Department of Orthopedics, The First Affiliated Hospital of Zhengzhou University, No. 1, Jianshe East Road, Zhengzhou, 450052, People's Republic of China.
School of Materials and Chemical Engineering, Zhengzhou University of Light Industry, No. 136, Science Avenue, Zhengzhou, 450001, People's Republic of China.
Mikrochim Acta. 2021 Feb 5;188(3):69. doi: 10.1007/s00604-021-04726-z.
A novel heterogeneous architecture has been constructed integrating two-dimensional (2D) bimetallic CoCu-zeolite imidazole framework (CoCu-ZIF) and zero-dimensional (0D) TiCT MXene-derived carbon dots (CDs) (represented by CoCu-ZIF@CDs). The prepared CoCu-ZIF@CDs were further explored as sensitive layer for anchoring B16-F10 cell-targeted aptamer strands and detecting B16-F10 cells from the biological environment. Basic characterization showed that CDs were homogeneously embedded within CoCu-ZIF NSs owing to their π-π stacking interaction, leading to outstanding fluorescence performance of the 0D/2D CoCu-ZIF@CD nanohybrid. As such, the CoCu-ZIF@CD-based cytosensor was applied to detect living B16-F10 cells through electrochemical techniques and cell imaging. Compared with CoCu-ZIF- and CD-based cytosensors, the constructed CoCu-ZIF@CD-based one showed superior sensing performance, with an extremely low limit of detection (LOD) of 33 cells∙mL and a wide range of suspension concentration of 1 × 10-1 × 10 cells∙mL B16-F10 cells. The developed cytosensor also demonstrated excellent detection performance, including cell imaging properties, good selectivity, high stability, and good reproducibility. By anchoring other probe molecules, the constructed CoCu-ZIF@CD-based biosensor can be extensively explored for early diagnosis of other analytes, thereby widening the applications of porous organic frameworks in biosensing and biomedical fields. A novel sensing system for melanoma B16-F10 cells based on a novel CoCu-ZIF@CD nanohybrid has been developed. The CoCu-ZIF@CDs-based cytosensor displayed an extremely low limit of detection (LOD) of 33 cells∙mL within the wide range of B16-F10 cell concentration from 1 × 10 to 1 × 10 cells∙mL, accompanying with cell imaging properties, good selectivity, high stability, and well reproducibility.
一种新型的杂化结构已被构建,该结构集成了二维(2D)双金属 CoCu-沸石咪唑骨架(CoCu-ZIF)和零维(0D)TiCT MXene 衍生的碳点(CDs)(以 CoCu-ZIF@CDs 表示)。制备的 CoCu-ZIF@CDs 进一步作为敏感层被用于锚定 B16-F10 细胞靶向适配体链并从生物环境中检测 B16-F10 细胞。基本表征表明,由于其π-π堆积相互作用,CDs 均匀地嵌入 CoCu-ZIF NSs 中,导致 0D/2D CoCu-ZIF@CD 纳米杂化物具有出色的荧光性能。因此,基于 CoCu-ZIF@CD 的细胞传感器通过电化学技术和细胞成像被应用于检测活的 B16-F10 细胞。与基于 CoCu-ZIF 和 CD 的细胞传感器相比,所构建的基于 CoCu-ZIF@CD 的传感器具有优越的传感性能,其检测 B16-F10 细胞的极限检测限(LOD)低至 33 个细胞·mL-1,悬浮浓度范围宽达 1×10-1×10 个细胞·mL-1 B16-F10 细胞。所开发的细胞传感器还表现出优异的检测性能,包括细胞成像特性、良好的选择性、高稳定性和良好的重现性。通过锚定其他探针分子,所构建的基于 CoCu-ZIF@CD 的生物传感器可以广泛用于其他分析物的早期诊断,从而拓宽了多孔有机骨架在生物传感和生物医学领域的应用。已经开发了一种基于新型 CoCu-ZIF@CD 纳米杂化物的新型黑色素瘤 B16-F10 细胞传感系统。基于 CoCu-ZIF@CD 的细胞传感器在 B16-F10 细胞浓度从 1×10 到 1×10 细胞·mL-1 的宽范围内显示出极低的检测限(LOD),低至 33 个细胞·mL-1,同时具有细胞成像特性、良好的选择性、高稳定性和良好的重现性。
