Nome |
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The Glitter of Carbon Nanostructures in Hybrid/Composite Hydrogels for Medicinal Use, file e2913fda-5c2e-f688-e053-3705fe0a67e0
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1.106
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Wire Up on Carbon Nanostructures! How To Play a Winning Game, file e2913fd9-b222-f688-e053-3705fe0a67e0
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379
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The Unexpected Advantages of Using D-Amino Acids for Peptide Self- Assembly into Nanostructured Hydrogels for Medicine, file e2913fda-5c60-f688-e053-3705fe0a67e0
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357
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Assembly of a Tripeptide and Anti-Inflammatory Drugs into Supramolecular Hydrogels for Sustained Release, file e2913fdb-a545-f688-e053-3705fe0a67e0
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354
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Design and fabrication of magnetically responsive nanocarriers for drug delivery, file e2913fdb-27b4-f688-e053-3705fe0a67e0
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301
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Carbon nanotubes for organ regeneration: an electrifying performance, file e2913fd9-f2f8-f688-e053-3705fe0a67e0
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295
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The Covalent Functionalization of Graphene on Substrates, file e2913fde-b221-f688-e053-3705fe0a67e0
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282
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Oxidized Nanocarbons-Tripeptide Supramolecular Hydrogels: Shape Matters!, file e2913fdc-34ab-f688-e053-3705fe0a67e0
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272
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Ice Nucleation Activity of Graphene and Graphene Oxides, file e2913fdc-27ee-f688-e053-3705fe0a67e0
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214
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Luminescent supramolecular hydrogels from a tripeptide and nitrogen-doped carbon nanodots, file e2913fdb-a7db-f688-e053-3705fe0a67e0
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211
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Self-assembling, ultrashort peptide gels as antimicrobial biomaterials, file e2913fdd-6dc0-f688-e053-3705fe0a67e0
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196
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Green Approaches to Carbon Nanostructure-Based Biomaterials, file e2913fde-0046-f688-e053-3705fe0a67e0
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191
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Higher and lower supramolecular orders for the design of self-assembled heterochiral tripeptide hydrogel biomaterials, file e2913fd9-ab0a-f688-e053-3705fe0a67e0
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175
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Embedding and Positioning of Two FeII4L4 Cages in Supramolecular Tripeptide Gels for Selective Chemical Segregation, file e2913fdc-a61e-f688-e053-3705fe0a67e0
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171
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Supramolecular Tripeptide Hydrogel Assembly with 5-Fluorouracil, file e2913fdc-aa9a-f688-e053-3705fe0a67e0
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166
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Oxygen vacancies and interfaces enhancing photocatalytic hydrogen production in mesoporous CNT/TiO2 hybrids, file e2913fdb-21d6-f688-e053-3705fe0a67e0
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157
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The Phe-Phe Motif for Peptide Self-Assembly in Nanomedicine, file e2913fd9-ae13-f688-e053-3705fe0a67e0
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154
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Advances in nanocarbon composite materials, file e2913fdb-cdc8-f688-e053-3705fe0a67e0
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144
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Carbon nanotubes and catalysis: the many facets of a successful marriage, file e2913fdb-2b64-f688-e053-3705fe0a67e0
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133
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Self-Assembled Peptide Nanostructures for ECM Biomimicry, file 117d4c93-9fa3-4ada-badf-cbdfa6a55ce5
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126
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Bioadhesive supramolecular hydrogel from unprotected, short d,l-peptides with Phe-Phe and Leu-Asp-Val motifs, file e2913fdd-6d1c-f688-e053-3705fe0a67e0
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112
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Nanomaterials for stimulating nerve growth: Flexible nanomaterials may recruit neurons or create artificial bridges to restore connectivity, file e2913fdb-9bcd-f688-e053-3705fe0a67e0
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97
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Nanoscale assembly of functional peptides with divergent programming elements, file e2913fdf-9eef-f688-e053-3705fe0a67e0
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94
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Interfacial charge transfer in functionalized multi-walled carbon nanotube@TiO2 nanofibres, file e2913fde-f7c9-f688-e053-3705fe0a67e0
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89
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Design of a hydrophobic tripeptide that self-assembles into amphiphilic superstructures forming a hydrogel biomaterial, file e2913fda-5c62-f688-e053-3705fe0a67e0
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88
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New Magnetic Graphitized Carbon Black TiO2 Composite for Phosphopeptide Selective Enrichment in Shotgun Phosphoproteomics, file e2913fdb-2c0f-f688-e053-3705fe0a67e0
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87
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Diketopiperazine gels: New horizons from the self-assembly of cyclic dipeptides, file e2913fde-5746-f688-e053-3705fe0a67e0
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80
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A biocatalytic and thermoreversible hydrogel from a histidine-containing tripeptide, file e2913fde-f7ca-f688-e053-3705fe0a67e0
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65
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Driving up the Electrocatalytic Performance for Carbon Dioxide Conversion through Interface Tuning in Graphene Oxide-Bismuth Oxide Nanocomposites, file 41e48e37-7027-42a7-a77d-76268dfe8a70
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63
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Assembly of a Tripeptide and Anti-Inflammatory Drugs into Supramolecular Hydrogels for Sustained Release, file e2913fdb-a8bd-f688-e053-3705fe0a67e0
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59
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Supramolecular hydrogels from unprotected dipeptides: a comparative study on stereoisomers and structural isomers, file e2913fdd-de39-f688-e053-3705fe0a67e0
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59
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Peptide Gelators to Template Inorganic Nanoparticle Formation, file e2913fde-0d1f-f688-e053-3705fe0a67e0
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56
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Polymer Conjugates of Antimicrobial Peptides (AMPs) with D-Amino Acids (D-aa): State of the Art and Future Opportunities, file e2913fdf-5a62-f688-e053-3705fe0a67e0
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48
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Cages meet gels: Smart materials with dual porosity, file e2913fde-5a88-f688-e053-3705fe0a67e0
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47
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Nanostructured Ceria: Biomolecular Templates and (Bio)applications, file e2913fdf-0c6d-f688-e053-3705fe0a67e0
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46
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Higher and lower supramolecular orders for the design of self-assembled heterochiral tripeptide hydrogel biomaterials, file e2913fdb-3406-f688-e053-3705fe0a67e0
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45
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Unzipping the role of chirality in nanoscale self-assembly of tripeptide hydrogels, file e2913fd9-7f7d-f688-e053-3705fe0a67e0
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43
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Carbon Graphitization: Towards Greener Alternatives to Develop Nanomaterials for Targeted Drug Delivery, file e2913fdf-760d-f688-e053-3705fe0a67e0
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42
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Will Magnetic Nanomedicine Realise the Future of Therapy and Diagnosis?, file e2913fdb-242a-f688-e053-3705fe0a67e0
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41
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Carbon nanostructure morphology templates nanocomposites for phosphoproteomics, file e2913fdd-60ee-f688-e053-3705fe0a67e0
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40
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Chirality Effects on Peptide Self-Assembly Unraveled from Molecules to Materials, file e2913fde-fe92-f688-e053-3705fe0a67e0
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40
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Smart Hydrogels Meet Carbon Nanomaterials for New Frontiers in Medicine, file e2913fde-5a26-f688-e053-3705fe0a67e0
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37
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Cyclodipeptides: From Their Green Synthesis to Anti-Age Activity, file 38c2e098-caff-423e-a0d9-9f0b3251a142
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35
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Chirality effects at each amino acid position on tripeptide self-assembly into hydrogel biomaterials, file e2913fd9-7072-f688-e053-3705fe0a67e0
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35
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Self-Assembly and Gelation Study of Dipeptide Isomers with Norvaline and Phenylalanine, file b15ab641-c757-40a0-bd43-a51ab020d451
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34
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Heterochirality and Halogenation Control Phe-Phe Hierarchical Assembly, file e2913fdd-d5b7-f688-e053-3705fe0a67e0
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33
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Nanostructured Gels for Energy and Environmental Applications, file e2913fdd-d5ba-f688-e053-3705fe0a67e0
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33
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Peptide-Based Materials That Exploit Metal Coordination, file c163af43-3a99-4684-a044-a3ced7d24bc6
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32
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Peptide Inhibitors of Insulin Fibrillation: Current and Future Challenges, file 044ef979-e632-4985-a690-e318cb43b9e7
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31
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A biocatalytic and thermoreversible hydrogel from a histidine-containing tripeptide, file e2913fdf-0aa6-f688-e053-3705fe0a67e0
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31
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Cysteine Redox Chemistry in Peptide Self-Assembly to Modulate Hydrogelation, file 05311668-5ce0-455f-8c96-974f475476b6
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30
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Self-Assembly of Homo- and Hetero-Chiral Cyclodipeptides into Supramolecular Polymers towards Antimicrobial Gels, file 446e03ee-611b-48c9-a73f-aa4ef8b01852
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30
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Self-Assembling Peptides and Carbon Nanomaterials Join Forces for Innovative Biomedical Applications, file e2913fde-7e06-f688-e053-3705fe0a67e0
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27
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Biocatalysis of D,L-peptide nanofibrillar hydrogel, file e2913fdd-6dbd-f688-e053-3705fe0a67e0
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26
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Carbon Nanomaterials (CNMs) and Enzymes: From Nanozymes to CNM‐Enzyme Conjugates and Biodegradation, file e2913fdf-5a61-f688-e053-3705fe0a67e0
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26
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Heterochiral tetrapeptide self-assembly into hydrogel biomaterials for hydrolase mimicry, file 0401d156-bed8-4698-af8f-038837f1395f
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25
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Bioinspired Magnetic Nanochains for Medicine, file e2913fde-e8be-f688-e053-3705fe0a67e0
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25
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Single-atom substitution enables supramolecular diversity from dipeptide building blocks, file 67ed86f6-9852-447c-bc09-d68365f15c83
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23
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Under the lens: Carbon nanotube and protein interaction at the nanoscale, file e2913fdb-2422-f688-e053-3705fe0a67e0
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22
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Chemoenzymatic synthesis of GDP-azidodeoxymannoses: Non-radioactive probes for mannosyltransferase activity, file e2913fdb-ade1-f688-e053-3705fe0a67e0
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21
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Oxidized Nanocarbons-Tripeptide Supramolecular Hydrogels: Shape Matters!, file e2913fdc-34ac-f688-e053-3705fe0a67e0
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21
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Asymmetric Organocatalysis Accelerated via Self-Assembled Minimal Structures, file e2913fde-c470-f688-e053-3705fe0a67e0
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21
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A Double-Walled Tetrahedron with AgI 4 Vertices Binds Different Guests in Distinct Sites, file 080744f0-5b1a-46b3-ac36-d8be78bdb8be
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20
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Tripeptide self-assembled hydrogels: Unexpected twists of chirality, file e2913fd9-7f15-f688-e053-3705fe0a67e0
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19
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Luminescent supramolecular hydrogels from a tripeptide and nitrogen-doped carbon nanodots, file e2913fdb-a546-f688-e053-3705fe0a67e0
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19
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Carbon nanostructures decorated with titania: Morphological control and applications, file e2913fde-e041-f688-e053-3705fe0a67e0
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19
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Ice Nucleation Activity of Graphene and Graphene Oxides, file e2913fdc-381e-f688-e053-3705fe0a67e0
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18
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Ion Channels and Transporters as Therapeutic Agents: From Biomolecules to Supramolecular Medicinal Chemistry, file e2913fdf-b3d3-f688-e053-3705fe0a67e0
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18
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Supramolecular Hydrogels from a Tripeptide and Carbon Nano-Onions for Biological Applications, file 65b2649a-6577-400f-9c6a-bda73ad3a75f
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17
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Self-Assembly of Unprotected Dipeptides into Hydrogels: Water-Channels Make the Difference, file 14389399-77bf-4859-a540-065b86cd52dd
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16
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Design of a hydrophobic tripeptide that self-assembles into amphiphilic superstructures forming a hydrogel biomaterial, file e2913fda-570d-f688-e053-3705fe0a67e0
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16
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Hydrogels from a Self-Assembling Tripeptide and Carbon Nanotubes (CNTs): Comparison between Single-Walled and Double-Walled CNTs, file 3f260c60-09ff-4f10-9337-f3883d67249a
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15
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Cyclodipeptides: From Their Green Synthesis to Anti-Age Activity, file bd2d168e-4c50-4ae3-97e3-09f06efe5928
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15
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Self-assembly of benzophenone-diphenylalanine conjugate into a nanostructured photocatalyst, file bee7250d-2c14-481f-9bfb-d869997e1883
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15
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Dipeptide self-assembly into water-channels and gel biomaterial, file 8a1da3a0-59c1-4a90-814f-f7f9226ec005
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13
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Hydrogels from a Self-Assembling Tripeptide and Carbon Nanotubes (CNTs): Comparison between Single-Walled and Double-Walled CNTs, file b778a493-a808-48d2-a201-a97f0fd5dd31
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13
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Carbon nanotubes for cardiac tissue regeneration: State of the art and perspectives, file e2913fdf-abb2-f688-e053-3705fe0a67e0
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13
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Tripeptide Self-Assembly into Bioactive Hydrogels: Effects of Terminus Modification on Biocatalysis, file e2913fdd-d5b5-f688-e053-3705fe0a67e0
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12
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Supramolecular hydrogels from unprotected dipeptides: a comparative study on stereoisomers and structural isomers, file e2913fdd-e25a-f688-e053-3705fe0a67e0
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11
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Carbon nanotubes for cardiac tissue regeneration: State of the art and perspectives, file e2913fde-db67-f688-e053-3705fe0a67e0
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11
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Growth, Properties, and Applications of Branched Carbon Nanostructures, file e2913fde-eb61-f688-e053-3705fe0a67e0
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11
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Short Peptides for Hydrolase Supramolecular Mimicry and Their Potential Applications, file cf9f4e93-7757-4e6d-8ca7-c283bc81a221
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10
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Heterochirality and Halogenation Control Phe-Phe Hierarchical Assembly, file e2913fdd-df59-f688-e053-3705fe0a67e0
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9
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Smart tools for antimicrobial peptides expression and application: the elastic perspective, file 0625904a-e9c5-44a7-90df-df465f3a31c2
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8
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Interactions Between Peptide Assemblies and Proteins for Medicine, file 5dcfa3db-ee86-4194-9c2e-2a060971bd5b
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8
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Self-assembly of benzophenone-diphenylalanine conjugate into a nanostructured photocatalyst, file 14299085-c890-4f87-ab22-6e7495d5e500
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7
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Microwave-Assisted Cyclization of Unprotected Dipeptides in Water to 2,5-Piperazinediones and Self-Assembly Study of Products and Reagents, file e2913fdc-a623-f688-e053-3705fe0a67e0
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7
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Esterase Sequence Composition Patterns for the Identification of Catalytic Triad Microenvironment Motifs, file 17adcb09-66a9-45ea-8e14-8591cdf0f041
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6
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Natural and artificial photosynthesis: general discussion, file e2913fd9-f895-f688-e053-3705fe0a67e0
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6
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The Unexpected Advantages of Using D-Amino Acids for Peptide Self- Assembly into Nanostructured Hydrogels for Medicine, file e2913fda-5a93-f688-e053-3705fe0a67e0
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6
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Smart tools for antimicrobial peptides expression and application: the elastic perspective, file 1a6603f2-27dd-4350-b80e-4e0eeeec9991
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5
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Driving up the Electrocatalytic Performance for Carbon Dioxide Conversion through Interface Tuning in Graphene Oxide-Bismuth Oxide Nanocomposites, file 910257f1-bf03-4c5b-aa95-2497f0d6c2e2
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5
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Heterochiral tetrapeptide self-assembly into hydrogel biomaterials for hydrolase mimicry, file e2913fde-0d1d-f688-e053-3705fe0a67e0
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5
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Single-atom substitution enables supramolecular diversity from dipeptide building blocks, file e2913fdf-a6c9-f688-e053-3705fe0a67e0
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5
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Peptide Stereochemistry Effects from pKa-Shift to Gold Nanoparticle Templating in a Supramolecular Hydrogel, file 1a274f69-1df5-4eb6-a2ba-3153758b6559
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4
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Diverging conformations guide dipeptide self-assembly into crystals or hydrogels, file 1c924096-0abb-4c77-bdd4-953cbc5ddca6
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4
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Nanocomposite Hydrogels with Self-Assembling Peptide-Functionalized Carbon Nanostructures, file 7fad1db9-e81f-45ca-ad02-4eb34a5328a8
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4
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Under the lens: Carbon nanotube and protein interaction at the nanoscale, file e2913fd9-7071-f688-e053-3705fe0a67e0
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4
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The winding road for carbon nanotubes in nanomedicine, file e2913fd9-7f78-f688-e053-3705fe0a67e0
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4
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The Covalent Functionalization of Graphene on Substrates, file e2913fd9-a649-f688-e053-3705fe0a67e0
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4
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Totale |
7.725 |