cell culture medium supplemented with serum and antibiotics, and wherein temperature, pH, pO2, pCO2, and nutrients are maintained at levels sufficient to maintain the viability of the vessel;\n
a reservoir within which the culture medium is pooled, having a gas exchange port, which permits gas exchange within the medium, before the medium is returned to the pump for circulation within the system;\n
as a controller, a needle valve controller at either end of the chamber to control pressure within the chamber housing the excised blood vessel;\n
as an in-line probe, at least one in-line probe to measure pressure within the system at a rate of approximately 250 times per second, wherein the data is reported in analog;\n
as a data measurement means, a data measurement module attached to the in-line probe(s) for digitizing the analog pressure."],"number":13,"annotation":false,"title":false,"claim":true},{"lines":["The system of claim 12, wherein when multiple excised small blood vessels are exposed to precisely controlled flow and pressure regimes, the vessels are run in parallel, wherein each vessel is contained within its own housing, having corresponding chambers and needle valves."],"number":14,"annotation":false,"title":false,"claim":true},{"lines":["The system of claim 12, wherein ports on the Plexiglas cylinder allow the exchange of medium and nutrients, fluid overflow and air/CO2 discharge."],"number":15,"annotation":false,"title":false,"claim":true},{"lines":["The system of claim 12, wherein improved control of the mechanical environment provides localized intravascular and extravascular pressure measurement and control, providing real time monitoring of vessel remodeling."],"number":16,"annotation":false,"title":false,"claim":true},{"lines":["The system of claim 13, wherein the two sliding stainless-steel tubes slide independently of the rest of the unit to control vessel strain."],"number":17,"annotation":false,"title":false,"claim":true},{"lines":["A method of physically remodeling an excised small blood vessel, said method comprising\n
cannulating each end of the excised vessel to two sliding stainless-steel tubes that are cannulated on each end and that are contained within an enclosed medium-filled chamber,\n
gradually extending the vessel without rupture by slowly extending the stainless steel tubes on which the vessel is mounted within the enclosed media filled chamber, while\n
maintaining the viability of the vessel by perfusing the vessel under precisely controlled flow and pressure regimes with cell culture medium supplemented with serum and antibiotics, and wherein temperature, pH, pO2, pCO2, and nutrients are maintained at levels sufficient to maintain the viability of the vessel."],"number":18,"annotation":false,"title":false,"claim":true}]}},"filters":{"npl":[],"notNpl":[],"applicant":[],"notApplicant":[],"inventor":[],"notInventor":[],"owner":[],"notOwner":[],"tags":[],"dates":[],"types":[],"notTypes":[],"j":[],"notJ":[],"fj":[],"notFj":[],"classIpcr":[],"notClassIpcr":[],"classNat":[],"notClassNat":[],"classCpc":[],"notClassCpc":[],"so":[],"notSo":[],"sat":[]},"sequenceFilters":{"s":"SEQIDNO","d":"ASCENDING","p":0,"n":10,"sp":[],"si":[],"len":[],"t":[],"loc":[]}}