New bioactive motifs and their use in functionalized self-assembling peptides for NSC differentiation and neural tissue engineering

Keyphrases

• Differentiation in Vitro 100%
• Self-assembling Peptide 100%
• Neural Stem Cell Differentiation 100%
• Bioactive Motifs 100%
• Neural Tissue Engineering 100%
• Multidisciplinary Approach 66%
• Biomimetic Scaffold 33%
• Tissue Engineering Applications 33%
• Injured Tissue 33%
• Spinal Cord Compression 33%
• Regeneration 33%
• Circular Dichroism 33%
• Phage 33%
• Atomic Force Microscopy 33%
• Stem Cell-derived 33%
• Neural Stem Cells 33%
• Neural Differentiation 33%
• Proliferation in Vitro 33%
• Regrowth 33%
• Derived Peptide 33%
• Functional Motif 33%
• Stem Cell Engraftment 33%
• Nervous System 33%
• Peptide Sequencing 33%
• Regenerative Medicine 33%
• Cell Engraftment 33%
• Phage Display Technology 33%
• Differentiation Therapy 33%
• Rheology 33%
• Stem Cell Viability 33%
• Neural Stem Cell Proliferation 33%
• Nervous Tissue 33%
• Functionalized Biomaterials 33%
• Neural Precursor Cells 33%
• Nanostructured Hydrogels 33%
• Sprout Regeneration 33%
• Nervous Tissue Engineering 33%
• Nervous Fibers 33%
• Locomotor Recovery 33%
• Fiber Regeneration 33%
• Axon Sprouting 33%

Neuroscience

• In Vitro 100%
• Cellular Differentiation 100%
• Neural Stem Cell 100%
• Nerve Tissue 100%
• Stem Cell 50%
• Spinal Cord Injury 25%
• In Vivo 25%
• Cell Viability 25%
• Cell Proliferation 25%
• Amino Acid Sequence 25%
• Minoxidil 25%
• Nervous System 25%
• Nerve Sprouting 25%

Biochemistry, Genetics and Molecular Biology

• Stem Cell 100%
• Cellular Differentiation 100%
• Tissue Regeneration 100%
• Self-Assembling Peptide 100%
• Cell Proliferation 16%
• Precursor 16%
• Peptide Sequence 16%
• Bacteriophage 16%
• Cell Viability 16%
• Phage Display 16%
• Biomimetics 16%
• Atomic Force Microscopy 16%
• Minoxidil 16%
• Flow Kinetics 16%
• Nerve Sprouting 16%
• Circular Dichroism 16%