about
Designing fractal nanostructured biointerfaces for biomedical applications.Recent progress in biointerfaces with controlled bacterial adhesion by using chemical and physical methods.Recent progress of abrasion-resistant materials: learning from nature.Designing Bioinspired Anti-Biofouling Surfaces based on a Superwettability Strategy.Hierarchical biointerfaces assembled by leukocyte-inspired particles for specifically recognizing cancer cells.Underwater-transparent nanodendritic coatings for directly monitoring cancer cells.Programmable fractal nanostructured interfaces for specific recognition and electrochemical release of cancer cells.Rapid generation of cell gradients by utilizing solely nanotopographic interactions on a bio-inert glass surface.Rapid Cell Patterning Induced by Differential Topography on Silica Nanofractal Substrates.Hydrophobic interaction-mediated capture and release of cancer cells on thermoresponsive nanostructured surfaces.Organogel-based thin films for self-cleaning on various surfaces.A Self-Cleaning TiO2 Nanosisal-like Coating toward Disposing Nanobiochips of Cancer Detection.Hierarchical Nanowire Arrays as Three-Dimensional Fractal Nanobiointerfaces for High Efficient Capture of Cancer Cells.Trap Effect of Three-Dimensional Fibers Network for High Efficient Cancer-Cell Capture.Antibody-Modified Reduced Graphene Oxide Films with Extreme Sensitivity to Circulating Tumor Cells.High antibacterial efficiency of pDMAEMA modified silicon nanowire arrays.Analysis of the bystander effect in cone photoreceptors via a guided neural network platform.Cancer Cells: Underwater-Transparent Nanodendritic Coatings for Directly Monitoring Cancer Cells (Adv. Healthcare Mater. 3/2014)Fabrication of Patterned Concave Microstructures by Inkjet ImprintingSemi-Egg-Like Heterogeneous Compartmentalization of Cells Controlled by Contact Angle HysteresisSuperwetting Surfaces under Different Media: Effects of Surface Topography on WettabilityGrooved Organogel Surfaces towards Anisotropic Sliding of Water DropletsBio-inspired soft polystyrene nanotube substrate for rapid and highly efficient breast cancer-cell captureDual-Responsive Surfaces Modified with Phenylboronic Acid-Containing Polymer Brush To Reversibly Capture and Release Cancer CellsRecent Advances in Bioinspired Gel Surfaces with Superwettability and Special AdhesionLayered nanocomposites by shear-flow-induced alignment of nanosheetsHigh-Throughput Isolation of Cell Protrusions with Single-Cell Precision for Profiling Subcellular Gene ExpressionMicrofluidics-Based Single-Cell Protrusion Analysis for Screening Drugs Targeting Subcellular Mitochondrial Trafficking in Cancer ProgressionCRISPR-Cas12a Coupled with Platinum Nanoreporter for Visual Quantification of SNVs on a Volumetric Bar-Chart ChipAuthor Correction: Layered nanocomposites by shear-flow-induced alignment of nanosheets
P50
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P50
description
researcher
@en
wetenschapper
@nl
հետազոտող
@hy
name
Pengchao Zhang
@ast
Pengchao Zhang
@en
Pengchao Zhang
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Pengchao Zhang
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type
label
Pengchao Zhang
@ast
Pengchao Zhang
@en
Pengchao Zhang
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Pengchao Zhang
@nl
prefLabel
Pengchao Zhang
@ast
Pengchao Zhang
@en
Pengchao Zhang
@es
Pengchao Zhang
@nl
P106
P31
P496
0000-0002-7851-2976