Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform

Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform

Photonic crystal (PC) barcodes are a new type of spectrum-encoding microcarriers used in multiplex high-throughput bioassays, such as broad analysis of biomarkers for clinical diagnosis, gene expression, and cell culture. Unfortunately, most of these existing PC barcodes suffered from undesired feat...

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Main Authors: Panmiao Liu, Zhongde Mu, Muhuo Ji, Xiaojiang Liu, Hanwen Gu, Yi Peng, Jianjun Yang, Zhuoying Xie, Fuyin Zheng
Format: Article
Language:English
Published: American Association for the Advancement of Science 2021-01-01
Series:Research
Online Access:http://dx.doi.org/10.34133/2021/9851609
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spelling doaj-57607cbeb703420982dc9968ee4a3fd52021-05-24T12:55:32ZengAmerican Association for the Advancement of ScienceResearch2639-52742021-01-01202110.34133/2021/9851609Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture PlatformPanmiao Liu0Zhongde Mu1Muhuo Ji2Xiaojiang Liu3Hanwen Gu4Yi Peng5Jianjun Yang6Zhuoying Xie7Fuyin Zheng8Department of Anesthesiology,Pain and Perioperative Medicine,The First Affiliated Hospital of Zhengzhou University,Zhengzhou, 450052,ChinaJiangsu Cancer Hospital & Jiangsu Institute of Cancer Research & The Affiliated Cancer Hospital of Nanjing Medical University,Nanjing 210009,ChinaDepartment of Anesthesiology,The Second Affiliated Hospital,Nanjing Medical University,Nanjing,ChinaState Key Laboratory of Bioelectronics,School of Biological Science and Medical Engineering,Southeast University,Nanjing, 210096,ChinaDepartment of Anesthesiology,Pain and Perioperative Medicine,The First Affiliated Hospital of Zhengzhou University,Zhengzhou, 450052,ChinaJiangsu Cancer Hospital & Jiangsu Institute of Cancer Research & The Affiliated Cancer Hospital of Nanjing Medical University,Nanjing 210009,ChinaDepartment of Anesthesiology,Pain and Perioperative Medicine,The First Affiliated Hospital of Zhengzhou University,Zhengzhou, 450052,ChinaState Key Laboratory of Bioelectronics,School of Biological Science and Medical Engineering,Southeast University,Nanjing, 210096,ChinaKey Laboratory for Biomechanics and Mechanobiology,Beijing Advanced Innovation Center for Biomedical Engineering,School of Biological Science and Medical Engineering,Beihang University, Beijing 100083,ChinaPhotonic crystal (PC) barcodes are a new type of spectrum-encoding microcarriers used in multiplex high-throughput bioassays, such as broad analysis of biomarkers for clinical diagnosis, gene expression, and cell culture. Unfortunately, most of these existing PC barcodes suffered from undesired features, including difficult spectrum-signal acquisition, weak mechanical strength, and high ontology fluorescence, which limited their development to real applications. To address these limitations, we report a new type of structural color-encoded PC barcodes. The barcodes are fabricated by the assembly of monodisperse polydopamine- (PDA-) coated silica (PDA@SiO2) nanoparticles using a droplet-based microfluidic technique and followed by pyrolysis of PDA@SiO2 (C@SiO2) barcodes. Because of the templated carbonization of adhesive PDA, the prepared C@SiO2 PC beads were endowed with simultaneous easy-to-identify structural color, high mechanical strength, and ultralow ontology fluorescence. We demonstrated that the structural colored C@SiO2 barcodes not only maintained a high structural stability and good biocompatibility during the coculturing with fibroblasts and tumor cells capture but also achieved an enhanced fluorescent-reading signal-to-noise ratio in the fluorescence-reading detection. These features make the C@SiO2 PC barcodes versatile for expansive application in fluorescence-reading-based multibioassays.http://dx.doi.org/10.34133/2021/9851609
collection DOAJ
language English
format Article
sources DOAJ
author Panmiao Liu
Zhongde Mu
Muhuo Ji
Xiaojiang Liu
Hanwen Gu
Yi Peng
Jianjun Yang
Zhuoying Xie
Fuyin Zheng
spellingShingle Panmiao Liu
Zhongde Mu
Muhuo Ji
Xiaojiang Liu
Hanwen Gu
Yi Peng
Jianjun Yang
Zhuoying Xie
Fuyin Zheng
Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform
Research
author_facet Panmiao Liu
Zhongde Mu
Muhuo Ji
Xiaojiang Liu
Hanwen Gu
Yi Peng
Jianjun Yang
Zhuoying Xie
Fuyin Zheng
author_sort Panmiao Liu
title Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform
title_short Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform
title_full Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform
title_fullStr Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform
title_full_unstemmed Robust Carbonated Structural Color Barcodes with Ultralow Ontology Fluorescence as Biomimic Culture Platform
title_sort robust carbonated structural color barcodes with ultralow ontology fluorescence as biomimic culture platform
publisher American Association for the Advancement of Science
series Research
issn 2639-5274
publishDate 2021-01-01
description Photonic crystal (PC) barcodes are a new type of spectrum-encoding microcarriers used in multiplex high-throughput bioassays, such as broad analysis of biomarkers for clinical diagnosis, gene expression, and cell culture. Unfortunately, most of these existing PC barcodes suffered from undesired features, including difficult spectrum-signal acquisition, weak mechanical strength, and high ontology fluorescence, which limited their development to real applications. To address these limitations, we report a new type of structural color-encoded PC barcodes. The barcodes are fabricated by the assembly of monodisperse polydopamine- (PDA-) coated silica (PDA@SiO2) nanoparticles using a droplet-based microfluidic technique and followed by pyrolysis of PDA@SiO2 (C@SiO2) barcodes. Because of the templated carbonization of adhesive PDA, the prepared C@SiO2 PC beads were endowed with simultaneous easy-to-identify structural color, high mechanical strength, and ultralow ontology fluorescence. We demonstrated that the structural colored C@SiO2 barcodes not only maintained a high structural stability and good biocompatibility during the coculturing with fibroblasts and tumor cells capture but also achieved an enhanced fluorescent-reading signal-to-noise ratio in the fluorescence-reading detection. These features make the C@SiO2 PC barcodes versatile for expansive application in fluorescence-reading-based multibioassays.
url http://dx.doi.org/10.34133/2021/9851609
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