Přehled o publikaci
2022
Geometric Control of Cell Behavior by Biomolecule Nanodistribution
POSPÍŠIL, Jakub; Milos HRABOVSKY; Dáša BOHAČIAKOVÁ; Zuzana HOVADKOVA; Miroslav JURÁSEK et al.Basic information
Original name
Geometric Control of Cell Behavior by Biomolecule Nanodistribution
Authors
POSPÍŠIL, Jakub; Milos HRABOVSKY; Dáša BOHAČIAKOVÁ; Zuzana HOVADKOVA; Miroslav JURÁSEK; Jarmila MLČOUŠKOVÁ; Kamil PARUCH; Šárka NEVOLOVÁ; Jiří DAMBORSKÝ; Aleš HAMPL and Josef JAROŠ
Edition
ENGINEERING, WASHINGTON, AMER CHEMICAL SOC, 2022, 2373-9878
Other information
Language
English
Type of outcome
Article in a journal
Country of publisher
United States of America
Confidentiality degree
is not subject to a state or trade secret
Marked to be transferred to RIV
Yes
RIV identification code
RIV/00216224:14110/22:00127154
Organization
Lékařská fakulta – Repository – Repository
UT WoS
EID Scopus
Keywords in English
nanopatterning; nanospacing; biomimetic surface; electron-beam lithography; cell-cell interaction; cell adhesion and spreading; ligand clustering
Links
EF18_046/0015974, research and development project. LM2018129, research and development project. LM2018130, research and development project. MUNI/A/1398/2021, interní kód Repo. MUNI/R/1697/2020, interní kód Repo. 857560, interní kód Repo. RECETOX RI, large research infrastructures. CIISB II, large research infrastructures.
Changed: 13/6/2025 00:49, RNDr. Daniel Jakubík
Abstract
In the original language
Many dynamic interactions within the cell micro-environment modulate cell behavior and cell fate. However, the pathways and mechanisms behind cell-cell or cell-extracellular matrix interactions remain understudied, as they occur at a nanoscale level. Recent progress in nanotechnology allows for mimicking of the microenvironment at nanoscale in vitro; electron-beam lithography (EBL) is currently the most promising technique. Although this nanopatterning technique can generate nanostructures of good quality and resolution, it has resulted, thus far, in the production of only simple shapes (e.g., rectangles) over a relatively small area (100 x 100 mu m), leaving its potential in biological applications unfulfilled. Here, we used EBL for cell-interaction studies by coating cell-culture-relevant material with electron-conductive indium tin oxide, which formed nanopatterns of complex nanohexagonal structures over a large area (500 x 500 mu m). We confirmed the potential of EBL for use in cell-interaction studies by analyzing specific cell responses toward differentially distributed nanohexagons spaced at 1000, 500, and 250 nm. We found that our optimized technique of EBL with HaloTags enabled the investigation of broad changes to a cell-culture-relevant surface and can provide an understanding of cellular signaling mechanisms at a single-molecule level.
