Macrophage functional polarization (M1/M2) in response to varying fiber and pore dimensions of electrospun scaffolds.
about
How Biomaterials Can Influence Various Cell Types in the Repair and Regeneration of the Heart after Myocardial InfarctionThe Effect of Biomaterials Used for Tissue Regeneration Purposes on Polarization of MacrophagesInnate Immunity and Biomaterials at the Nexus: Friends or FoesPhysical and mechanical regulation of macrophage phenotype and functionBiomechanics and mechanobiology in functional tissue engineering.Biomineralized hydroxyapatite nanoclay composite scaffolds with polycaprolactone for stem cell-based bone tissue engineering.To cross-link or not to cross-link? Cross-linking associated foreign body response of collagen-based devices.Micro- and Nanopatterned Topographical Cues for Regulating Macrophage Cell Shape and Phenotype.Substrate modulus of 3D-printed scaffolds regulates the regenerative response in subcutaneous implants through the macrophage phenotype and Wnt signalingThe significance of macrophage phenotype in cancer and biomaterials.Monocytes and macrophages in tissue repair: Implications for immunoregenerative biomaterial designModulation of macrophage phenotype by cell shape.Adoptive transfer of M2 macrophages reduces neuropathic pain via opioid peptidesRegulation of Epithelial-to-Mesenchymal Transition Using Biomimetic Fibrous Scaffolds.In vivo remodelling of vascularizing engineered tissues.Rethinking regenerative medicine: a macrophage-centered approach.Impact of surface chemistry and topography on the function of antigen presenting cells.Delivery strategies to control inflammatory response: Modulating M1-M2 polarization in tissue engineering applications.Role of Bone Marrow Mononuclear Cell Seeding for Nanofiber Vascular Grafts.Biomaterials for Enhancing CNS Repair.Biomaterial strategies for generating therapeutic immune responses.Activation of Macrophages in Response to Biomaterials.Long-Term Functional Efficacy of a Novel Electrospun Poly(Glycerol Sebacate)-Based Arterial Graft in Mice.A hypothesis-driven parametric study of effects of polymeric scaffold properties on tissue engineered neovessel formation.Shear flow affects selective monocyte recruitment into MCP-1-loaded scaffolds.Galectin-1 promotes an M2 macrophage response to polydioxanone scaffolds.Topographical modulation of macrophage phenotype by shrink-film multi-scale wrinkles.CP and CP-PGN protect mice against MRSA infection by inducing M1 macrophages.Winner of the student award in the undergraduate category, 10th World Biomaterials Congress, May 17–22, 2016, Montreal QC, Canada: Evaluation of the tissue response to alginate encapsulated islets in an omentum pouch modelThe influence of surface modified poly(l-lactic acid) films on the differentiation of human monocytes into macrophages.Transparent Substrates Prepared From Different Amorphous Polymers Can Directly Modulate Primary Human B cell functions.Influence of porosity and pore shape on structural, mechanical and biological properties of poly ϵ-caprolactone electro-spun fibrous scaffolds.Transplantation of devitalized muscle scaffolds is insufficient for appreciable de novo muscle fiber regeneration after volumetric muscle loss injury.The effect of engineered nanotopography of electrospun microfibers on fiber rigidity and macrophage cytokine production.Enhancement of local bone remodeling in osteoporotic rabbits by biomimic multilayered structures on Ti6Al4V implants.Covalent immobilization of stem cell inducing/recruiting factor and heparin on cell-free small-diameter vascular graft for accelerated in situ tissue regeneration.Three-Layered PCL Grafts Promoted Vascular Regeneration in a Rabbit Carotid Artery Model.Biomaterial-driven in situ cardiovascular tissue engineering-a multi-disciplinary perspective.Localized Delivery of Cl-Amidine From Electrospun Polydioxanone Templates to Regulate Acute Neutrophil NETosis: A Preliminary Evaluation of the PAD4 Inhibitor for Tissue Engineering.Insert-based microfluidics for 3D cell culture with analysis.
P2860
Q26739723-62C47785-FACD-4DA0-966E-14DA61CC540DQ26767055-8A78741E-7607-4FFC-BFF7-FC065D20F2ADQ26801604-B9A81E9F-E20F-4F76-BA40-17A1BD335637Q27024278-5B88B95C-02CA-4341-864C-97CBCE5D6295Q33733279-4F537B55-52E7-49D1-B9E4-1E2FE93930C2Q35352327-3B0EF2BA-5BAA-4971-94D3-967E699DBCDAQ35641614-15DDD0C6-8C00-4357-A539-55A6C64FECBBQ36701904-DD07A84A-A626-4BE7-A7EE-17FF66728C55Q36840463-EBE18EA0-E85E-4956-B840-CE7E9BD80ADCQ36944484-779E7626-3607-414F-8B17-493E833DA523Q36981636-BF802051-9A53-45FB-A399-7B96B53B60EEQ37255982-FE46EE17-A114-47C3-A596-0D973C0C27EBQ37322206-E9E33CFA-1716-47C7-A80A-9E2157AC9DBBQ37351034-443E7E8F-F905-4B21-B9A0-9820926E0F35Q38258291-2887A701-1EB2-4ACF-AFCA-E67E25BB4891Q38269487-1B657978-4B0A-4364-8049-38D75199A519Q38556840-F96C3583-A1A9-4EE7-A9CE-D06D6C8529E5Q38700498-F9E9AC0A-F7CE-4F4B-AC91-897182471117Q38796045-976AD986-570D-4A87-8AF5-5EC2AE6D4B33Q38850744-AFDC77D6-1BAC-4770-95DF-A09A78ED067CQ39271088-B164A8C5-E11E-4A8E-800F-248E223D103CQ39271657-A797DD4D-17D8-440F-9E37-7936D1454536Q42034264-31425371-1481-4509-86AC-37BDA5CC2F55Q42551441-07826555-B050-407B-BB68-F7F0979997F6Q42987671-22DEC51F-BC1F-4338-9B00-F9BE9BB1A6D6Q45059919-A314F2CE-F217-4CA3-80DD-EE10BFF746AEQ46144471-0C05C7EB-3CAB-47C0-87C2-DA6985E5FFC2Q47136179-CFBD02C9-3326-4543-90CE-3969C1D57B89Q47758007-01C02D94-7359-4AB7-8458-8DA72BCCCF56Q48304976-21DECBEB-D020-4707-B042-6488E4F1ED33Q50249568-714EAF9B-665C-49ED-8D59-C4981BE89C2EQ50519340-8AC425C2-D0E7-44E8-9F4B-E1D63E0989FEQ50629701-FE869C84-5FC9-4310-90C7-7D3F25643566Q50911490-F9B6ACC6-9E14-424A-92C5-9A33210C2FEBQ51543058-15611D36-3CEF-4216-8DF2-0D3C0CA48BF6Q51543100-B4E525A3-FAFB-45C9-83A9-6250DE2526F7Q51566019-EABDB3B1-1851-44E5-BD85-78D40CDFCDB5Q52399862-AA28B8D5-53C9-4768-84FC-8DB546AAB770Q52592944-D99E8B0B-281C-4194-AB51-C163D1B51995Q52656909-44C4B767-6709-4E06-A8F3-35D59CAE5931
P2860
Macrophage functional polarization (M1/M2) in response to varying fiber and pore dimensions of electrospun scaffolds.
description
2013 nî lūn-bûn
@nan
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
2013年论文
@zh
2013年论文
@zh-cn
name
Macrophage functional polariza ...... ions of electrospun scaffolds.
@ast
Macrophage functional polariza ...... ions of electrospun scaffolds.
@en
type
label
Macrophage functional polariza ...... ions of electrospun scaffolds.
@ast
Macrophage functional polariza ...... ions of electrospun scaffolds.
@en
prefLabel
Macrophage functional polariza ...... ions of electrospun scaffolds.
@ast
Macrophage functional polariza ...... ions of electrospun scaffolds.
@en
P2093
P2860
P1433
P1476
Macrophage functional polariza ...... ions of electrospun scaffolds.
@en
P2093
Carole A Oskeritzian
Gary L Bowlin
John J Ryan
Koyal Garg
Nicholas A Pullen
P2860
P304
P356
10.1016/J.BIOMATERIALS.2013.02.065
P577
2013-03-17T00:00:00Z