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Correction to “Recent advances in non-plasmonic surface-enhanced Raman spectroscopy nanostructures for biomedical applications”
WIREs Nanomedicine and Nanobiotechnology ( IF 8.6 ) Pub Date : 2023-09-06 , DOI: 10.1002/wnan.1926
TABLE 1. Substrates for nonplasmonic detection with excitation laser wavelengths λex, reference molecular probe, limit of detection, and maximum enhancement factors (EF).
TABLE 2. Nanomaterials for nonplasmonic SERS detection and biomedical applications (see icon in Figure 9).
中文翻译:
对“生物医学应用非等离子体表面增强拉曼光谱纳米结构的最新进展”的更正
表 1.用于使用激发激光波长λ ex进行非等离子体检测的基质、参考分子探针、检测限和最大增强因子 (EF)。
表 2.用于非等离子体 SERS 检测和生物医学应用的纳米材料(见图 9 中的图标)。
更新日期:2023-09-06
WIREs Nanomedicine and Nanobiotechnology ( IF 8.6 ) Pub Date : 2023-09-06 , DOI: 10.1002/wnan.1926
Li, D., Aubertin, K., Onidas, D., Nizard, P., Félidj, N., Gazeau, F., Mangeney, C., & Luo, Y. (2022). Recent advances in non-plasmonic surface-enhanced Raman spectroscopy nanostructures for biomedical applications. WIREs Nanomedicine and Nanobiotechnology, e1795. https://doi.org/10.1002/wnan.1795
In the originally published version of this article, the format of the references in Tables 1 and 2 did not match the format of the final reference list. The corrected tables with the references written in the correct format have been included in this correction.
| Substrate (laser lex) | Probe | LOD (M) | Enhancement factor (EF) | References |
|---|---|---|---|---|
| Carbons | ||||
| 0D graphene quantum dots (GQDs) | ||||
| GQDs-Mn3O4 (λex = 514 nm) | Rhodamine B | – | 2.06 × 104 | Lan et al., 2017 |
| N-GQDs (λex = 488 nm) | Rhodamine B | 10−10 | 3.2 × 103 | Das et al., 2020 |
| 1D carbon nanotubes (CNTs) | ||||
| R/L-CNTs/TiO2 (λex = 532 nm) | Methylene blue | 5 × 10−5 | – | Qiu et al., 2015 |
| 2D graphene | ||||
| EG-TiO2 (λex = 633 nm) | CuPc | 6 × 10−5 (2.07 × 10−16 IU) | 48.2 | Zheng et al., 2017 |
| Graphene flask (λex = 633 nm) | Hemoglobin | – | 4.5 | Huang et al., 2018 |
| GMFs/W-MoS2 (λex = 632.8 nm) | Rhodamine B | 5 × 10−11 | 2.96 × 107 | Qiu et al., 2020 |
| 3D interconnected nanocarbon web (INW) | ||||
| INW (λex = 785 nm) | Crystal violet | – | 3.66 × 104 | Chowdhury et al., 2018 |
| Oxides | ||||
| Zinc oxide | ||||
| Amorphous ZnO nanocages (λex = 633 nm) | 4-MBA, 4-MPY, and 4-ATP | 10−4 | 6.62 × 105 | Wang et al., 2017 |
| ZnO quantum probe (λex = 785 nm) | Crystal violet and rhodamine 6G, 4-adenosine tri-phosphate, 4-mercaptobenzoic | 10−9 | 1.4–6.9 × 106 | Haldavnekar et al., 2018 |
| Titanium oxide | ||||
| Quantum-structured TiOx (λex = 785 nm) | Crystal violet | 10−9 | 3.4 × 107 | Keshavarz et al., 2020 |
| Crystal-amorphous core-shell TiO2 (λex = 532 nm) | 4-Nitrobenzenthiol | 5 × 10−4 | 4.3 × 105 | Lin et al., 2020 |
| Silica NPs coated with TiO2 (λex = 783 nm) | Methylene blue and dopamine | 10−2 | 3.63 × 104 | Liu et al., 2019 |
| Atomic-defect quantum probe of TiO2 (λex = 785 nm) | Crystal violet | 10−9 | 1010 | Dharmalingam et al., 2019 |
| TiO2 inverse opal substrate (λex = 532 nm) | Methylene blue | 10−5 | 2.0 × 104 | Qi et al., 2014 |
| Copper and tungsten oxide | ||||
| Cu2O cubic super structure (λex = 647 nm) | Rhodamine 6G Crystal violet Methyl Blue Methyl Orange |
10−7 | 1.5 × 104–8 × 105 | Lin et al., 2017 |
| WO3−x (λex = 532.8 nm) | Rhodamine 6G | 10−7 | 3.4 × 105 | Cong et al., 2015 |
| Transition metal chalcogenides | ||||
| 0D transition metal chalcogenides | ||||
| ZnS nanocrystals (λex = 514.5 nm) | 4-Mercaptopyridine | 10−6 | 103 | Wang et al., 2007 |
| CuS microflowers (λex = 532 or 633 nm) | Crystal violet, malachite green, rhodamine 6G | 10−8 for MG 10−7 for R6G and CV |
105 | Zhou et al., 2021 |
| Multi-branched CuS nanodendrites | Crystal violet | 10−10 | – | Li et al., 2017 |
| Hollow CuS NPs (λex = 785 nm) | 3,3′-diethylthiatricarbocyanine iodide | 10−12 | 3.9 × 102–4.6 × 104 | Qiu et al., 2019 |
| 2D transition metal chalcogenides | ||||
| 2D MoS2 monolayer (λex = 488 nm) | 4-Mercaptopyridine | – | ~105 | Muehlethaler et al., 2016 |
| Oxygen incorporated MoS2 (λex = 532.8 nm) | Rhodamine 6G | Below 10−7 | ~105 | Zheng et al., 2017 |
| MoS2 microspheres with different interlayered spacings (λex = 785 nm) | 4-mercaptopyridine (4-MPy), 4-mercaptobenzoic acid (4-MBA), and 4-aminothiophenol (4-ATP) | – | 5.31 × 105 | Li et al., 2020 |
| Ultrathin 2D NbS2 | Methylene blue | 10−14 | ~103 | Song et al., 2019 |
| Large-area NbSe2 flakes from monolayer to few-layer | Rhodamine 6G | 5 × 10−16 | – | Lv et al., 2021 |
| Ternary ZnO/ZnS/MoS2 nanoflake composite | Rhodamine 6G | 10−9 | 1.4 × 108 | Yin et al., 2019 |
| Polymers, telluride and Si | ||||
| DFH-4T films (λex = 785 nm) | Methylene blue | – | 3.4 ± 1.3 × 103 | Yilmaz et al., 2017 |
| PEDOT:PSS film (λex = 514 nm) | Methylene blue | – | 2.26 × 103 | Zhang et al., 2020 |
| 2D 1T′-W(Mo)Te2 layers (λex = 532 nm) | Rhodamine 6G | 40 (400) fM | 1.8 × 109 | Tao et al., 2018 |
| MIL-100(Fe) MOF array (λex = 785 nm) | Toluene, acetone, and chloroform | 2.5, 20 and 92.7 ppm | 105 | Fu et al., 2020 |
| 3D nQS Si nanomesh (λex = 532 and 785 nm) | l-Glutathione, tryptophan, cysteine, and methionine | 10−9 M | ∼102 | Powell et al., 2017 |
| Nanomaterials | Surface functionalization | Application | References | |
|---|---|---|---|---|
| GQDs–Mn3O4 nanocomposite | 
|
Identification of cancer cells from normal cells | 
|
Lan et al., 2017 |
| Monolayer graphene flakes | 
|
Sensing of hemoglobin and albumin | 
|
Huang et al., 2018 |
| Interconnected nanocarbon web (INW) | 
|
In vitro detection and differentiation of HeLa cells and fibroblasts | 
|
Chowdhury et al., 2018 |
| Graphene–TiO2 nanocomposites | 
|
Real-time monitoring of telomerase activity in stem cells | 
|
Zheng et al., 2017 |
| SiO2/TiO2 core–shell beads | 
|
Monitor the redox cycle of glutathione at physiological concentration as homeostasis model | 
|
Alessandri et al., 2014 |
| Nano denstrite supported ZnO quantum probe | 
|
Identification of cancer cells from normal cells | 
|
Haldavnekar et al., 2018 |
| Crystal−amorphous core−shell TiO2 | 
|
Cancer cell imaging | 
|
Lin et al., 2020 |
| Q-structured TiOx (Q-TiOx) | 
|
Identification of cancer cells from normal cells | 
|
Keshavarz et al., 2020 |
| SiO2/TiO2 core–shell beads | 
|
Recognition, separation, and probing of lysine mono-methylated histone H3 tail peptides | 
|
Bontempi et al., 2017 |
| Hollow CuS NPs | 
|
Cancer tissue imaging | 
|
Qiu et al., 2019 |
| Lithium-exfoliated MoS2 | 
|
Live cell imaging | 
|
Anbazhagan et al., 2018 |
| 3D near quantum-scaled silicon | 
|
Detection of tripeptide biomarker (l-glutathione) | 
|
Powell et al., 2017 |
We apologize for this error.
中文翻译:
对“生物医学应用非等离子体表面增强拉曼光谱纳米结构的最新进展”的更正
Li, D.、Aubertin, K.、Onidas, D.、Nizard, P.、Félidj, N.、Gazeau, F.、Mangeney, C. 和 Luo, Y. (2022)。用于生物医学应用的非等离子体表面增强拉曼光谱纳米结构的最新进展。WIRE 纳米医学和纳米生物技术,e1795。https://doi.org/10.1002/wnan.1795
在本文最初发布的版本中,表 1 和表 2 中的参考文献格式与最终参考文献列表的格式不匹配。更正后的表格以及以正确格式编写的参考文献已包含在本次更正中。
| 基材(激光 l ex) | 探测 | 详细程度(中) | 增强因子(EF) | 参考 |
|---|---|---|---|---|
| 碳 | ||||
| 0D 石墨烯量子点 (GQD) | ||||
| GQDs-Mn 3 O 4 ( λ ex = 514 nm) | 罗丹明B | – | 2.06×10 4 | 兰等人,2017 |
| N-GQD(λ ex = 488 nm) | 罗丹明B | 10 −10 | 3.2×10 3 | 达斯等人,2020 |
| 一维碳纳米管 (CNT) | ||||
| R/L-CNT/TiO 2 ( λ ex = 532 nm) | 亚甲蓝 | 5 × 10 -5 | – | 邱等,2015 |
| 二维石墨烯 | ||||
| EG-TiO 2 ( λ ex = 633 nm) | 铜矿 | 6×10−5 ( 2.07×10−16国际 单位) | 48.2 | 郑等人,2017 |
| 石墨烯烧瓶(λ ex = 633 nm) | 血红蛋白 | – | 4.5 | 黄等人,2018 |
| GMF/W-MoS 2 ( λ ex = 632.8 nm) | 罗丹明B | 5× 10−11 | 2.96×10 7 | 邱等人,2020 |
| 3D 互连纳米碳网 (INW) | ||||
| INW(λ ex = 785 nm) | 结晶紫 | – | 3.66×10 4 | 乔杜里等人,2018 |
| 氧化物 | ||||
| 氧化锌 | ||||
| 非晶态 ZnO 纳米笼 ( λ ex = 633 nm) | 4-MBA、4-MPY 和 4-ATP | 10 -4 | 6.62×10 5 | 王等人,2017 |
| ZnO 量子探针 ( λ ex = 785 nm) | 结晶紫和罗丹明 6G、4-三磷酸腺苷、4-巯基苯甲酸 | 10 −9 | 1.4–6.9×10 6 | 哈尔达夫内卡等人,2018 |
| 氧化钛 | ||||
| 量子结构 TiO x ( λ ex = 785 nm) | 结晶紫 | 10 −9 | 3.4×10 7 | 克沙瓦尔兹等人,2020 |
| 晶体非晶核壳TiO 2 ( λ ex = 532 nm) | 4-硝基苯硫醇 | 5 × 10 -4 | 4.3×10 5 | 林等人,2020 |
| 涂有 TiO 2 的二氧化硅纳米颗粒( λ ex = 783 nm) | 亚甲蓝和多巴胺 | 10 -2 | 3.63×10 4 | 刘等人,2019 |
| TiO 2原子缺陷量子探针(λ ex = 785 nm) | 结晶紫 | 10 −9 | 10 10 | Dharmalingam 等人,2019 |
| TiO 2反蛋白石基材 ( λ ex = 532 nm) | 亚甲蓝 | 10 -5 | 2.0×10 4 | 齐等人,2014 |
| 铜和钨的氧化物 | ||||
| Cu 2 O 立方超结构 ( λ ex = 647 nm) | 罗丹明6G 结晶紫 甲基蓝 甲基橙 |
10 -7 | 1.5×10 4 –8×10 5 | 林等人,2017 |
| WO 3−x ( λ ex = 532.8 nm) | 罗丹明6G | 10 -7 | 3.4×10 5 | 丛等人,2015 |
| 过渡金属硫属化物 | ||||
| 0D过渡金属硫属化物 | ||||
| ZnS 纳米晶体 ( λ ex = 514.5 nm) | 4-巯基吡啶 | 10 -6 | 10 3 | 王等人,2007 |
| CuS 微花(λ ex = 532 或 633 nm) | 结晶紫、孔雀石绿、罗丹明6G | MG 10 −8 R6G 和 CV 为10 −7 |
10 5 | 周等人,2021 |
| 多支化CuS纳米枝晶 | 结晶紫 | 10 −10 | – | 李等人,2017 |
| 空心 CuS 纳米颗粒 ( λ ex = 785 nm) | 3,3′-二乙基硫杂三碳花青碘化物 | 10 −12 | 3.9×10 2 –4.6×10 4 | 邱等,2019 |
| 二维过渡金属硫属化物 | ||||
| 2D MoS 2单层 ( λ ex = 488 nm) | 4-巯基吡啶 | – | 〜10 5 | Muehlethaler 等人,2016 |
| 氧结合 MoS 2 ( λ ex = 532.8 nm) | 罗丹明6G | 低于 10 −7 | 〜10 5 | 郑等人,2017 |
| 不同层间距的MoS 2微球( λ ex = 785 nm) | 4-巯基吡啶 (4-MPy)、4-巯基苯甲酸 (4-MBA) 和 4-氨基苯硫酚 (4-ATP) | – | 5.31×10 5 | 李等人,2020 |
| 超薄二维 NbS 2 | 亚甲蓝 | 10 −14 | 〜10 3 | 宋等人,2019 |
| 从单层到多层的大面积 NbSe 2薄片 | 罗丹明6G | 5× 10−16 | – | 吕等人,2021 |
| 三元ZnO/ZnS/MoS 2纳米片复合材料 | 罗丹明6G | 10 −9 | 1.4×10 8 | 尹等人,2019 |
| 聚合物、碲化物和硅 | ||||
| DFH-4T 薄膜(λ ex = 785 nm) | 亚甲蓝 | – | 3.4±1.3×10 3 | 耶尔马兹等人,2017 |
| PEDOT:PSS 薄膜 ( λ ex = 514 nm) | 亚甲蓝 | – | 2.26×10 3 | 张等人,2020 |
| 2D 1T′-W(Mo)Te 2层 ( λ ex = 532 nm) | 罗丹明6G | 40 (400) FM | 1.8×10 9 | 陶等人,2018 |
| MIL-100(Fe) MOF 阵列(λ ex = 785 nm) | 甲苯、丙酮和氯仿 | 2.5、20 和 92.7 ppm | 10 5 | 傅等人,2020 |
| 3D nQS Si 纳米网(λ ex = 532 和 785 nm) | l -谷胱甘肽、色氨酸、半胱氨酸和蛋氨酸 | 10 −9 M | 〜10 2 | 鲍威尔等人,2017 |
| 纳米材料 | 表面功能化 | 应用 | 参考 | |
|---|---|---|---|---|
| GQDs–Mn 3 O 4纳米复合材料 |
|
从正常细胞中识别癌细胞 |
|
兰等人,2017 |
| 单层石墨烯片 |
|
血红蛋白和白蛋白的传感 |
|
黄等人,2018 |
| 互连纳米碳网(INW) |
|
HeLa细胞和成纤维细胞的体外检测和分化 |
|
乔杜里等人,2018 |
| 石墨烯-TiO 2纳米复合材料 |
|
实时监测干细胞端粒酶活性 |
|
郑等人,2017 |
| SiO 2 /TiO 2核壳珠 |
|
监测生理浓度下谷胱甘肽的氧化还原循环作为稳态模型 |
|
亚历山德里等人,2014 |
| 纳米枝晶支撑的ZnO量子探针 |
|
从正常细胞中识别癌细胞 |
|
哈尔达夫内卡等人,2018 |
| 晶体-非晶核-壳TiO 2 |
|
癌细胞成像 |
|
林等人,2020 |
| Q结构TiO x (Q-TiO x ) |
|
从正常细胞中识别癌细胞 |
|
克沙瓦尔兹等人,2020 |
| SiO 2 /TiO 2核壳珠 |
|
赖氨酸单甲基化组蛋白 H3 尾肽的识别、分离和探测 |
|
邦坦皮等人,2017 |
| 空心 CuS 纳米颗粒 |
|
癌症组织成像 |
|
邱等,2019 |
| 锂剥离MoS 2 |
|
活细胞成像 |
|
安巴扎甘等人,2018 |
| 3D 近量子尺度硅 |
|
三肽生物标志物(l-谷胱甘肽)的检测 |
|
鲍威尔等人,2017 |
对于这个错误,我们深表歉意。
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