about
Stem Cells in Skin Wound Healing: Are We There Yet?Perivascular-like cells contribute to the stability of the vascular network of osteogenic tissue formed from cell sheet-based constructsHuman skin cell fractions fail to self-organize within a gellan gum/hyaluronic acid matrix but positively influence early wound healing.Human mesenchymal stem cells response to multi-doped silicon-strontium calcium phosphate coatings.Human adipose tissue-derived SSEA-4 subpopulation multi-differentiation potential towards the endothelial and osteogenic lineages.Cell interactions in bone tissue engineering.Semipermeable Capsules Wrapping a Multifunctional and Self-regulated Co-culture Microenvironment for Osteogenic Differentiation.Cell sheet engineering using the stromal vascular fraction of adipose tissue as a vascularization strategy.Platelet lysate-based pro-angiogenic nanocoatings.Effect of monocytes/macrophages on the early osteogenic differentiation of hBMSCs.Eumelanin-releasing spongy-like hydrogels for skin re-epithelialization purposes.Preparation and characteristics of the sulfonated chitosan derivatives electrodeposited onto 316l stainless steel surface.Nanostructured interfacial self-assembled peptide-polymer membranes for enhanced mineralization and cell adhesion.Carboxymethylchitosan/poly(amidoamine) dendrimer nanoparticles in central nervous systems-regenerative medicine: effects on neuron/glial cell viability and internalization efficiency.In vivo osteogenic differentiation of stem cells inside compartmentalized capsules loaded with co-cultured endothelial cells.Stem Cell-Containing Hyaluronic Acid-Based Spongy Hydrogels for Integrated Diabetic Wound Healing.Extraction and characterization of collagen from Antarctic and Sub-Antarctic squid and its potential application in hybrid scaffolds for tissue engineering.Mastocarcinoma therapy synergistically promoted by lysosome dependent apoptosis specifically evoked by 5-Fu@nanogel system with passive targeting and pH activatable dual function.Neovascularization Induced by the Hyaluronic Acid-Based Spongy-Like Hydrogels Degradation Products.Growth Factor-Free Pre-vascularization of Cell Sheets for Tissue Engineering.Tissue engineering: new tools for old problems.Endothelial cells enhance the in vivo bone-forming ability of osteogenic cell sheets.Fibroblasts regulate osteoblasts through gap junctional communication.Influence of freezing temperature and deacetylation degree on the performance of freeze-dried chitosan scaffolds towards cartilage tissue engineeringBottom-up approach to construct microfabricated multi-layer scaffolds for bone tissue engineeringCell sheet technology-driven re-epithelialization and neovascularization of skin woundsGellan Gum-Hyaluronic Acid Spongy-like Hydrogels and Cells from Adipose Tissue Synergize Promoting Neoskin VascularizationAdipose stem cell-derived osteoblasts sustain the functionality of endothelial progenitors from the mononuclear fraction of umbilical cord bloodHuman Adipose Stem Cells Cell Sheet Constructs Impact Epidermal Morphogenesis in Full-Thickness Excisional WoundsDevelopment of Osteogenic Cell Sheets for Bone Tissue Engineering ApplicationsMarine Collagen/Apatite Composite Scaffolds Envisaging Hard Tissue ApplicationsStem Cells for Osteochondral RegenerationStrategies for the hypothermic preservation of cell sheets of human adipose stem cellsTumor Targeting Strategies of Smart Fluorescent Nanoparticles and Their Applications in Cancer Diagnosis and Treatment
P50
Q26748513-66B801FF-4285-49DC-9E7E-CDD4E3F0CBECQ28729038-E07A71A0-76B0-44E7-A7D0-A2D2140552BDQ33571621-33C11B17-4B8B-44A4-9BFD-2479E5F406ADQ35026949-FB1ACDAF-D1BD-4C36-958E-36F24D3D8613Q36490813-D5AE99D9-12E5-40C1-964E-B582A12064FAQ37668709-F849E802-3B5B-41F5-A23B-2C5E3E0BFC85Q38607042-B77ED971-B55D-4E37-BD21-FD089EED298EQ38873001-5F47147D-31C2-4EB1-8082-D258FD844504Q40167204-90ED6BBB-6ED7-4797-87FC-06D672F05350Q45237754-241A0882-E512-48D7-8A3F-B1640AC36C24Q46420647-1B88E81A-1F39-4EFB-AFBF-1B2F67F47DB3Q47317577-92DD68AC-B994-4202-B15C-B5AE365A9BC4Q47710827-C9397EC0-6722-4BB5-A930-6AF4E9F0911BQ48139849-F838BC76-A2A3-4A5E-8D63-5C147385B732Q48837488-5F7F888B-C6EB-4D61-A5DC-DDD7EE511552Q50682746-F759BAC9-39E0-46E7-BC46-9D5F7DBB230CQ50854584-7D615976-3C7F-4DE9-A5E1-C32D3A0761EFQ50945478-45AEEB9D-F2BB-44BC-BDE5-7ECB5C53AF3AQ51080671-15E708AF-8EAB-4EC9-A73B-AFAE555C1097Q51308312-0CC091CA-64B2-41C2-8C0C-C4A15F991E36Q53245379-20A750F6-B632-4C95-A307-D23711489282Q53580223-0015B4D4-DFAF-4469-B1C6-5BC1A2454DBAQ54298574-DF0A7C43-43F0-4C4E-AC0B-017860B7ABFAQ57170662-DE1C4F64-AF9E-407E-A765-6C460913E17CQ57171094-B1CCA685-E8DE-4B8D-A2EE-F1D23C7DC218Q57171096-314DDBF9-1813-4169-B19A-C22FF7DED311Q57171124-4153F3BD-CD41-4E28-912F-F2D91E06B983Q57171204-3998D3B5-E038-43BF-BD27-5D75784C2E75Q57171256-218799F7-71F4-4EB8-8C04-62D0866ECB73Q57171420-864165C5-F09C-41EB-86C1-455C8CE01BE0Q58801035-8809B858-794F-4BCD-B2A5-FF2A01375347Q88598593-D869667C-6BEF-48BA-907F-EC12D259404EQ90717140-3EF34B3C-3354-4E92-BDA6-7F9E0F916920Q92337683-0DC0DCFD-A554-42FE-A6E3-B370F9825E0B
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Rogério P Pirraco
@nl
Rogério P Pirraco
@sl
Rogério P. Pirraco
@en
Rogério P. Pirraco
@es
type
label
Rogério P Pirraco
@nl
Rogério P Pirraco
@sl
Rogério P. Pirraco
@en
Rogério P. Pirraco
@es
prefLabel
Rogério P Pirraco
@nl
Rogério P Pirraco
@sl
Rogério P. Pirraco
@en
Rogério P. Pirraco
@es
P106
P1153
24473477700
P31
P496
0000-0001-5521-950X