Mechanisms of arterial graft healing. Rapid transmural capillary ingrowth provides a source of intimal endothelium and smooth muscle in porous PTFE prostheses.
about
In Vivo Application of Tissue-Engineered Veins Using Autologous Peripheral Whole Blood: A Proof of Concept Study.Biomaterials for vascular tissue engineeringManipulating the microvasculature and its microenvironment.Antithrombogenic modification of small-diameter microfibrous vascular grafts.Regional expression of the platelet-derived growth factor and its receptors in a primate graft model of vessel wall assembly.The soft keratoprosthesis.Platelet-derived growth factor activity and mRNA expression in healing vascular grafts in baboons. Association in vivo of platelet-derived growth factor mRNA and protein with cellular proliferationThe in vivo performance of small-caliber nanofibrous polyurethane vascular grafts.Bone morphogenetic protein 4: potential regulator of shear stress-induced graft neointimal atrophy.Accumulation and loss of extracellular matrix during shear stress-mediated intimal growth and regression in baboon vascular grafts.In vivo Quantification of the Effects of Radiation and Presence of Hair Follicle Pores on the Proliferation of Fibroblasts in an Acellular Human Dermis in a Dorsal Skinfold Chamber: Relevance for Tissue Reconstruction following Neoadjuvant Therapy.Cellular immunoisolation for islet transplantation by a novel dual porosity electrospun membrane.Biodegradation and biocompatibility of a degradable chitosan vascular prosthesisHistologic findings after in vivo placement of small intestine submucosal vascular grafts and saphenous vein grafts in the carotid artery in dogs.Endothelial regeneration. VI. Chronic nondenuding injury in baboon vascular grafts.Tissue-Engineered Small Diameter Arterial Vascular Grafts from Cell-Free Nanofiber PCL/Chitosan Scaffolds in a Sheep Model.Strategies and techniques to enhance the in situ endothelialization of small-diameter biodegradable polymeric vascular graftsInduction of vascular atrophy as a novel approach to treating restenosis. A reviewPolymeric materials for tissue engineering of arterial substitutes.Mucin covalently bonded to microfibers improves the patency of vascular grafts.ECM-based materials in cardiovascular applications: Inherent healing potential and augmentation of native regenerative processes.Accelerating in situ endothelialisation of cardiovascular bypass grafts.Perspectives in vascular surgery--biocompatible vascular surfaces: the past and future role of endothelial cells.Growing a living blood vessel: insights for the second hundred years.Immunochemical identification of human endothelial cells on the lining of a ventricular assist deviceProliferation of endothelial cell on polytetrafluoroethylene vascular graft materials carried VEGF gene plasmid.
P2860
Q30653426-6246E935-0ABD-4442-BAFB-4FA972F7256FQ33655808-61F21145-EBC6-4CAA-AC5E-7832CC3E73B6Q33893860-9A138768-6538-4DC6-8FE4-029EFB53F526Q33998552-C1262140-F87B-46F4-B12B-591BE852CE72Q34113116-C48D9CFD-9429-427C-8965-656312AE69AEQ34163557-6D875B0E-F3C4-4781-88E7-97E1F41B4222Q34180102-336FAFF3-F0F9-47AC-8844-FEEF6023C693Q34498621-BE9929B2-6069-4717-B188-AA65AB2BAE20Q34567420-9518FC38-F4A4-458B-BF87-F5C49A8FE865Q34576649-D5CCE9D0-9F8D-4E29-A4E6-336848A937AAQ35587736-E3EEC541-4DD4-4B57-83C2-7D412F2A66D3Q35606168-086C84D5-E9AE-4054-813C-88773061A037Q35660703-5DEC75BA-F346-4B30-86E3-BA2943A3B280Q35831442-995FF415-5CEC-4E51-9BCC-2CFA1262830DQ35836095-C0D587C8-5C11-4A69-8AED-04B334E952DEQ36088850-8199E139-EA08-4050-BA98-4B20DEF7701EQ36948086-9D3D1716-F6CD-41DD-9046-C175F9F78E9EQ36976632-5F1D45BD-3567-42D4-AFDA-DF2E7AF58242Q37271721-4C8DBAD4-3776-486B-8CE7-9F1DA201898AQ37419171-7CF4225E-ECB2-455B-BE0F-BB1F315AF1A3Q37670671-86297557-7C04-44F0-B396-3E5271A706D0Q38304670-9BEDD0CD-9ED9-47ED-A9BD-2153993BC723Q38957424-7FC4B0ED-98DF-4AA7-9366-8739ABECB021Q39251607-2BE17D0C-6B41-4EB2-A4A8-E220F784E684Q40486548-A7D0BA7F-67DB-4503-BE14-E48F5354F808Q42007729-E215A8C1-B86B-4280-A0DF-0EFB87C1D70B
P2860
Mechanisms of arterial graft healing. Rapid transmural capillary ingrowth provides a source of intimal endothelium and smooth muscle in porous PTFE prostheses.
description
1986 nî lūn-bûn
@nan
1986年の論文
@ja
1986年論文
@yue
1986年論文
@zh-hant
1986年論文
@zh-hk
1986年論文
@zh-mo
1986年論文
@zh-tw
1986年论文
@wuu
1986年论文
@zh
1986年论文
@zh-cn
name
Mechanisms of arterial graft h ...... cle in porous PTFE prostheses.
@ast
Mechanisms of arterial graft h ...... cle in porous PTFE prostheses.
@en
type
label
Mechanisms of arterial graft h ...... cle in porous PTFE prostheses.
@ast
Mechanisms of arterial graft h ...... cle in porous PTFE prostheses.
@en
prefLabel
Mechanisms of arterial graft h ...... cle in porous PTFE prostheses.
@ast
Mechanisms of arterial graft h ...... cle in porous PTFE prostheses.
@en
P2093
P2860
P1476
Mechanisms of arterial graft h ...... scle in porous PTFE prostheses
@en
P2093
A W Clowes
T R Kirkman
P2860
P304
P407
P577
1986-05-01T00:00:00Z