Designing multivalent probes for tunable superselective targeting.
about
Biophysically inspired model for functionalized nanocarrier adhesion to cell surface: roles of protein expression and mechanical factorsObtaining control of cell surface functionalizations via Pre-targeting and Supramolecular host guest interactionsOptimal multivalent targeting of membranes with many distinct receptorsBinding of Hyaluronan to the Native Lymphatic Vessel Endothelial Receptor LYVE-1 Is Critically Dependent on Receptor Clustering and Hyaluronan OrganizationHybridization chain reaction: a versatile molecular tool for biosensing, bioimaging, and biomedicine.Chelating effect in short polymers for the design of bidentate binders of increased affinity and selectivity.Controlling Multivalent Binding through Surface Chemistry: Model Study on Streptavidin.Crystallinity of Double-Stranded RNA-Antimicrobial Peptide Complexes Modulates Toll-Like Receptor 3-Mediated Inflammation.A Multivalent Structure-Specific RNA Binder with Extremely Stable Target Binding but Reduced Interaction with Nonspecific RNAs.An experimental and computational framework for engineering multifunctional nanoparticles: designing selective anticancer therapies.Bond formation kinetics affects self-assembly directed by ligand-receptor interactions.Melting transition in lipid vesicles functionalised by mobile DNA linkers.Precision engineering of targeted nanocarriers.Modulation of toll-like receptor signaling by antimicrobial peptides.Exploiting Receptor Competition to Enhance Nanoparticle Binding Selectivity.What is special about 200 kDa hyaluronan that activates hyaluronan receptor signaling?Multivalent Binding of a Ligand-Coated Particle: Role of Shape, Size, and Ligand Heterogeneity.
P2860
Q28596891-888EE291-EACE-4AB5-B7C8-7EE911205C06Q28817957-DD03BB94-CB4A-4886-871C-BDA8FEC53CDBQ33913650-58A560D8-EA32-4A48-AE45-9C8C9B5DB064Q36778808-3AAFD2BA-868C-4BC5-9929-85E868980E38Q38675885-369ED06B-4D56-4BC2-B71D-99C6D6993205Q41862768-B9219F26-019F-4EE5-8C00-F95EE250A324Q42314473-294A7AB9-6650-497B-BE20-E3A67ACA0372Q46812773-1AE2E23C-A51A-4CE7-8029-E61BC0981435Q47601857-FAFCE9F5-5AE7-467F-BBE0-B52D1DCEA2AEQ47700402-425B0DE0-205C-4EBD-9DFF-E8B856D4367CQ48223811-59C95973-C8F9-4283-AF39-A7EEFD60073EQ48310775-E3A5D498-455E-4C18-B0F4-6AF3E6BA69EDQ50049633-A1D6ECC6-7EA8-44BA-AA20-5655E8E54735Q50060087-CDDFE3A3-C409-4174-8A29-61646B89678DQ50991342-0700ABB3-278D-490D-88EA-F27B33756F9EQ51012674-335681E3-1A8D-49FF-A7E9-2288028547E7Q52563513-0B7991FE-8877-4A8D-AEB1-B3E725842681
P2860
Designing multivalent probes for tunable superselective targeting.
description
2015 nî lūn-bûn
@nan
2015年の論文
@ja
2015年論文
@yue
2015年論文
@zh-hant
2015年論文
@zh-hk
2015年論文
@zh-mo
2015年論文
@zh-tw
2015年论文
@wuu
2015年论文
@zh
2015年论文
@zh-cn
name
Designing multivalent probes for tunable superselective targeting.
@ast
Designing multivalent probes for tunable superselective targeting.
@en
type
label
Designing multivalent probes for tunable superselective targeting.
@ast
Designing multivalent probes for tunable superselective targeting.
@en
prefLabel
Designing multivalent probes for tunable superselective targeting.
@ast
Designing multivalent probes for tunable superselective targeting.
@en
P2860
P50
P356
P1476
Designing multivalent probes for tunable superselective targeting.
@en
P2093
Rachel Auzély-Velty
P2860
P304
P356
10.1073/PNAS.1500622112
P407
P577
2015-04-21T00:00:00Z