使用掺有 BODIPY 发射器的荧光和比色微粒和聚合物薄膜进行氨和温度传感应用。

IF 5.3 2区 化学 Q1 CHEMISTRY, ANALYTICAL
Beatriz S. Cugnasca, Frederico Duarte, Hugo M. Santos, José Luis Capelo-Martínez, Emilia Bértolo, Alcindo A. Dos Santos, Carlos Lodeiro
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引用次数: 0

摘要

我们合成了四种官能化 BODIPY 衍生物(BDP1 至 BDP4),并研究了它们在溶液中和加入固体基质后的光学特性。考虑到 BODIPY 衍生物的多功能性以及人们对开发嵌入聚合物的新型发光有机染料的兴趣与日俱增,研究人员将 BODIPY 衍生物分散到两种聚合物基质中:聚甲基丙烯酸甲酯 (PMMA) 和热塑性聚氨酯 (TPU)。由此产生了八种新的掺杂 BODIPY 的聚合物薄膜和八种掺杂 BODIPY 的聚合物微粒,可用于水溶液中。将 BODIPY 染料整合到聚合物基质中,将聚合物薄膜的独特性能(如多孔性、柔韧性和弹性)与 BODIPY 的优异光物理特性结合在一起。重要的是,分散过程最大程度地减少了固态发光材料中常见的聚集引起的淬灭等问题。通过研究所有聚合物薄膜在 25-200 °C 温度范围内的固态发射光谱,对其热度反应进行了评估。此外,还对这些温度诱导变化的可逆性进行了评估,结果表明发光的恢复效果极佳。这些令人鼓舞的结果表明,这些材料可用作荧光测温传感器。此外,我们还探索了溴化(BDP3)和瑀化(BDP4)BODIPY 衍生物作为氨传感器的潜力。这两种衍生物与分析物作用后产生黄色荧光产物。利用 BDP4@TPU 和 BDP4@PMMA 的固态发射光谱进行的动力学研究表明,由于热塑性聚氨酯与 PMMA 相比具有更高的渗透性,二者的反应速率存在显著差异(BDP4@TPU 为几分钟,BDP4@PMMA 为几小时)。氨浓度的检测和定量采用简单的照相分析方法,测量 RGB 颜色参数中的 "R"(红色)和 "G"(绿色)分量。照相法得出的结果与荧光光谱研究得出的结果有很好的相关性。照相分析法简单、便携,不需要昂贵的设备。最后,我们成功地将掺杂了 BODIPYs 的聚合物微粒用于检测水中的氨,证明了它们在无需有机溶剂的情况下的有效性。这凸显了它们在环境监测和其他需要灵敏度和选择性检测方法的应用中的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ammonia and temperature sensing applications using fluorometric and colorimetric microparticles and polymeric films doped with BODIPY-emitters

Four functionalized BODIPY derivatives (BDP1 to BDP4) were synthesized and their optical properties investigated both in solution and when incorporated into a solid matrix. Recognizing the versatility of BODIPY derivatives and the increasing interest in developing new luminescent organic dyes embedded in polymers, the BODIPY derivatives were dispersed into two types of polymeric matrices: Poly(methyl methacrylate) (PMMA) and Thermoplastic Polyurethane (TPU), both as films and microparticles. This resulted in eight new BODIPY-doped polymer films and eight types of BODIPY-doped polymeric microparticles for use in aqueous solutions. The integration of the BODIPY dyes into the polymeric matrices combines the unique properties of the polymer films, such as porosity, flexibility, and elasticity, with the excellent photophysical characteristics of the BODIPYs. Importantly, the dispersion minimized issues such as aggregation-caused quenching commonly observed in solid-state luminescent materials. The thermometric responses of all polymer films were evaluated by studying their solid-state emission spectra in the 25–200 °C temperature range. The reversibility of these temperature-induced changes was also assessed, revealing excellent recovery of luminescence. These promising results suggest these materials could have applications as fluorescent thermometric sensors. Furthermore, we explored the potential of the brominated (BDP3) and chalcogenated (BDP4) BODIPY derivatives as ammonia sensors. The two derivatives produced yellow fluorescent products upon interaction with the analyte. Kinetic studies using solid-state emission spectra of BDP4@TPU and BDP4@PMMA showed significant differences in reaction rates (minutes for BDP4@TPU and hours in the case of BDP4@PMMA) attributable to the higher permeability of TPU when compared with PMMA. Detection and quantification of ammonia concentration were conducted by means of simple photographic analysis, measuring the “R” (red) and “G” (green) components of RGB color parameters. The results from the photographic method correlated well with the results from fluorimetric spectroscopy studies. The photographic analysis is straightforward, portable, and does not require expensive equipment. Finally, we successfully applied polymeric microparticles doped with BODIPYs to detect ammonia in water, demonstrating their effectiveness without the need for organic solvents. This highlights their potential for environmental monitoring and other applications requiring sensitive and selective detection methods.

Graphical abstract

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来源期刊
Microchimica Acta
Microchimica Acta 化学-分析化学
CiteScore
9.80
自引率
5.30%
发文量
410
审稿时长
2.7 months
期刊介绍: As a peer-reviewed journal for analytical sciences and technologies on the micro- and nanoscale, Microchimica Acta has established itself as a premier forum for truly novel approaches in chemical and biochemical analysis. Coverage includes methods and devices that provide expedient solutions to the most contemporary demands in this area. Examples are point-of-care technologies, wearable (bio)sensors, in-vivo-monitoring, micro/nanomotors and materials based on synthetic biology as well as biomedical imaging and targeting.
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