A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Nanoplasmonic Single‐Tumoroid Microarray for Real‐Time Secretion Analysis
https://orcid.org/0000-0002-7000-3245
AbstractOrganoid tumor models have emerged as a powerful tool in the fields of biology and medicine as such 3D structures grown from tumor cells recapitulate better tumor characteristics, making these tumoroids unique for personalized cancer research. Assessment of their functional behavior, particularly protein secretion, is of significant importance to provide comprehensive insights. Here, a label‐free spectroscopic imaging platform is presented with advanced integrated optofluidic nanoplasmonic biosensor that enables real‐time secretion analysis from single tumoroids. A novel two‐layer microwell design isolates tumoroids, preventing signal interference, and the microarray configuration allows concurrent analysis of multiple tumoroids. The dual imaging capability combining time‐lapse plasmonic spectroscopy and bright‐field microscopy facilitates simultaneous observation of secretion dynamics, motility, and morphology. The integrated biosensor is demonstrated with colorectal tumoroids derived from both cell lines and patient samples to investigate their vascular endothelial growth factor A (VEGF‐A) secretion, growth, and movement under various conditions, including normoxia, hypoxia, and drug treatment. This platform, by offering a label‐free approach with nanophotonics to monitor tumoroids, can pave the way for new applications in fundamental biological studies, drug screening, and the development of therapies.
Nanoplasmonic Single‐Tumoroid Microarray for Real‐Time Secretion Analysis
https://orcid.org/0000-0002-7000-3245
AbstractOrganoid tumor models have emerged as a powerful tool in the fields of biology and medicine as such 3D structures grown from tumor cells recapitulate better tumor characteristics, making these tumoroids unique for personalized cancer research. Assessment of their functional behavior, particularly protein secretion, is of significant importance to provide comprehensive insights. Here, a label‐free spectroscopic imaging platform is presented with advanced integrated optofluidic nanoplasmonic biosensor that enables real‐time secretion analysis from single tumoroids. A novel two‐layer microwell design isolates tumoroids, preventing signal interference, and the microarray configuration allows concurrent analysis of multiple tumoroids. The dual imaging capability combining time‐lapse plasmonic spectroscopy and bright‐field microscopy facilitates simultaneous observation of secretion dynamics, motility, and morphology. The integrated biosensor is demonstrated with colorectal tumoroids derived from both cell lines and patient samples to investigate their vascular endothelial growth factor A (VEGF‐A) secretion, growth, and movement under various conditions, including normoxia, hypoxia, and drug treatment. This platform, by offering a label‐free approach with nanophotonics to monitor tumoroids, can pave the way for new applications in fundamental biological studies, drug screening, and the development of therapies.
Nanoplasmonic Single‐Tumoroid Microarray for Real‐Time Secretion Analysis
https://orcid.org/0000-0002-7000-3245
AbstractOrganoid tumor models have emerged as a powerful tool in the fields of biology and medicine as such 3D structures grown from tumor cells recapitulate better tumor characteristics, making these tumoroids unique for personalized cancer research. Assessment of their functional behavior, particularly protein secretion, is of significant importance to provide comprehensive insights. Here, a label‐free spectroscopic imaging platform is presented with advanced integrated optofluidic nanoplasmonic biosensor that enables real‐time secretion analysis from single tumoroids. A novel two‐layer microwell design isolates tumoroids, preventing signal interference, and the microarray configuration allows concurrent analysis of multiple tumoroids. The dual imaging capability combining time‐lapse plasmonic spectroscopy and bright‐field microscopy facilitates simultaneous observation of secretion dynamics, motility, and morphology. The integrated biosensor is demonstrated with colorectal tumoroids derived from both cell lines and patient samples to investigate their vascular endothelial growth factor A (VEGF‐A) secretion, growth, and movement under various conditions, including normoxia, hypoxia, and drug treatment. This platform, by offering a label‐free approach with nanophotonics to monitor tumoroids, can pave the way for new applications in fundamental biological studies, drug screening, and the development of therapies.
Nanoplasmonic Single‐Tumoroid Microarray for Real‐Time Secretion Analysis
Advanced Science
Liu, Yen‐Cheng (author) / Ansaryan, Saeid (author) / Tan, Jiayi (author) / Broguiere, Nicolas (author) / Lorenzo‐Martín, Luis Francisco (author) / Homicsko, Krisztian (author) / Coukos, George (author) / Lütolf, Matthias P. (author) / Altug, Hatice (author)
2024-06-24
Article (Journal)
Electronic Resource
English
Nanoplasmonic Single‐Tumoroid Microarray for Real‐Time Secretion Analysis
| Wiley | 2024
Nanoplasmonic Single‐Tumoroid Microarray for Real‐Time Secretion Analysis (Adv. Sci. 34/2024)
| Wiley | 2024
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