Reis, Rui L.
Reis, Rui L. 1967-
Reis, Rui Luís Gonçalves dos
Rui L. Reis Portuguese scientist
Reis, Rui Luís Gonçalves dos, 1967-
VIAF ID: 44591901 ( Personal )
Permalink: http://viaf.org/viaf/44591901
Preferred Forms
- 200 _ | ‡a Reis ‡b Rui L.
- 100 1 _ ‡a Reis, Rui L.
- 100 1 _ ‡a Reis, Rui L.
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- 100 1 _ ‡a Reis, Rui L.
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- 100 1 _ ‡a Reis, Rui L. ‡d 1967-
- 100 1 _ ‡a Reis, Rui L. ‡d 1967-
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- 100 0 _ ‡a Rui L. Reis ‡c Portuguese scientist
4xx's: Alternate Name Forms (18)
5xx's: Related Names (2)
Works
Title | Sources |
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Adipose derived stem cells for nbone and cartilage tissue engineering novel isolation procedure in vitro characterization and in vivo functionality assessment | |
Autologous bone tissue engineering strategies envisioning the regeneration of critical size defects using cell-seeded scaffolds and a newly developed perfusion bioreactor | |
Biomaterials for 3D tumor modeling | |
Biomaterials from nature for advanced devices and therapies | |
Biomedical devices engineering based on the control of the surface wettability | |
Biomimicked Biomaterials : Advances in Tissue Engineering and Regenerative Medicine | |
Cell-derived matrices. | |
Cell targeted nanoparticle-based drug delivery systems for spinal cord injury regeneration | |
Comportamento sob esforços ciclicos de fadiga em ambientes fisiológicos simulados de biomateriais com revestimento bio-reactivo | |
Development of electrospun nanofibrous-based scaffolds for bone regeneration | |
Engineering articular cartilage using newly developed carrageenan basedhydrogels | |
Engineering osteochondral tissues with human adipose tissue derived stem cells under precise biomechanical and biochemical in vitro environments | |
Imovative self-assembled and microfabricated structures to be used in distinct biomedical aplications | |
In vivo assessment of the host reactions to natural origin biomaterials aimed to be used as wound dressers and as bone tissue engineering scaffolds | |
Learning from nature how to design new implantable biomaterials : from biomineralization fundamentals to biomimetic materials and processing routes | |
Microfluidics and Biosensors in Cancer Research : Applications in Cancer Modeling and Theranostics | |
Multifunctional Hydrogels for Biomedical Applications | |
New 3D scaffolds and adequate mesenchymal stem cells culture methodologies for engineering an articular cartilage transplants | |
New biomimetic acellular routes for pre-calcification of implant materials, carrier particles and porous scaffolds | |
New biomimetic approaches for producing bone-like calcium-phosphate coatings on the surface of tissue engineering 3D architectures and ortopaedic implants | |
New functionalization-reinforcement strategies for cork plastics composites opening a wide range of innovative applications for cork based products | |
New nanotechnology approaches using dendrimers modified with natural polymers for controlling stem cells behaviour in tissue engineering strategies | |
Novel 3D scaffolds modified with nanostructured polymeric coatings or micro-nanofibers for tissue engineering applications | |
Novel biodegradable drug delivery systems for the controlled release of growth factors in bone healing and tissue engineering | |
Novel biodegradable polymeric and composite structures to be used as biomedical implants and tissue engineering scaffolds | |
Novel cork-based compounds for biomedical applications from antibacterials to the modulation of neurodegeneration | |
Osteochondral Tissue Engineering : Challenges, Current Strategies, and Technological Advances | |
Polymer based systems on tissue engineering, replacement, and regeneration | |
Polysaccharides of Microbial Origin : Biomedical Applications | |
Potential of human bone marrow derived stem cells combined with chitosan based biodegradable scaffolds for bone tissue engineering | |
Preparation and characterisation of novel multifuncional chitosan-based membranes to modulate cell-material interactions | |
Processing and surface modification of novel natural-origin architectures aimed for biomedical applications | |
Regenerative strategies for the treatment of knee joint disabilities, 2017: | |
Skin tissue models | |
Some hints on using surface phenomena for the design and performance optimization of distinct biomedical devices | |
Starch and polyetheylene based bone-analogue composite biomaterials | |
Tendon regeneration : understanding tissue physiology and development to engineer functional substitutes |