高性能聚集诱导发光纳米探针用于肿瘤切除手术导航

doi:10.6023/A20100501

摘要/Abstract

远红/近红外(FR/NIR)发射荧光材料因其在生物成像领域的巨大应用潜力而受到广泛关注. 然而, 根据“能隙”规则, 电子带隙减小时, 非辐射失活途径占据能量耗散主导地位, 因此制备高量子产率、长发射波长的有机FR/NIR材料仍然是一个挑战. 本文通过引入扭曲构象基团(四苯基乙烯)对分子聚集态进行调控, 合成了一系列基于苯并硒二唑的供体-受体-供体(D-A-D)型化合物. 化合物TPE-DPA-Se在纳米粒子状态下表现出明亮的荧光发射, 其量子产率可高达16.48%, 证明其在水体系中仍具有良好的发射性能, 适用于多个领域. 本研究进一步证实了其优秀的细胞成像能力, 并将其成功地应用于荧光成像引导的手术导航, 特别是微小转移瘤的术中检测.

关键词: 聚集诱导发光, 远红/近红外, 纳米粒子, 细胞成像, 手术导航

Far red/near infrared (FR/NIR) materials have attracted wide attention due to their great potential in various applications, particularly in bio-imaging. However, it is still a challenge to manufacture organic FR/NIR materials with quite high efficiency and long emission wavelength, owing to the dominance of non-radiative deactivation in the dissipation of absorbed light excitation energy when the electronic bandgap decreases. Herein, a series of donor-acceptor-donor (D-A-D) type compounds based on benzoselenidazole are developed through the regulation of molecular aggregation states by twisted conformation groups. In one hand, the compound TPE-DPA-Se (tetraphenylethylene-diphenylamine-benzoselenidazole) exhibits the best aggregation-induced emission (AIE) properties among these compounds. In another hand, the obtained TPE-DPA-Se showed over 150 nm Stokes shift, which can be used to avoid the interference between excitation and emission light, as well as the near-infrared emission spectrum away from the organism auto-fluorescence, which was beneficial for the bio-application. Next, density functional theory (DFT) calculation was carried out with Gaussian 09W program at B3LYP/6-31G** level to determine the highest occupied molecular orbital (HOMO), the lowest unoccupied molecular orbital (LUMO) distributions and the optimized structures of these compounds. Then TPE-DPA-Se was formulated into nanoparticles by nanoprecipitation method with an amphiphilic co-polymer 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N- [methoxy(polyethylene glycol)-2000] (MPEG₂₀₀₀-DSPE) as the doping matrix. TPE-DPA-Se exhibited excellent aqueous diameter stability in nanoparticle-state, as well as impressive luminescence in aqueous system with higher efficiency of up to 16.48%, which are suitable for many fields. To evaluate the biocompatibility of the TPE-DPA-Se NPs, we further carried out 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) cytotoxicity assay. The result indicated their negligible toxicity. Encouraged by the excellent performance of these luminogens in nanoparticle state, a successful 4T1 cells imaging was demonstrated. Next, to set up the tumor-bearing mouse model, the luciferase-expressed 4T1 cancer cells were injected into the healthy mice via intraperitoneal injection. After about 7 days, the abdominal metastatic tumors were formed with many nodules in the abdominal cavity. The fluorescent image can merged with bioluminescence image completely and image-guided tumor resection is verified in this work, particularly for the micro-sized tumor of intraoperative detection.

Key words: aggregation-induced emission, far red/near-infrared, nanoparticles, cell imaging, surgical navigation

引用此文

高贺麒, 焦迪, 欧翰林, 章经天, 丁丹. 高性能聚集诱导发光纳米探针用于肿瘤切除手术导航[J]. 化学学报, 2021, 79(3): 319-325.

Heqi Gao, Di Jiao, Hanlin Ou, Jingtian Zhang, Dan Ding. High Performance Aggregation-Induced Emission Nanoprobes for Image-Guided Cancer Surgery[J]. Acta Chimica Sinica, 2021, 79(3): 319-325.

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图/表 9

图1. TPE-DPA-Se-NPs制备及荧光成像引导肿瘤切除示意图

Figure 1. Schematic illustration of TPE-DPA-Se NPs preparation and fluorescent image-guided tumor resection

图2. 化合物TPE-Se、TPA-Se和TPE-DPA-Se的合成路线.

Figure 2. Synthetic route for TPE-Se, TPA-Se and TPE-DPA-Se.

图3. (a)化合物TPE-Se、TPA-Se和TPE-DPA-Se在四氢呋喃(THF)中的归一化UV-Vis吸收光谱. (b)化合物TPE-Se、TPA-Se和TPE-DPA-Se在四氢呋喃(THF)中的归一化光致发光光谱.

Figure 3. (a) Normalized UV-Vis absorption spectra of compound TPE-Se, TPA-Se, and TPE-DPA-Se in THF. (b) Normalized photoluminescence spectra of compound TPE-Se, TPA-Se, and TPE-DPA-Se in THF.

图4. (a) 化合物TPE-Se在不同体积比例下THF/水混合溶液中的归一化光致发光光谱(λex=422 nm). (b) 化合物TPA-Se在不同体积比例下THF/水混合溶液中的归一化光致发光光谱(λex=488 nm). (c) 化合物TPE-DPA-Se在不同体积比例下THF/水混合溶液中的归一化光致发光光谱(λex=488 nm). (d) 化合物TPE-Se、TPA-Se和TPE-DPA-Se的聚集诱导发光曲线(I0为水体积为10%时光致发光强度)

Figure 4. (a) Photoluminescence (PL) spectra of TPE-Se in THF/H2O mixtures with different volume fractions of water (λex=422 nm). (b) Photoluminescence (PL) spectra of TPA-Se in THF/H2O mixtures with different volume fractions of water (λex=488 nm). (c) Photoluminescence (PL) spectra of TPE-DPA-Se in THF/H2O mixtures with different volume fractions of water (λex=488 nm). (d) AIE curves of TPE-Se, TPA-Se, and TPE-DPA-Se. (I0 is the photoluminescence intensity of 10% water fraction).

图5. 化合物TPE-Se (a)、TPA-Se (b)和TPE-DPA-Se (c)的优化结构、最高占据分子轨道(HOMO)和最低未占据分子轨道 (LUMO)的分布

Figure 5. The optimized structure, HOMO and LUMO orbital distributions of TPE-Se (a), TPA-Se (b), and TPE-DPA-Se (c)

图6. TPE-Se NPs (a)、TPA-Se NPs (b)和TPE-DPA-Se NPs (c)的动态光散射直径(DLS). 插图: TPE-Se NPs (a), TPA-Se NPs(b)和TPE-DPA-Se NPs (c)的透射电子显微镜图(TEM). (d) 纳米粒子在4 ℃条件下存储1, 7, 14, 21和28 d后的粒径

Figure 6. The DLS distributions of TPE-Se NPs (a), TPA-Se NPs (b), and TPE-DPA-Se NPs (c). Inset: the TEM images of TPE-Se NPs (a), TPA-Se NPs (b), and TPE-DPA-Se NPs (c). (d) The diameter of nanoparticles after storage at 4 ℃ for 1, 7, 14, 21 and 28 d

图7. (a) TPE-Se NPs、TPA-Se NPs和TPE-DPA-Se NPs在365 nm 紫外光照射下的荧光照片. TPE-Se NPs (b)、TPA-Se NPs (c)与TPE-DPA-Se NPs (d) 的归一化UV-Vis吸收光谱和归一化光致发光光谱

Figure 7. (a) The fluorescent image of TPE-Se NPs, TPA-Se NPs, and TPE-DPA-Se NPs under illumination of 365 nm UV light. The normalized UV-Vis absorption and the normalized photoluminescence spectra of TPE-Se NPs (b), TPA-Se NPs (c), and TPE-DPA-Se NPs (d)

图8. 共聚焦激光扫描显微镜(CLSM)观察4T1乳腺癌细胞与TPE-DPA-Se-NPs共孵育4 h后的图像, 细胞核用DAPI(蓝色)染色. 比例尺为20 μm.

Figure 8. Confocal laser scanning microscope (CLSM) images of 4T1 breast cancer cells after incubation with TPE-DPA-Se NPs for 4 h. The cell nuclei were stained with DAPI (blue). Scale bars indicate 20 μm.

图9. (a) 肿瘤切除前小鼠腹腔的生物发光和荧光显像图. (b) 荧光影像引导切除前后的腹腔荧光图像和肿瘤结节荧光显像. (c) 未引导组和TPE-DPA-Se NPs引导组切除的肿瘤结节的生物发光图像.

Figure 9. (a) Bioluminescence and fluorescence imaging of the abdominal cavity before tumor resection. (b) Fluorescence imaging of the abdominal cavity before and after image-guided tumor resection, and the fluorescence imaging of resected nodules. (c) Bioluminescence imaging of resected nodules of unguided and TPE-DPA-Se NPs-guided groups.

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