Handbook of Aggregation-Induced Emission, Volume 2. Группа авторов

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      DSA derivatives with amino and hydroxyl groups are very sensitive to the pH of the solution [92]. Compound 3‐1 has almost no fluorescence in the solution of pH > 10. However, when pH < 10, the fluorescence of the solution gradually increases. At pH = 6, the fluorescence intensity of the solution reaches a maximum, which is 140 times that at pH = 10.3. It is because under basic conditions, the hydroxyl group of the molecule is converted into a sodium alkoxide to dissolve itself in the solution. As the pH of the solution decreases, the number of the sodium alkoxide structure gradually decreases, leading to the molecules starting to aggregate and the fluorescence of the solution increasing. Compound 4‐4 can also be used to detect pH based on the same mechanism, and the fluorescence is turned on when pH is high [92].

Compound 4‐5 was used to develop a facile, sensitive, and label‐free aptamer‐based fluorescent biosensor for chloramphenicol (CAP) detection [93]. In this aptasensor, C‐Apt, the specific aptamer of CAP, is used as the recognition part, the AIE molecule 4‐5 is the fluorescent probe, and GO with a low oxidation degree is the fluorescent quencher. Before CAP is added, AIE probe 4‐5 and C‐Apt are adsorbed on GO via π‐stacking interactions, and the fluorescence of 4‐5 is efficiently quenched due to the energy transfer from 4‐5 to GO. After the addition of CAP, C‐Apt can preferentially combine with CAP and the newly formed complex, C‐Apt–CAP, is released from GO, leading to the recovery of the fluorescence of 4‐5. Therefore, by the aid of GO, the turn‐on detection of CAP can be readily realized through monitoring the fluorescence of 4‐5 from “off” to “on.” Under the optimized conditions, the aptasensor has a high sensitivity to CAP, and the detection limit is 1.26 pg/ml. In addition, it was successfully applied in detecting CAP of the spiked milk sample [93].

      2.2.4.2 Fluorescent Probes for Biological Sensing

      Fluorescent biosensor has been widely concerned because of its high sensitivity and simple operation. AIE molecules are widely used in bioassays due to their unique “turn‐on” luminescence properties. Tian and coworkers used the water‐soluble probe molecule 4‐5 to detect endonuclease S1 [94]. The aqueous solution of the AIE fluorescent probe 4‐5 has no fluorescence. When ssDNA is added, the negatively charged ssDNA and the positively charged probe molecule are combined by electrostatic interaction and hydrophobic interaction. Then, the probe molecules aggregate, enhancing the fluorescence of the solution. When the S1 enzyme is added, ssDNA is cleaved into fragments. The large number of probe molecules are dispersed in the solution, and the fluorescence of the solution is weakened. The specific detection of the S1 enzyme can be realized by observing the fluorescence change of the solution. In addition, the activity of the S1 enzyme can be regulated by the inhibitor. Based on this method, the S1 enzyme inhibitor can also be screened out.

In the recent years, carbon nanomaterials such as GO and water‐soluble carbon nanotubes (CNTs) have become a hot research topic in the field of biosensing due to their excellent physicochemical properties and strong quenching ability of luminescent molecules. Investigation results have indicated that GO can selectively adsorb ssDNA. However, as to double‐stranded DNA (dsDNA) with a double helix structure or ssDNA with high folding degree, GO has weak adsorption ability. Based on this, Tian's research team used the probe molecule 3‐5 (i.e. DSAI in Figure 2.13) and GO to achieve “turn‐on” recognition of target DNA (T1) (see Figure 2.13a) [89]. The probe molecule 3‐5 is weakly fluorescent in aqueous solution (see Figure 2.13b, c, curve 1). After the addition of unlabeled ssDNA (P1), P1 and probe molecule 3‐5 aggregate to form a complex, 3‐5/ssDNA aptamer complex, and the fluorescent emission is enhanced (see Figure 2.13b, c, curve 2). Under the condition without GO, the fluorescent intensity of the interferential mismatched ssDNA (M1) (see Figure 2.13b, curve 3) is a little stronger than that of the targeted complementary ssDNA (T1) (see Figure 2.13b, curve 4), indicating that the AIE‐active aptasensor could not distinguish T1 from M1. When GO is introduced, the fluorescence of the solution is quenched due to the adsorption of 3‐5/ssDNA aptamer complex onto GO. When M1 is added, there is no obvious fluorescent enhancement. However, with the addition of T1, P1 binds to T1 to form dsDNA, thereby breaking the binding of GO. At the same time, probe 3‐5 and dsDNA form a new complex and the new complex stays away from GO; thus, the fluorescence of the solution is gradually enhanced, which realizes the “turn‐on” recognition of the target DNA.

      To further understand the sensing mechanism of the system and optimize the sensing performance, Tian's group studied the interaction of AIE probe, DNA, and GO, which realized the construction of a highly sensitive and highly selective DNA sensing platform [95]. It is found that the probe molecules are tightly bound to dsDNA by intercalation and are not easily adsorbed by GO. Changing the sequence of dsDNA and mutating one of the bases will destroy the double helical chain. It weakens the binding of the probe molecule to the site of the mutation, and the probe molecule is easily adsorbed by the GO, which weakens the fluorescence of the solution. Based on the same mechanism, they used the probe molecule 3‐5 and CNTs to detect single nucleotide polymorphism (SNP) defined as the mutation of a single base pair in the genome, which is the most general form in genetic variation and can induce a few human genetic diseases and protein dysfunctions [96].

Figure 2.13 (a) Schematic description of the selective fluorescent aptasensor based on the probe molecule 3‐5 (i.e. DSAI in the figure)/GO probe; fluorescence emission spectra of 3‐5 in the absence (b) and presence (c) of GO at different conditions: (1) 3‐5 in buffer; (2) 3‐5 + P1 (200 nM); (3) 3‐5 + P1 + M1 (200 nM); and (4) 3‐5 + P1 + T1 (200 nM) [89].

      Source: Reprinted (adapted) with permission from Ref. [89]. Copyright © 2014 American Chemical Society.

Like the detection of DNA by cationic probes, anionic AIE probes can also be used to detect proteins by electrostatic and hydrophobic interactions. Tian's research team designed and synthesized a water‐soluble sulfonate 4‐6 based on DSA [97]. In the solution, the probe molecule 4‐6 exhibits a weak fluorescence. When bovine serum albumin (BSA) is added, the probe molecule enters the hydrophobic cavity of the BSA folded chain and aggregates, and then the fluorescence of the solution is illuminated. Thereby, the purpose of detecting BSA is successfully achieved. In addition, the probe molecule 4‐5 can also detect the changes in the BSA folded structure [92]. When cetyltrimethylammonium bromide is added, the hydrophobic cavity of the BSA folded structure is destroyed, resulting in the inability of the probe molecules aggregating. The fluorescence of the solution becomes weak.

Ouyang's research team used 4‐6 as a fluorescent probe to realize the real‐time monitoring of the unfolding process of erythropoietin (EPO) [98]. In the solution, the probe molecules hardly emit fluorescence. When EPO is added, the probe molecules combine with the hydrophobic cavity of EPO and accumulate, and the fluorescence of the solution is illuminated. The detection limit is up to 1 nM. When guanidine hydrochloride (GndHCl) (the protein denaturant) is added, EPO changes from the original folded structure to a random coil structure. In this process, the binding of the probe molecule to EPO is weakened, and resultantly, the fluorescence СКАЧАТЬ