about
Cells and biomaterials in cartilage tissue engineering.Physical stimulation of chondrogenic cells in vitro: a reviewHydrogels in calcium phosphate moldable and injectable bone substitutes: Sticky excipients or advanced 3-D carriers?Antimicrobial delivery systems for local infection prophylaxis in orthopedic- and trauma surgery.Three-dimensional spheroids of adipose-derived mesenchymal stem cells are potent initiators of blood vessel formation in porous polyurethane scaffolds.Injectable thermoreversible hyaluronan-based hydrogels for nucleus pulposus cell encapsulation.Thiol-containing degradable poly(thiourethane-urethane)s for tissue engineering.Farnesol-modified biodegradable polyurethanes for cartilage tissue engineering.Self-Healing Dynamic Hydrogel as Injectable Shock-Absorbing Artificial Nucleus Pulposus.The effect of human osteoblasts on proliferation and neo-vessel formation of human umbilical vein endothelial cells in a long-term 3D co-culture on polyurethane scaffolds.Cross-Linking Chemistry of Tyramine-Modified Hyaluronan Hydrogels Alters Mesenchymal Stem Cell Early Attachment and Behavior.Short-term cultivation of in situ prevascularized tissue constructs accelerates inosculation of their preformed microvascular networks after implantation into the host tissue.Two-step labeling of Staphylococcus aureus with Lysostaphin-Azide and DIBO-Alexa using click chemistry.A drug eluting poly(trimethylene carbonate)/poly(lactic acid)-reinforced nanocomposite for the functional delivery of osteogenic moleculesLessons to be learned and future directions for intervertebral disc biomaterialsA papain-induced disc degeneration model for the assessment of thermo-reversible hydrogel-cells therapeutic approachIn vitro apatite forming ability of type I collagen hydrogels containing bioactive glass and silica sol-gel particlesSingle step synthesis and characterization of thermoresponsive hyaluronan hydrogelsTailoring Thermoreversible Hyaluronan Hydrogels by “Click” Chemistry and RAFT Polymerization for Cell and Drug TherapyEvaluation of a new press-fit in situ setting composite porous scaffold for cancellous bone repair: Towards a “surgeon-friendly” bone filler?Poly(trimethylene carbonate) and nano-hydroxyapatite porous scaffolds manufactured by stereolithographyIn vitro and in vivo evaluation of a novel nanosize hydroxyapatite particles/poly(ester-urethane) composite scaffold for bone tissue engineeringIn vivo biocompatibility and vascularization of biodegradable porous polyurethane scaffolds for tissue engineeringNanohydroxyapatite/poly(ester urethane) scaffold for bone tissue engineeringA Comparison of Osteoblast and Osteoclast In Vitro Co-Culture Models and Their Translation for Preclinical Drug Testing ApplicationsEffects of locally applied adipose tissue-derived microvascular fragments by thermoresponsive hydrogel on bone healingThe RAPIDOS project-European and Chinese collaborative research on biomaterialsEvaluation of biomimetic hyaluronic-based hydrogels with enhanced endogenous cell recruitment and cartilage matrix formation3D bioprinting of a hyaluronan bioink through enzymatic-and visible light-crosslinkingIntroduction of the Anspach drill as a novel surgical driller for creating calvarial defects in animal modelsElectrospray-Based Microencapsulation of Epigallocatechin 3-Gallate for Local Delivery into the Intervertebral Disc
P50
Q37357270-F973F30C-B5B7-4A91-8C43-264F3FF6E343Q37846132-D0AF6918-ECA1-43D9-B200-82FCEB9055F3Q38064182-C097F2E5-02BA-4955-B088-B9A6B6496679Q38394338-5ADE2F01-CA25-486F-9DB9-E84DEAD0BDD8Q39466115-720852FD-3D1F-4023-8245-316489E55E2FQ42112335-44ED11D0-8BCF-4C3B-9B73-59998B7A6EF8Q43127569-DA56F63F-810F-4977-8149-36770C853E5BQ46134627-33B8E354-053C-4F87-93DE-EED402E158A4Q46340331-2E7DDCE4-1103-49DB-9221-74AE399C853CQ47405417-AEFC7E9B-21BC-42B7-9FEF-A493249F7702Q48288780-275C91DF-2518-4EC0-8B3B-64E1D54599D1Q50537399-DFA1EB9A-C330-4A4A-9486-A8CC98C43BB5Q54323331-CDA60B7B-CD6A-49CD-8F86-41563DC3ABFAQ57070380-85CC2082-9BBC-4557-AB94-167DC7B41502Q57156711-B4E5DFBF-D5DB-4D0B-BE02-0B37050EED12Q57345532-D5B74F3E-1214-4FC4-8756-035D6CAAD993Q57349039-C7E0DAC7-9DCF-4BD9-8B34-030661BBCD23Q57350410-59980E13-15F4-4154-9606-8C536B969364Q57359582-9AA9EC49-B7F7-4F1B-8C92-4BC5DEF6C871Q60184579-F54D957D-9639-4FFB-BD64-56399D2B3FA1Q60248470-8CAB3F3C-62D2-48DE-A191-7D9483D57F54Q82217981-1E604945-A38E-4B08-8194-CDDB63F74FA1Q83475983-5742D1B2-E226-49F2-A843-A2E756D58E99Q83832046-A874EAB3-7310-4452-91FD-3E4B73DB0414Q89529722-77410AAB-272E-4B20-B44F-9F79C8814E78Q90373728-81957ED3-CB61-40E9-B889-D22CCD53B747Q90406568-C14B4ECD-7B45-4412-8D0B-05FFD9C4F484Q91281391-0463660B-89C4-4166-A6FC-4E6C79023AC5Q91314334-A85B3358-D699-46A1-9A3B-C338CDC5076AQ92141555-1212458F-0FAC-44F2-A9EC-76AAB1A35777Q93080090-8825DCCD-1726-4F99-A58E-E4B15F913F7C
P50
description
hulumtues
@sq
onderzoeker
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researcher
@en
հետազոտող
@hy
name
David Eglin
@ast
David Eglin
@en
David Eglin
@es
David Eglin
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type
label
David Eglin
@ast
David Eglin
@en
David Eglin
@es
David Eglin
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prefLabel
David Eglin
@ast
David Eglin
@en
David Eglin
@es
David Eglin
@sl
P106
P1153
6603127012
P21
P31
P496
0000-0002-8500-6887