Photostable phosphorescent polymer nanospheres for high sensitivity detection

Edwards, A. N.; Yamazaki, M.; Krishnadasan, Siva H.; Phillips, T. W.; Rowlands, Lucy J; Jourdain, Roxane; Nightingale, Adrian M.; Mello, John C. de

doi:10.1039/c5tc00933b

Cited by 6 publications

(7 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Despite these benefits, the process offers very little control because of the 193 (b) RAFT polymerization of Fe 3 O 4 @poly(methacrylic acid). 189 (c) Co-precipitation of the encoding element and the polymer to form the barcodes, 196 and (d) Solvothermal method to prepare differently shaped barcodes based on different ratios of Ag + PVP dispersed in DMF solvent. 199 (e) Sol-gel method to prepare QD encoded SiO 2 beads.…”

Section: Embeddingmentioning

confidence: 99%

See 1 more Smart Citation

Versatile design and synthesis of nano-barcodes

et al. 2017

View full text Add to dashboard Cite

Encoded nano-structures/particles have been used for barcoding and are in great demand for the simultaneous analysis of multiple targets. Due to their nanoscale dimension(s), nano-barcodes have been implemented favourably for bioimaging, in addition to their security and multiplex bioassay application. In designing nano-barcodes for a specific application, encoding techniques, synthesis strategies, and decoding techniques need to be considered. The encoding techniques to generate unique multiple codes for nano-barcodes are based on certain encoding elements including optical (fluorescent and non-fluorescent), graphical, magnetic, and phase change properties of nanoparticles or their different shapes and sizes. These encoding elements can generally be embedded inside, decorated on the surface of nanostructures or self-assembled to prepare the nano-barcodes. The decoding techniques for each encoding technique are different and need to be suitable for the desired applications. This review will provide a thorough discussion on designing nano-barcodes, focusing on the encoding techniques, synthesis methods, and decoding for applications including bio-detection, imaging, and anti-counterfeiting. Additionally, associated challenges in the field and potential solutions will also be discussed. We believe that a comprehensive understanding on this topic could significantly contribute towards the advancement of nano-barcodes for a broad spectrum of applications.

show abstract

Section: Embeddingmentioning

confidence: 99%

“…In this strategy, encoding elements are co-precipitated with polymers to form encoded nanospheres. [196][197][198] Lipophilic encoding elements and amphiphilic polymers (insoluble in a water-organic solvent mixture) are co-dissolved in a small amount of organic solvent miscible in water (Fig. 14c).…”

Section: Embeddingmentioning

confidence: 99%

Versatile design and synthesis of nano-barcodes

et al. 2017

View full text Add to dashboard Cite

show abstract

“…The use of polymers for encapsulation of phosphorescent dyes is particularly advantageous for bioimaging, since the size of the nanospheres can be tuned by controlling the polymer chain length, while inclusion of appropriate functional groups can be used to tailor the nanosphere surface to provide biocompatibility or to attach bioactive molecules [38].…”

Section: Nanoparticle-loaded Phosphorescent Dyesmentioning

confidence: 99%

“…Subsequent crosslinking of the polymer chains provides high quantum efficiencies and better photostability to equivalent noncrosslinked nanospheres due to a better protection of the phosphors against oxygen and other emission quenchers [41]. Recently, the use of small-molecule crosslinking agents, such as bisphenol A diglycidyl ether (BPA) in conjunction with a single amphiphilic polymer, has been proposed as an alternative to the use of multiple polymers with crossreactive functional groups, achieving a better control over the size, morphology and surface chemistry of the nanospheres [38] as shown on Figure 4.…”

Section: Nanoparticle-loaded Phosphorescent Dyesmentioning

confidence: 99%

“…By using a pulsed excitation source and measuring the phosphorescence emission after a "delay time", it is possible to eliminate any contribution that comes from the excitation source or from the fluorescent background. Therefore, phosphorescence-based methodologies are an excellent option to develop analytical strategies in biological media where scattering macromolecules and luminescent species abound [38]. Detection of glucose was also performed based on quenching of the phosphorescence.…”

Section: Biosensing Applications Using Phosphorescent Nanoprobes As Lmentioning

confidence: 99%

See 1 more Smart Citation

Functionalized phosphorescent nanoparticles in (bio)chemical sensing and imaging – A review

Llano-Suárez

García-Cortés

Fernández-Argüelles

et al. 2019

Analytica Chimica Acta

View full text Add to dashboard Cite

Inorganic nanoparticles are a fascinating class of materials which promise great potential in numerous fields, including optical (bio)sensing. Many different kinds of such nanoparticles have been widely used for fluorescent sensing and imaging due to the different merits of fluorescent nanoparticles compared to molecular fluorophores.Progress made in the rational design of nanomaterials also allowed the synthesis of hybrid phosphorescent nanoparticles, that finds growing applications in sensing due to the combination of the interesting size-and shape-dependent properties of nanomaterials with a phosphorescence-type emission.In this review, we intend to highlight some of progress made in this active research area and update the database of various phosphorescent nanoparticles-based sensors on the basis of different sensing targets of interest in environmental, industrial and biomedical areas.Following an introduction and a discussion of merits of the synergy between nanomaterials and phosphorescence detection as compared to molecular luminophores the article assesses the kinds and specific features of nanomaterials often used in phosphorescence sensing. Specific examples on the use of phosphorescence nanoparticles in chemical sensing and bioimaging are given next. A final section intends to provide an overview of the prospects of such type of nanomaterials in the design of future devices for analytical chemistry.

show abstract