A novel in vitro model for microvasculature reveals regulation of circumferential ECM organization by curvatureDifferentiation of human ESCs to retinal ganglion cells using a CRISPR engineered reporter cell lineA new nerve guide conduit material composed of a biodegradable poly(phosphoester).Self-assembled biodegradable micellar nanoparticles of amphiphilic and cationic block copolymer for siRNA delivery.Stem cell therapy with overexpressed VEGF and PDGF genes improves cardiac function in a rat infarct modelTissue extracellular matrix nanoparticle presentation in electrospun nanofibers.Retention of stemness and vasculogenic potential of human umbilical cord blood stem cells after repeated expansions on PES-nanofiber matrices.Direct interrogation of DNA content distribution in nanoparticles by a novel microfluidics-based single-particle analysis.Dual-sensitive micellar nanoparticles regulate DNA unpacking and enhance gene-delivery efficiency.Charge density and molecular weight of polyphosphoramidate gene carrier are key parameters influencing its DNA compaction ability and transfection efficiencyNanofiber matrices promote the neuronal differentiation of human embryonic stem cell-derived neural precursors in vitro.Shape Transformation Following Reduction-Sensitive PEG Cleavage of Polymer/DNA Nanoparticles.String-like micellar nanoparticles formed by complexation of PEG-b-PPA and plasmid DNA and their transfection efficiency.Probing in vivo trafficking of polymer/DNA micellar nanoparticles using SPECT/CT imaging.Chitosan-DNA nanoparticles delivered by intrabiliary infusion enhance liver-targeted gene deliveryShape Control in Engineering of Polymeric Nanoparticles for Therapeutic Delivery.Fabrication of 3-dimensional multicellular microvascular structures.PEG-b-PPA/DNA micelles improve transgene expression in rat liver through intrabiliary infusion.Design of polyphosphoester-DNA nanoparticles for non-viral gene delivery.Control of polymeric nanoparticle size to improve therapeutic delivery.Tim-3/galectin-9 regulate the homeostasis of hepatic NKT cells in a murine model of nonalcoholic fatty liver disease.Nanoparticle-mediated transcriptional modification enhances neuronal differentiation of human neural stem cells following transplantation in rat brain.Surface-immobilization of adhesion peptides on substrate for ex vivo expansion of cryopreserved umbilical cord blood CD34+ cellsFunctional nanofiber scaffolds with different spacers modulate adhesion and expansion of cryopreserved umbilical cord blood hematopoietic stem/progenitor cells.Expansion of engrafting human hematopoietic stem/progenitor cells in three-dimensional scaffolds with surface-immobilized fibronectin.Critical Length of PEG Grafts on lPEI/DNA Nanoparticles for Efficient in Vivo Delivery.Single-dose microparticle delivery of a malaria transmission-blocking vaccine elicits a long-lasting functional antibody response.Nanoparticle-mediated conversion of primary human astrocytes into neurons and oligodendrocytesSimultaneous Non-invasive Analysis of DNA Condensation and Stability by Two-step QD-FRETEx vivo nanofiber expansion and genetic modification of human cord blood-derived progenitor/stem cells enhances vasculogenesis.Polymeric nanofiber coating with tunable combinatorial antibiotic delivery prevents biofilm-associated infection in vivoElectrospun scaffolds for stem cell engineering.Plasmid-templated shape control of condensed DNA-block copolymer nanoparticles.Current applications and future perspectives of artificial nerve conduits.Recent advances in nanoparticle-mediated siRNA delivery.Biodegradable poly(terephthalate-co-phosphate)s: synthesis, characterization and drug-release propertiesQuantitative comparison of intracellular unpacking kinetics of polyplexes by a model constructed from quantum dot-FRET.Enhancing oligodendrocyte differentiation by transient transcription activation via DNA nanoparticle-mediated transfection.Characterization of a novel bioreactor system for 3D cellular mechanobiology studies.Galactosylated ternary DNA/polyphosphoramidate nanoparticles mediate high gene transfection efficiency in hepatocytes.
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Q27301419-1B4DDF06-DD2C-48B0-9620-D117277CBA45Q27306313-2E77710D-0646-47E0-A023-A4256798A0FBQ30989330-26A3C771-0B51-474B-BBA5-B8500C68EE0BQ33361831-7EFDD9C3-0CAA-4D12-B0F4-214DAFF39622Q33509006-56A91E16-49A5-4F5C-8B5B-AD59AAD63E20Q33757392-704494B9-D4A4-4ACB-9686-CBBD6BF2FB57Q34041306-DA6B6C48-9076-4D97-9A6E-682CBED6F723Q34050308-0F675BF1-4C7D-4A88-A72D-EA6AD740A7D1Q34400042-313ABBE0-A2B1-4220-8906-FEF7CFCABA0BQ34494885-70D0262F-3043-461D-A6C8-B7C860B70906Q34599726-6C5D6EB3-EE7D-455E-87C4-3FDF11312B38Q34727867-AB99E188-0EB8-423F-AE5B-F8CD70EC2F28Q35050973-F5E0BB81-206D-436F-ADE4-F46B762D679AQ35238269-5799040A-2D53-4B05-9854-BDE4CC166E69Q35688220-0D4FF776-16F7-4DC5-8141-EFC2D4224F77Q35801327-CC72D235-DE12-4168-A927-0251C103D603Q35878963-72E4D5EE-8AE2-4B70-9272-815B3CFA87CFQ36084329-99A9B9E1-1740-4E59-80C5-A1028618F2C3Q36293325-08D1216F-5410-45E5-9AD3-8D40E23130BAQ36307555-0B5D2A50-7BEF-4B2B-859D-5780CC5394F8Q36586341-B78E6AAD-3DBB-4D53-881A-6593CDF67290Q36586365-630B302A-7D32-4F36-8590-3BFC2DE2C5E6Q36647888-7F01D3BC-A0CD-452C-91D7-08EB6727B644Q36647930-113B38CC-9CDF-4EF3-81C7-FFA59B5E44CDQ36675920-58E3D140-902E-46EC-9F48-94EAF13C0861Q36793350-EE1E8866-E07C-40E6-AC2E-F83F81254C24Q36998403-5180DA42-AE0C-4AFC-8609-0A709D1CE2AEQ37041873-FE67ED70-A5B6-4F2A-802F-A83532358538Q37352954-FB903E15-D0E8-4C49-8ACA-71234221263CQ37358894-1891DACD-619F-465A-8AF1-489100920CDFQ37417976-0BEE7DC3-1B29-43CA-9A24-1F9700AE9F06Q37568515-3E9A206A-4D51-4D5F-8A8E-270438BCB95FQ37570199-56F94A8A-25C7-46CD-833F-AB63D76B99B5Q37601035-E3C49C3C-CDC4-4990-86BD-E48CD21FA3B3Q38218250-49748F33-5363-41B3-B1F7-A4CE4E242B0EQ38303045-1142A860-4C0E-45AC-93D3-08EEFB31ECF8Q40027542-186675B3-31FE-4739-A552-FA79EAF4CEE1Q40273070-EB97F3C8-887F-43CD-BA6B-79E5D9ADF269Q40348611-65215E06-3E92-4D5C-B986-4AAD12447F65Q40463867-755EE8B7-D8D2-4D26-B8AE-43EB2294F0D5
P50
description
Chinese-American chemist and nanotechnologist
@en
wetenschapper
@nl
հետազոտող
@hy
name
Hai-Quan Mao
@ast
Hai-Quan Mao
@en
Hai-Quan Mao
@es
Hai-Quan Mao
@nl
Hai-Quan Mao
@sl
毛海泉
@zh
毛海泉
@zh-cn
毛海泉
@zh-tw
type
label
Hai-Quan Mao
@ast
Hai-Quan Mao
@en
Hai-Quan Mao
@es
Hai-Quan Mao
@nl
Hai-Quan Mao
@sl
毛海泉
@zh
毛海泉
@zh-cn
毛海泉
@zh-tw
altLabel
Mao Haiquan
@en
prefLabel
Hai-Quan Mao
@ast
Hai-Quan Mao
@en
Hai-Quan Mao
@es
Hai-Quan Mao
@nl
Hai-Quan Mao
@sl
毛海泉
@zh
毛海泉
@zh-cn
毛海泉
@zh-tw
P1153
7201796602
P21
P31
P496
0000-0002-4262-9988