about
P184
ATG101 Single-Stranded Antisense RNA-Loaded Triangular DNA Nanoparticles Control Human Pulmonary Endothelial Growth via Regulation of Cell Macroautophagy.Reconfiguration of DNA molecular arrays driven by information relay.Regulating DNA Self-assembly by DNA-Surface Interactions.Can strand displacement take place in DNA triplexes?One DNA strand homo-polymerizes into defined nanostructures.Isothermal Self-Assembly of Spermidine-DNA Nanostructure Complex as a Functional Platform for Cancer Therapy.In vivo production of RNA nanostructures via programmed folding of single-stranded RNAs.Capturing intracellular oncogenic microRNAs with self-assembled DNA nanostructures for microRNA-based cancer therapyUniversal pH-Responsive and Metal-Ion-Free Self-Assembly of DNA NanostructuresParanemic Crossover DNA: There and Back AgainRational Design of pH-Responsive DNA Motifs with General Sequence CompatibilityMaking Engineered 3D DNA Crystals RobustAssembly of a DNA Origami Chinese Knot by Only 15% of the Staple StrandsTargeted Delivery of Rab26 siRNA with Precisely Tailored DNA Prism for Lung Cancer TherapySelf-Assembly of Microparticles by Supramolecular Homopolymerization of One Component DNA MoleculeDesigning Higher Resolution Self-Assembled 3D DNA Crystals via Strand Terminus ModificationsModulating Self-Assembly of DNA Crystals with Rationally Designed AgentsPatterning Nanoparticles with DNA MoldsRational Design and Self-Assembly of Two-Dimensional, Dodecagonal DNA QuasicrystalsATP-Triggered, Allosteric Self-Assembly of DNA NanostructuresBranched kissing loops for the construction of diverse RNA homooligomeric nanostructuresCorrection to Isothermal Self-Assembly of Spermidine-DNA Nanostructure Complex as a Functional Platform for Cancer Therapy
P50
Q47706481-D47425C9-DF13-48CF-BF3B-7AF6C8605E64Q47993421-FFC45675-49C7-4996-AA6D-57EA66C2A93CQ48051880-01D78D5A-E4BC-4511-B471-53B87F4501E8Q48561934-DB0F5A25-4E2C-4A93-9916-C95C72F24F44Q48716571-A730B160-A907-44D5-AB36-7EE8901E3ADDQ52322510-47565844-79E3-43D2-9404-D074459DF498Q54954372-D54AEF3E-29D2-4763-837D-805CD15FE34DQ57470012-CF02196E-0DC8-48D8-AAF9-7EAC93E8367AQ88439672-73CC077B-0D2F-4434-8FA8-11EAB747CEA5Q89134111-6E8BCBF0-0F80-4BEF-BAC3-9B13B4775C82Q90142137-E0B548ED-8F2D-4ADF-82E7-DABBECED402BQ90275174-3AE0D644-317B-472E-89BE-EF797037826FQ90512204-D0AE9A63-70C4-437D-9FF9-A0636FD5077CQ90898709-95AE5231-6CA5-4E7C-AE69-26FFB4D9D2B5Q91415433-D9816173-A24C-4001-96F3-8DBC70E78380Q91545154-0FB0316F-5C04-49EA-AB5D-831811A2488EQ91622099-B2AAAA12-9D06-4242-8778-E2B11FEF148EQ91824506-BB0D1C0D-41BA-4603-A2DB-8BF1E5370FC9Q92079564-AFE170BC-4EDB-4B6F-9AD5-A4E88D88D337Q92251273-EC94DF06-1E80-4A51-AF78-BE278CC8E181Q92784384-0F0E7F72-99A1-47FA-B096-970DAD27CD72Q96613178-E656027E-CA15-4A34-8D18-9320048FD134
P50
description
researcher
@en
ricercatore
@it
name
Chengde Mao
@en
Chengde Mao
@nl
type
label
Chengde Mao
@en
Chengde Mao
@nl
prefLabel
Chengde Mao
@en
Chengde Mao
@nl
P1006
P214
P1006
P185
P2038
Chengde_Mao
P21
P214
P31
P496
0000-0001-7516-8666
P7859
lccn-no2007004069