The periosteum as a cellular source for functional tissue engineering.
about
Bone repair with skeletal stem cells: rationale, progress to date and clinical applicationConcise review: the periosteum: tapping into a reservoir of clinically useful progenitor cellsAnchoring structure of the calvarial periosteum revealed by focused ion beam/scanning electron microscope tomography.Stem Cells of Dental Origin: Current Research Trends and Key Milestones towards Clinical ApplicationSurgical membranes as directional delivery devices to generate tissue: testing in an ovine critical sized defect modelImaging and quantifying solute transport across periosteum: implications for muscle-bone crosstalk.Myoconductive and osteoinductive free-standing polysaccharide membranes.Induction of granulation tissue for the secretion of growth factors and the promotion of bone defect repair.Association between in vivo bone formation and ex vivo migratory capacity of human bone marrow stromal cellsMechanisms for redox actions of nicotine and glutathione in cell culture, relevant to periodontitisElucidating multiscale periosteal mechanobiology: a key to unlocking the smart properties and regenerative capacity of the periosteum?Effective Spatial Separation of PC12 and NIH3T3 Cells by the Microgrooved Surface of Biocompatible Polymer Substrates.Role of Cartilage Forming Cells in Regenerative Medicine for Cartilage Repair.Regenerative Dentistry: Animal Model for Regenerative Endodontology.Biofabrication and Bone Tissue Regeneration: Cell Source, Approaches, and Challenges.Bioreactor design for tendon/ligament engineering.Differences in the developmental origins of the periosteum may influence bone healing.Maturation of cortical bone suppresses periosteal osteoprogenitor proliferation in a paracrine manner.Periosteum: a highly underrated tool in dentistry.Bioactive glass/polymer composite scaffolds mimicking bone tissue.Anabolic Actions of the Regenerative Agent Enamel Matrix Derivative (EMD) in Oral Periosteal Fibroblasts and MG 63 Osteoblasts, Modulation by Nicotine and Glutathione in a Redox EnvironmentGeneration of osteogenic construct using periosteal-derived osteoblasts and polydioxanone/pluronic F127 scaffold with periosteal-derived CD146 positive endothelial-like cells.MSCA-1/TNAP selection of human jaw periosteal cells improves their mineralization capacity.Net change in periosteal strain during stance shift loading after surgery correlates to rapid de novo bone generation in critically sized defects.Hydroxyapatite/collagen nanocomposite-coated titanium rod for achieving rapid osseointegration onto bone surface.Human periosteum-derived stem cells for tissue engineering applications: the role of VEGF.Bone repair by cell-seeded 3D-bioplotted composite scaffolds made of collagen treated tricalciumphosphate or tricalciumphosphate-chitosan-collagen hydrogel or PLGA in ovine critical-sized calvarial defects.Engineering vascularized bone: osteogenic and proangiogenic potential of murine periosteal cells.The Role of Bone Marrow-Derived Cells during Ectopic Bone Formation of Mouse Femoral Muscle in GFP Mouse Bone Marrow Transplantation Model.Periosteum, bone's “smart” bounding membrane, exhibits direction-dependent permeability
P2860
Q26744340-F4425D9E-9F2C-4997-99B1-C58980515833Q26859064-C2DEC232-5D99-44F8-825D-BF86C62E8352Q27304706-7E6F8AC1-25D8-469B-8BF7-C3FE70BFF37DQ28073659-A372EC82-CF91-49C3-A911-D6181B17A732Q28741600-D7CB2707-8C8E-4349-A456-6916A7748FEAQ35188081-7628A4BD-49B6-4204-BDD8-C33AAE2C60D5Q35965765-ADBCAE57-8DBC-4E96-B58F-793E6AA3D4D6Q36071036-39190A53-A756-4B2F-9A3E-85382BF4D5BEQ36141009-0EEF0001-C5CD-4508-94F2-9E5BA9E4FD90Q36147404-CE4677AD-7175-454F-95F4-C07349315CB9Q36661236-F6C020E3-BFBE-4740-8705-7C4F9B1E8068Q37045986-D22DA0C8-D935-4E26-8E3C-E441369D1564Q37173495-2FFC110C-502A-48B0-84EB-8FDFD382DCD7Q37365227-C7BB42BB-7CD9-48D2-91C7-7830F40D0412Q37716810-ED3F49A9-96EC-47D4-A487-D336FE4617C1Q38052609-7B6A1B1C-3D9C-424C-BCC4-F5EA78A1C4F6Q38304160-43B7CF9C-926B-405F-A83A-34A1A019AE47Q38412794-053B53FF-CE8F-474F-B0A2-18C16363BEC5Q38559622-81BD5D12-B7AC-4770-9825-ED29770A15D8Q39344572-F18F52A1-109F-448A-B102-B96E72F540DCQ39873227-C140FEFC-882C-4678-AB89-56E3EDC4232CQ42512412-3D06C761-C5ED-4FDB-AAD3-740D00976106Q42759624-2A69D022-8787-4F5D-AF25-01A915F5957DQ42969433-D728BABC-D4A3-438D-BE7F-84CD8FC233C5Q44842839-087CA866-17C5-49E4-B70F-4136444BF1A3Q50578422-74E80242-E24D-45D6-9496-1EEE11BAC1CEQ52905030-B761C624-B5EE-449A-961C-0656D42E590CQ53150082-284C532C-DE37-43CD-8C39-AAC44145157DQ55618316-CC798BD9-67B0-467A-B7CD-1B94A28650E7Q58924064-C438B716-2F81-48EA-B90E-1466E8EA6671
P2860
The periosteum as a cellular source for functional tissue engineering.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on September 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
The periosteum as a cellular source for functional tissue engineering.
@en
The periosteum as a cellular source for functional tissue engineering.
@nl
type
label
The periosteum as a cellular source for functional tissue engineering.
@en
The periosteum as a cellular source for functional tissue engineering.
@nl
prefLabel
The periosteum as a cellular source for functional tissue engineering.
@en
The periosteum as a cellular source for functional tissue engineering.
@nl
P2093
P2860
P1476
The periosteum as a cellular source for functional tissue engineering.
@en
P2093
Christopher R Jacobs
Dennis R Carter
Emily J Arnsdorf
Luis M Jones
P2860
P304
P356
10.1089/TEN.TEA.2008.0244
P577
2009-09-01T00:00:00Z