Simple and Efficient Chromophoric-Fluorogenic Probes for Diethylchlorophosphate Vapor

Fu, Yanyan; Yu, Jinping; Wang, Kaixia; Liu, Huan; Yu, Yaguo; Liu, Ao; Xin, Peng; He, Qingguo; Cao, Huimin; Cheng, Jiangong

doi:10.1021/acssensors.8b00313

Cited by 41 publications

(22 citation statements)

References 39 publications

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“…Based on literature reports, the N-containing group presented an intense nucleophilic attack capacity toward the phosphonyl group of DCP, and then an ionic salt system will be formed after the reaction with DCP. 8,26,37 Hence, the conductivity of the ionic salt system will be much higher than that of the neutral CT complex, which agrees well with our test results in that all of the sensing films showed a resistance decrease after the DCP sensing process. Figure S5 presented the XRD patterns of the complexes before and after DCP sensing.…”

Section: Resultssupporting

confidence: 89%

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Rational Construction of Highly Tunable Organic Charge-Transfer Complexes for Chemiresistive Sensor Applications

Chen

Yan

Tang

et al. 2019

ACS Appl. Bio Mater.

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Organic charge-transfer (CT) complexes with a unique electrical performance are attractive materials for organic electronics. However, achieving breakthroughs in the practical application of CT complexes through rational design have always been a challenge. For the first time, a chemiresistive sensor for nerve agent that mimics (diethyl chlorophosphate) vapor detection is rationally designed based on organic CT complexes. Such CT complex chemiresistive sensor realizes a subppb detection of diethyl chlorophosphate (DCP) within 5 s under atmospheric conditions at room temperature with a high selectivity. Meanwhile, based on the highly tunable characteristics of CT complexes, the influence of morphology and intermolecular interaction on the sensing response are investigated. It is worth noting that a stronger intermolecular interaction results in lower sensing responses for CT complexes with a different D/A combination but with the same ratio. The organic charge-transfer materials not only provide a highly tunable platform for the chemiresistive sensor but also have the special properties such as solution processability, flexibility, and molecular recognition, which provides more possibilities for the application of flexible and wearable biosensors.

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Section: Resultssupporting

confidence: 89%

“…In reality, diethyl chlorophosphate (DCP) serves as a mimic for sarin due to its similar activity but low toxity. 26,27 At this time, there are many methods for detecting DCP vapor, and the detection limit is in the ppb range. However, most of these methods are complicated in operation and costly, limiting their applications.…”

Section: Introductionmentioning

confidence: 99%

Rational Construction of Highly Tunable Organic Charge-Transfer Complexes for Chemiresistive Sensor Applications

Chen

Yan

Tang

et al. 2019

ACS Appl. Bio Mater.

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“…Materials with nitrogen‐based nucleophiles constitute an important class of fluorescent sensors investigated for the detection of nerve agent and simulant vapors. N‐based chemosensors ( Figure ) include quinoline (e.g., 2 ), pyridine (e.g., 3 and 4 ), Schiff bases (e.g., 5 ), amines (e.g., 6 ), or quinoxaline . Solid‐state detection of the nerve agents has been reported to be achievable in different formats including drop‐casting ( 2 ) in a poly(ethylene oxide) (PEO) matrix, having ( 6 ) and ( 4 ) sorbed onto microbeads or glass, or filter paper, respectively, or in the form of a neat thin film by spin‐coating ( 3 ) or ( 5 ) onto quartz substrates.…”

Section: Solid‐state Fluorescence Sensing Of Nerve Agent and Simulantmentioning

confidence: 99%

“…Two typical detection mechanisms have been used with these materials to detect the nerve agents: protonation to enhance intramolecular charge transfer (ICT), e.g., compounds 2 – 5 and illustrated with 2→2′ , and phosphorylation to inhibit the photoinduced electron transfer (PET) process ( 6 →6′ ). Both the mechanisms lead to a fluorescence “turn on” response . There are other N‐based sensing materials (not listed here) that give fluorescence “turn off” signals, but the sensing mechanisms are unclear .…”

Section: Solid‐state Fluorescence Sensing Of Nerve Agent and Simulantmentioning

confidence: 99%

Challenges in Fluorescence Detection of Chemical Warfare Agent Vapors Using Solid‐State Films

et al. 2019

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Organophosphorus (OP)‐based nerve agents are extremely toxic and potent acetylcholinesterase inhibitors and recent attacks involving nerve agents highlight the need for fast detection and intervention. Fluorescence‐based detection, where the sensing material undergoes a chemical reaction with the agent causing a measurable change in the luminescence, is one method for sensing and identifying nerve agents. Most studies use the simulants diethylchlorophosphate and di‐iso‐propylfluorophosphate to evaluate the performance of sensors due to their reduced toxicity relative to OP nerve agents. While detection of nerve agent simulants in solution is relatively widely reported, there are fewer reports on vapor detection using solid‐state sensors. Herein, progress in organic semiconductor sensing materials developed for solid‐state detection of OP‐based nerve agent vapors is reviewed. The effect of acid impurities arising from the hydrolysis of simulants and nerve agents on the efficacy and selectivity of the reported sensing materials is also discussed. Indeed, in some cases it is unclear whether it is the simulant that is detected or the acid hydrolysis products. Finally, it is highlighted that while analyte diffusion into the sensing film is critical in the design of fast, responsive sensing systems, it is an area that is currently not well studied.

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“…Chemical reactions are more selective, but the selection of chromogenic agents, suitable for practical applications, was very limited in the past. However, during the last two decades, a lot of original works were published, referring particularly to chromogenic chemosensors for the G type nerve agents, featuring a significant change of color as well as good selectivity and sensitivity; these chemosensors are based on hydroxyl-activation, N-activation, and contain metal ions (coordination compounds), or possibly form reactive polymers [7][8][9][10][11][12][13][14][15][16][17][18][19]. Many publications deal with new chemosensors for sulphur mustard [20][21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

Detection Papers with Chromogenic Chemosensors for Direct Visual Detection and Distinction of Liquid Chemical Warfare Agents

et al. 2019

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This work provides a summary of our results in the area of the experimental development of detection paper for the detection of liquid phase chemical warfare agents (drops, aerosol), the presence of which is demonstrated by the development of characteristic coloring visible to the naked eye. The basis of the detection paper is a cellulose carrier saturated with the dithienobenzotropone monomer (RM1a)–chromogenic chemosensor sensitive to nerve agents of the G type, blister agent lewisite, or choking agent diphosgene. We achieve a higher coloring brilliance and the limit certain interferences by using this chemosensor in the mix of the o-phenylendiamine-pyronine (PY-OPD). We prove that the addition of the Bromocresol Green pH indicator even enables detection of nerve agents of the V type, or, nitrogen mustards, while keeping a high stability of the detection paper and its functions for other chemical warfare agents. We resolve the resistance against the undesirable influence of water by providing a hydrophobic treatment of the carrier surface.

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Simple and Efficient Chromophoric-Fluorogenic Probes for Diethylchlorophosphate Vapor

Cited by 41 publications

References 39 publications

Rational Construction of Highly Tunable Organic Charge-Transfer Complexes for Chemiresistive Sensor Applications

Rational Construction of Highly Tunable Organic Charge-Transfer Complexes for Chemiresistive Sensor Applications

Challenges in Fluorescence Detection of Chemical Warfare Agent Vapors Using Solid‐State Films

Detection Papers with Chromogenic Chemosensors for Direct Visual Detection and Distinction of Liquid Chemical Warfare Agents

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