Item type: | Article | ||||
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Journal or Publication Title: | ACS Applied Materials & Interfaces | ||||
Publisher: | AMER CHEMICAL SOC | ||||
Place of Publication: | WASHINGTON | ||||
Volume: | 12 | ||||
Number of Issue or Book Chapter: | 31 | ||||
Page Range: | pp. 34689-34702 | ||||
Date: | 2020 | ||||
Institutions: | Biology, Preclinical Medicine > Institut für Physiologie Biology, Preclinical Medicine > Institut für Physiologie > Prof. Dr. Frank Schweda Biology, Preclinical Medicine > Institut für Anatomie Biology, Preclinical Medicine > Institut für Anatomie > Lehrstuhl für Molekulare und zelluläre Anatomie Biology, Preclinical Medicine > Institut für Anatomie > Lehrstuhl für Molekulare und zelluläre Anatomie > Prof. Dr. Ralph Witzgall Chemistry and Pharmacy > Institute of Pharmacy Chemistry and Pharmacy > Institute of Pharmacy > Pharmaceutical Technology (Prof. Göpferich) | ||||
Identification Number: |
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Keywords: | GOLD NANOPARTICLES; ALPHA(V)BETA(3) INTEGRIN; DIABETIC-NEPHROPATHY; DRUG-DELIVERY; VIRUS ENTRY; RGD; PHARMACOKINETICS; ALPHA-V-BETA-3; THERAPY; BINDING; virus-mimetic nanoparticles; human adenovirus; sequential ligand-receptor interplay; cell-specific targeting; mesangial cells | ||||
Dewey Decimal Classification: | 500 Science > 570 Life sciences 600 Technology > 615 Pharmacy | ||||
Status: | Published | ||||
Refereed: | Yes, this version has been refereed | ||||
Created at the University of Regensburg: | Yes | ||||
Item ID: | 43683 |
Abstract
Viral infection patterns often rely on precisely coordinated sequences of distinct ligand-receptor interactions, leading in many cases to an outstanding target cell specificity. A successful mimicry of viral targeting strategies to create more site-specific nanoparticles (NPs) would therefore require particle-cell interactions to also be adequately controllable. In the present study, ...
Abstract
Viral infection patterns often rely on precisely coordinated sequences of distinct ligand-receptor interactions, leading in many cases to an outstanding target cell specificity. A successful mimicry of viral targeting strategies to create more site-specific nanoparticles (NPs) would therefore require particle-cell interactions to also be adequately controllable. In the present study, hetero-multivalent block-copolymer NPs present their attached ligands in a sterically controlled manner to create a sequential NP-cell interaction similar to the cell infiltration strategy of human adenovirus type 2. Targeting renal mesangial cells, particles therefore initially bind angiotensin II receptor type 1 (AT1r) on the cell surface via a structurally flexible AT1r antagonist. After a mandatory spatial approach, particle endocytosis is realized via binding of immobile alpha(nu)beta(3) integrins with a previously concealed secondary ligand, thereby creating a stepwise particle-cell interplay of primary NP attachment and subsequent uptake. Manufactured adenovirus-mimetic NPs show great avidity for both target motifs in vitro, leading to a substantial binding as well as subsequent cell uptake into target mesangial cells. Additionally, steric shielding of secondary ligand visibility leads to a highly controllable, sequential ligand-receptor interaction, whereby hetero-functional NPs activate mesangial cell surface integrins only after a successful prior binding to the AT1r. This stepwise cell identification significantly enhances mesangial cell specificity in co-culture assays with different off-target cells. Additionally, described NPs display excellent in vivo robustness by efficiently accumulating in the mesangium upon injection, thereby opening new paths for possible drug delivery applications.
Metadata last modified: 29 Sep 2021 07:41