Tunable Narrow Band Emissions from Dye-Sensitized Core/Shell/Shell Nanocrystals in the Second Near-Infrared Biological Window

Shao, Wei; Chen, Guanying; Kuzmin, A.; Kutscher, Hilliard L.; Pliss, Artem; Ohulchanskyy, Tymish Y.; Prasad, Paras N.

doi:10.1021/jacs.6b08973

Cited by 331 publications

(258 citation statements)

References 29 publications

Supporting

Mentioning

256

Contrasting

Unclassified

Order By: Relevance

“…[6] As ar esult of this inherent limitation, ar elatively low doping level of lanthanide activators is generally implemented. [9] However, Figure 1. 10 6 Wcm À2 )h as been demonstrated to effectively alleviate luminescence concentration quenching in nanoparticles with heavily doped activators (ca.…”

mentioning

confidence: 98%

“…10 6 Wcm À2 )h as been demonstrated to effectively alleviate luminescence concentration quenching in nanoparticles with heavily doped activators (ca. [9] However, Figure 1. [8] Another general strategy to prevent the concentration quenching is to implement ac ore-shell design by which the dominant luminescence quenching through energy migration to surface defects can be effectively blocked ( Figure 1a).…”

mentioning

confidence: 98%

See 1 more Smart Citation

Confining Excitation Energy in Er³⁺‐Sensitized Upconversion Nanocrystals through Tm³⁺‐Mediated Transient Energy Trapping

et al. 2017

View full text Add to dashboard Cite

A new class of lanthanide-doped upconversion nanoparticles are presented that are without Yb or Nd sensitizers in the host lattice. In erbium-enriched core-shell NaErF :Tm (0.5 mol %)@NaYF nanoparticles, a high degree of energy migration between Er ions occurs to suppress the effect of concentration quenching upon surface coating. Unlike the conventional Yb -Er system, the Er ion can serve as both the sensitizer and activator to enable an effective upconversion process. Importantly, an appropriate doping of Tm has been demonstrated to further enhance upconversion luminescence through energy trapping. This endows the resultant nanoparticles with bright red (about 700-fold enhancement) and near-infrared luminescence that is achievable under multiple excitation wavelengths. This is a fundamental new pathway to mitigate the concentration quenching effect, thus offering a convenient method for red-emitting upconversion nanoprobes for biological applications.

show abstract

mentioning

confidence: 98%

mentioning

confidence: 98%

Confining Excitation Energy in Er³⁺‐Sensitized Upconversion Nanocrystals through Tm³⁺‐Mediated Transient Energy Trapping

et al. 2017

View full text Add to dashboard Cite

show abstract

“…D) Photographs of tumor from different groups of mice at the end of cancer therapy. [77] More importantly, the www.advancedsciencenews.com www.advtherap.com modified ICG not only increases the NIR-II luminescence but provides a broad excitation spectral range from 700-860 nm, which facilitates their use in bioapplications. [93] Copyright 2018, Wiley-VCH.…”

Section: Optimization Of Rare Earth-doped Nanoprobesmentioning

confidence: 99%

Recent Advance in Near‐Infrared (NIR) Imaging Probes for Cancer Theranostics

Liu

Jia

Zhou

2018

Advanced Therapeutics

View full text Add to dashboard Cite

With the advantages of low biofluid scattering and minimal absorbance, light in a second near-infrared window (NIR II, 1000-1700 nm) either as a signal or as an excitation source is preferred for bioimaging and disease diagnosis, especially for cancer theranostics. Due to recent advances in chemical synthesis and imaging techniques, various NIR II probes have been evaluated for tumor luminescence image-guided cancer therapy and surgery. Furthermore, probes emitting optical, acoustic, or thermal signals under NIR II excitation have also been developed for upconversion luminescence, photoacoustic, and photothermal imaging of tumors. Herein, recent advances in the use of NIR II imaging probes in cancer theranostic applications are summarized along with future perspectives.

show abstract

“…[27] Thanks to the robust chemical synthesis methodologies developed for both bulk and micro/nanoscale materials, it is comparatively easy to manipulate the luminescent properties by means of modulating the composition, crystallographic parameters, sensitizer and activator ions distribution, size, morphology, and surface defects of luminescent materials. By integrating organic dye, indocyanine green (ICG), onto the surface of NaYF 4 :Yb 3+ /X 3+ @NaYbF 4 @NaYF 4 :Nd 3+ (X = null, Er, Ho, Tm, or Pr) core/shell/shell nanocrystals, Shao et al [41] broadened successfully the excitation spectral range (700-860 nm) and increased a set of narrow band emissions located within 1000-1700 nm taking advantage of the large absorption cross section of organic dye and subsequently improved energy transfer efficiency to lanthanide ions; Wisser et al [42] utilized dye ATTO 542 to decorate the surfaces of hexagonal-phase Na(Y/Gd/Lu) 0.8 F 4 :Yb 0.18 Er 0.02 upconverting nanoparticles to enhance the luminescence intensity and also tune the emission color and lifetime, where the Förster resonance energy transfer from Er 3+ to dye and the high radiative rate of the dye play a key role for luminescence manipulation. For example, co-doping of Ce 3+ with Tb 3+ and Eu 3+ at different concentrations within ScPO 4 ·2H 2 O microparticles allows manipulation of the emission wavelengths, intensity, and lifetime [37] ; Increasing the concentration of Tm 3+ /Er 3+ in NaYbF 4 nanoparticles could impact the energy transfer process between sensitizer Yb 3+ and activator Tm 3+ /Er 3+ , leading to the upconversion color tuning from blue/green to red [38] ; Zhuo et al [39] distributed multiple activators (Tm 3+ , Er 3+ , and Ho 3+ ) into spatially separated layers in one single KSc 2 F 7 nanorod to effectively restrain the deleterious energy transfer between these activators and enhance their www.advancedsciencenews.com www.ann-phys.org upconversion luminescence.…”

Section: Introductionmentioning

confidence: 99%

Physical Manipulation of Lanthanide‐Activated Photoluminescence

et al. 2019

View full text Add to dashboard Cite

Versatile manipulation of lanthanide photoluminescence not only enables a more thorough understanding of the luminescent mechanism, but also promotes their widespread applications including advanced display and security, bioimaging and biotherapy, and sensors. The traditional chemical methods, engineering of composition, concentration, size, morphology, and surface defects, can easily tune the excitation, energy transfer and emission processes and have been frequently used. Despite the powerful ability to control luminescence intensity and selectivity, these chemical approaches suffer from cumbersome synthesis processes and are usually time consuming and irreversible. Recently, there have been numerous examples of physical approaches realizing in situ, real time, and reversible luminescence manipulation for certain materials under a given excitation. Herein, the existing physical strategies comprising temperature, magnetic field, electric field, and mechanical stress are summarized. For each approach, the action mechanism, material design, applications, as well as current challenges are discussed, and possible development directions and broadening of the potential application areas are considered. Applying Magnetic FieldMagneto-optic interaction, here mainly refers to the effect of applied magnetic field during luminescence measurement, was also widely utilized to regulate luminescence emission of not

show abstract

Tunable Narrow Band Emissions from Dye-Sensitized Core/Shell/Shell Nanocrystals in the Second Near-Infrared Biological Window

Cited by 331 publications

References 29 publications

Confining Excitation Energy in Er³⁺‐Sensitized Upconversion Nanocrystals through Tm³⁺‐Mediated Transient Energy Trapping

Confining Excitation Energy in Er³⁺‐Sensitized Upconversion Nanocrystals through Tm³⁺‐Mediated Transient Energy Trapping

Recent Advance in Near‐Infrared (NIR) Imaging Probes for Cancer Theranostics

Physical Manipulation of Lanthanide‐Activated Photoluminescence

Contact Info

Product

Resources

About

Tunable Narrow Band Emissions from Dye-Sensitized Core/Shell/Shell Nanocrystals in the Second Near-Infrared Biological Window

Cited by 331 publications

References 29 publications

Confining Excitation Energy in Er3+‐Sensitized Upconversion Nanocrystals through Tm3+‐Mediated Transient Energy Trapping

Confining Excitation Energy in Er3+‐Sensitized Upconversion Nanocrystals through Tm3+‐Mediated Transient Energy Trapping

Recent Advance in Near‐Infrared (NIR) Imaging Probes for Cancer Theranostics

Physical Manipulation of Lanthanide‐Activated Photoluminescence

Contact Info

Product

Resources

About

Confining Excitation Energy in Er³⁺‐Sensitized Upconversion Nanocrystals through Tm³⁺‐Mediated Transient Energy Trapping

Confining Excitation Energy in Er³⁺‐Sensitized Upconversion Nanocrystals through Tm³⁺‐Mediated Transient Energy Trapping