Ultrastable and Biocompatible NIR‐II Quantum Dots for Functional Bioimaging

Fluorescence bioimaging in the second near‐infrared spectral region (NIR‐II, 1000–1700 nm) can provide advantages of high spatial resolution and large penetration depth, due to low light scattering. However, NIR‐II fluorophores simultaneously possessing high brightness, good stability, and biocompat...

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Veröffentlicht in:	Advanced functional materials 2018-02, Vol.28 (9), p.n/a
Hauptverfasser:	Zebibula, Abudureheman, Alifu, Nuernisha, Xia, Liqun, Sun, Chaowei, Yu, Xiaoming, Xue, Dingwei, Liu, Liwei, Li, Gonghui, Qian, Jun
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Schlagworte:	Biocompatibility Biomedical materials Blood vessels Brain brain vascular imaging Cadmium sulfide Chemical compounds Chemical synthesis Fluorescence gastrointestinal tract imaging in vivo imaging Lead sulfides Materials science Medical imaging Nanoparticles NIR‐II fluorescence imaging Penetration depth Protective coatings Quantum dots Silicon dioxide Spatial resolution Stability Toxicity
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description	Fluorescence bioimaging in the second near‐infrared spectral region (NIR‐II, 1000–1700 nm) can provide advantages of high spatial resolution and large penetration depth, due to low light scattering. However, NIR‐II fluorophores simultaneously possessing high brightness, good stability, and biocompatibility are very rare. Hydrophobic NIR‐II emissive PbS@CdS quantum dots (QDs) are surface‐functionalized, via a silica and amphiphilic polymer (Pluronic F‐127) dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible and possess a quantum yield of ≈5.79%, which is much larger than those of most existing NIR‐II fluorophores. Thanks to the dual‐layer protection, PbS@CdS@SiO2@F‐127 NPs show excellent chemical stability in a wide range of pH values. The biocompatibility of PbS@CdS@SiO2@F‐127 NPs is studied, and the results show that the toxicity of the NPs in vivo could be minimal. PbS@CdS@SiO2@F‐127 NPs are then utilized for in vivo and real‐time NIR‐II fluorescence microscopic imaging of mouse brain. The architecture of blood vessels is visualized and the imaging depth reaches 950 µm. Furthermore, in vivo NIR‐II fluorescence imaging of gastrointestinal tract is achieved, by perfusing PbS@CdS@SiO2@F‐127 NPs into mice at a rather low dosage. This work illustrates the potential of ultrastable, biocompatible, and bright NIR‐II QDs in biomedical and clinical applications, which require deep tissue imaging. NIR‐II emissive PbS@CdS quantum dots are surface‐functionalized with a dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible, and possess certain brightness. Chemically stable and biocompatible PbS@CdS@SiO2@F‐127 NPs are utilized for deep tissue (950 µm) in vivo microscopic angiography of the mice brain. Noninvasive and large depth (3–5 mm) gastrointestinal tract imaging with high contrast is achieved.
doi_str_mv	10.1002/adfm.201703451
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However, NIR‐II fluorophores simultaneously possessing high brightness, good stability, and biocompatibility are very rare. Hydrophobic NIR‐II emissive PbS@CdS quantum dots (QDs) are surface‐functionalized, via a silica and amphiphilic polymer (Pluronic F‐127) dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible and possess a quantum yield of ≈5.79%, which is much larger than those of most existing NIR‐II fluorophores. Thanks to the dual‐layer protection, PbS@CdS@SiO2@F‐127 NPs show excellent chemical stability in a wide range of pH values. The biocompatibility of PbS@CdS@SiO2@F‐127 NPs is studied, and the results show that the toxicity of the NPs in vivo could be minimal. PbS@CdS@SiO2@F‐127 NPs are then utilized for in vivo and real‐time NIR‐II fluorescence microscopic imaging of mouse brain. The architecture of blood vessels is visualized and the imaging depth reaches 950 µm. Furthermore, in vivo NIR‐II fluorescence imaging of gastrointestinal tract is achieved, by perfusing PbS@CdS@SiO2@F‐127 NPs into mice at a rather low dosage. This work illustrates the potential of ultrastable, biocompatible, and bright NIR‐II QDs in biomedical and clinical applications, which require deep tissue imaging. NIR‐II emissive PbS@CdS quantum dots are surface‐functionalized with a dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible, and possess certain brightness. Chemically stable and biocompatible PbS@CdS@SiO2@F‐127 NPs are utilized for deep tissue (950 µm) in vivo microscopic angiography of the mice brain. 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However, NIR‐II fluorophores simultaneously possessing high brightness, good stability, and biocompatibility are very rare. Hydrophobic NIR‐II emissive PbS@CdS quantum dots (QDs) are surface‐functionalized, via a silica and amphiphilic polymer (Pluronic F‐127) dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible and possess a quantum yield of ≈5.79%, which is much larger than those of most existing NIR‐II fluorophores. Thanks to the dual‐layer protection, PbS@CdS@SiO2@F‐127 NPs show excellent chemical stability in a wide range of pH values. The biocompatibility of PbS@CdS@SiO2@F‐127 NPs is studied, and the results show that the toxicity of the NPs in vivo could be minimal. PbS@CdS@SiO2@F‐127 NPs are then utilized for in vivo and real‐time NIR‐II fluorescence microscopic imaging of mouse brain. The architecture of blood vessels is visualized and the imaging depth reaches 950 µm. Furthermore, in vivo NIR‐II fluorescence imaging of gastrointestinal tract is achieved, by perfusing PbS@CdS@SiO2@F‐127 NPs into mice at a rather low dosage. This work illustrates the potential of ultrastable, biocompatible, and bright NIR‐II QDs in biomedical and clinical applications, which require deep tissue imaging. NIR‐II emissive PbS@CdS quantum dots are surface‐functionalized with a dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible, and possess certain brightness. Chemically stable and biocompatible PbS@CdS@SiO2@F‐127 NPs are utilized for deep tissue (950 µm) in vivo microscopic angiography of the mice brain. Noninvasive and large depth (3–5 mm) gastrointestinal tract imaging with high contrast is achieved.</description><subject>Biocompatibility</subject><subject>Biomedical materials</subject><subject>Blood vessels</subject><subject>Brain</subject><subject>brain vascular imaging</subject><subject>Cadmium sulfide</subject><subject>Chemical compounds</subject><subject>Chemical synthesis</subject><subject>Fluorescence</subject><subject>gastrointestinal tract imaging</subject><subject>in vivo imaging</subject><subject>Lead sulfides</subject><subject>Materials science</subject><subject>Medical imaging</subject><subject>Nanoparticles</subject><subject>NIR‐II fluorescence imaging</subject><subject>Penetration depth</subject><subject>Protective coatings</subject><subject>Quantum dots</subject><subject>Silicon dioxide</subject><subject>Spatial resolution</subject><subject>Stability</subject><subject>Toxicity</subject><issn>1616-301X</issn><issn>1616-3028</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2018</creationdate><recordtype>article</recordtype><recordid>eNqFkEFLwzAUx4MoOKdXzwXPnS9J27THuTktTEVx4C2kaTI62mYmLbKbH8HP6CcxZTKPnt7j8fs9_vwRusQwwQDkWpS6mRDADGgU4yM0wglOQgokPT7s-O0UnTm3AY8xGo3Qw6rurHCdKGoViLYMbiojTbMVXTVcHvOX78-vPA-ee9F2fRPMTecCbWyw6FvZVaYV9aBUjVhX7focnWhRO3XxO8dotbh9nd2Hy6e7fDZdhpKmFIdKp1kpmCiygihWFioqsKSQEAIaizIjiRQ6hdRjhee1pIyqFGKcYRwxHdMxutr_3Vrz3ivX8Y3prc_iOAFgWRRHJPHUZE9Ja5yzSvOt9UHtjmPgQ2V8qIwfKvNCthc-qlrt_qH5dL54-HN_AJOLcDQ</recordid><startdate>20180228</startdate><enddate>20180228</enddate><creator>Zebibula, Abudureheman</creator><creator>Alifu, Nuernisha</creator><creator>Xia, Liqun</creator><creator>Sun, Chaowei</creator><creator>Yu, Xiaoming</creator><creator>Xue, Dingwei</creator><creator>Liu, Liwei</creator><creator>Li, Gonghui</creator><creator>Qian, Jun</creator><general>Wiley Subscription Services, Inc</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7SP</scope><scope>7SR</scope><scope>7U5</scope><scope>8BQ</scope><scope>8FD</scope><scope>JG9</scope><scope>L7M</scope></search><sort><creationdate>20180228</creationdate><title>Ultrastable and Biocompatible NIR‐II Quantum Dots for Functional Bioimaging</title><author>Zebibula, Abudureheman ; 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However, NIR‐II fluorophores simultaneously possessing high brightness, good stability, and biocompatibility are very rare. Hydrophobic NIR‐II emissive PbS@CdS quantum dots (QDs) are surface‐functionalized, via a silica and amphiphilic polymer (Pluronic F‐127) dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible and possess a quantum yield of ≈5.79%, which is much larger than those of most existing NIR‐II fluorophores. Thanks to the dual‐layer protection, PbS@CdS@SiO2@F‐127 NPs show excellent chemical stability in a wide range of pH values. The biocompatibility of PbS@CdS@SiO2@F‐127 NPs is studied, and the results show that the toxicity of the NPs in vivo could be minimal. PbS@CdS@SiO2@F‐127 NPs are then utilized for in vivo and real‐time NIR‐II fluorescence microscopic imaging of mouse brain. The architecture of blood vessels is visualized and the imaging depth reaches 950 µm. Furthermore, in vivo NIR‐II fluorescence imaging of gastrointestinal tract is achieved, by perfusing PbS@CdS@SiO2@F‐127 NPs into mice at a rather low dosage. This work illustrates the potential of ultrastable, biocompatible, and bright NIR‐II QDs in biomedical and clinical applications, which require deep tissue imaging. NIR‐II emissive PbS@CdS quantum dots are surface‐functionalized with a dual‐layer coating method. The as‐synthesized PbS@CdS@SiO2@F‐127 nanoparticles (NPs) are aqueously dispersible, and possess certain brightness. Chemically stable and biocompatible PbS@CdS@SiO2@F‐127 NPs are utilized for deep tissue (950 µm) in vivo microscopic angiography of the mice brain. Noninvasive and large depth (3–5 mm) gastrointestinal tract imaging with high contrast is achieved.</abstract><cop>Hoboken</cop><pub>Wiley Subscription Services, Inc</pub><doi>10.1002/adfm.201703451</doi><tpages>13</tpages></addata></record>
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subjects	Biocompatibility Biomedical materials Blood vessels Brain brain vascular imaging Cadmium sulfide Chemical compounds Chemical synthesis Fluorescence gastrointestinal tract imaging in vivo imaging Lead sulfides Materials science Medical imaging Nanoparticles NIR‐II fluorescence imaging Penetration depth Protective coatings Quantum dots Silicon dioxide Spatial resolution Stability Toxicity
title	Ultrastable and Biocompatible NIR‐II Quantum Dots for Functional Bioimaging
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