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Multifunctional dendrimer-entrapped gold nanoparticles modified with RGD peptide for targeted computed tomography/magnetic resonance dual-modal imaging of tumors.Dendrimer-entrapped gold nanoparticles as potential CT contrast agents for blood pool imagingAdaptive Resolution Simulation (AdResS): A Smooth Thermodynamic and Structural Transition from Atomistic to Coarse Grained Resolution and Vice Versa in a Grand Canonical Fashion.Conjugation of iron oxide nanoparticles with RGD-modified dendrimers for targeted tumor MR imaging.Lactobionic acid-modified dendrimer-entrapped gold nanoparticles for targeted computed tomography imaging of human hepatocellular carcinoma.Folic acid-modified dendrimer-entrapped gold nanoparticles as nanoprobes for targeted CT imaging of human lung adencarcinoma.PEGylated dendrimer-entrapped gold nanoparticles for in vivo blood pool and tumor imaging by computed tomography.Computed tomography imaging of cancer cells using acetylated dendrimer-entrapped gold nanoparticles.Active targeting theranostic iron oxide nanoparticles for MRI and magnetic resonance-guided focused ultrasound ablation of lung cancer.Chemical potential of liquids and mixtures via adaptive resolution simulation.The optimal particle-mesh interpolation basis.Kaiser-Bessel basis for particle-mesh interpolation.[Magnetic resonance guided focused ultrasound surgery for pain palliation of bone metastases: early experience of clinical application in China].Multiple Staggered Mesh Ewald: Boosting the Accuracy of the Smooth Particle Mesh Ewald Method.On the existence of the optimal order for wavefunction extrapolation in Born-Oppenheimer molecular dynamics.Sampling the isothermal-isobaric ensemble by Langevin dynamics.Exploring the Conformational Dynamics of Alanine Dipeptide in Solution Subjected to an External Electric Field: A Nonequilibrium Molecular Dynamics Simulation.Is there a third order phase transition for supercritical fluids?Multifunctional gold nanocomposites designed for targeted CT/MR/optical trimodal imaging of human non-small cell lung cancer cells.On the Numerical Accuracy of Ewald, Smooth Particle Mesh Ewald, and Staggered Mesh Ewald Methods for Correlated Molecular Systems.On the existence of a third-order phase transition beyond the Andrews critical point: a molecular dynamics study.Deep Potential Molecular Dynamics: A Scalable Model with the Accuracy of Quantum Mechanics.A critical appraisal of the zero-multipole method: Structural, thermodynamic, dielectric, and dynamical properties of a water system.Synthesis of PEGylated low generation dendrimer-entrapped gold nanoparticles for CT imaging applications.Adaptive coupling of a deep neural network potential to a classical force fieldComparative atomistic and coarse-grained study of water: What do we lose by coarse-graining?End-to-end Symmetry Preserving Inter-atomic Potential Energy Model for Finite and Extended SystemsDeePCG: Constructing coarse-grained models via deep neural networksReinforced dynamics for enhanced sampling in large atomic and molecular systemsDP-GEN: A concurrent learning platform for the generation of reliable deep learning based potential energy models
P50
Q30909713-6587F220-4F10-4283-A095-56F11FCC3548Q35881174-9B2E8899-0259-4E20-9F82-50F4750E55CBQ38423713-637A8A7A-5506-4A27-8058-51EF528E2787Q38908083-10F458A0-7B8B-4611-AC0A-4B0F9449CECCQ39006466-5850A744-975B-4730-8D64-26F390C72CCDQ39255120-B9A5481C-DF63-42E9-8A89-1B6BFCE8482BQ39446941-A29E645E-6F13-4673-BA3D-BD9C6322E985Q39601089-6F7367F1-3730-4B3C-BE54-9A7DB24A0507Q46852541-9FA3623E-6260-44FE-B5A9-AE6AFC74180BQ46862721-3FA4B54E-34F8-4216-9881-32E98ECEE5B4Q47666248-680AB85D-05D4-451B-8AE2-9AE311D56007Q47765313-486D6CE0-8E5F-4B3A-A84C-0907E0D8FFD7Q50240574-41504FD7-417F-45D6-951B-D8EC605348C4Q50558473-95EC0619-3DA2-41DA-8449-BEA76757CA49Q50618027-D06ED250-05AD-441F-A9B5-534901ABE29AQ50676157-A4BBC6D7-6439-4ACD-93EF-64BBC5D5B049Q51097188-08FD1D54-EB95-4416-9FD1-73043BB6B12AQ51124675-4F623B55-28DD-4109-A3A6-D49FAE8F2B2FQ51266036-6BF670A5-70BA-4C6A-A426-8BD98F47E875Q51325834-03912A84-69AB-428D-A7CB-827C9DD70D6CQ51473026-5F3A913C-0CDB-4D12-B760-E88FB0CC6539Q52563927-F99CBAB6-43DD-45B2-9E2B-9F68147B2E82Q52854636-E591FC10-BFC7-46F6-9461-30D9F711E27EQ53074353-5B1EEF9B-EBBA-4CC1-B4D6-0E1B9AABD744Q57806633-B3D3180D-97E4-4054-95C2-D8534D918B57Q59219378-FBB34F45-1127-4802-8017-099C8790063AQ59481621-F02E1356-0286-42B8-B09E-9EF08C08E3ABQ64123423-340D9BA8-D92E-461C-8A01-228E3FE3C56EQ64125271-F1CC4951-EE6F-405F-827B-200A34CDCFB6Q84727297-04CCA577-E36C-4DD2-A61E-8E87CACC5F36
P50
description
researcher ORCID: 0000-0001-5623-1148
@en
name
Han Wang
@ast
Han Wang
@en
Han Wang
@es
Han Wang
@nl
Han Wang
@sl
type
label
Han Wang
@ast
Han Wang
@en
Han Wang
@es
Han Wang
@nl
Han Wang
@sl
prefLabel
Han Wang
@ast
Han Wang
@en
Han Wang
@es
Han Wang
@nl
Han Wang
@sl
P106
P2456
P31
P496
0000-0001-5623-1148