Designing of New Optical Immunosensors Based on 2-Amino-4

Mar 5, 2019 - A one-pot greener methodology has been adopted for the synthesis of a simple ... Diastereoisomerism, Stability, and Morphology of Substi...
0 downloads 0 Views 5MB Size
This is an open access article published under a Creative Commons Attribution (CC-BY) License, which permits unrestricted use, distribution and reproduction in any medium, provided the author and source are cited.

Article Cite This: ACS Omega 2019, 4, 4814−4824

http://pubs.acs.org/journal/acsodf

Designing of New Optical Immunosensors Based on 2‑Amino-4(anthracen-9-yl)-7-hydroxy‑4H‑chromene-3-carbonitrile for the Detection of Aeromonas hydrophila in the Organs of Oreochromis mossambicus Fingerlings Ellairaja Sundaram,† Shenbagavalli Kathiravan,† Abhijit Manna,‡ Amutha Chinnaiah,‡ and VairathevarSivasamy Vasantha*,† Department of Natural Products Chemistry, School of Chemistry, and ‡Department of Animal Behaviour and Physiology, School of Biological Sciences, Madurai Kamaraj University, Madurai 625 021, Tamilnadu, India

ACS Omega 2019.4:4814-4824. Downloaded from pubs.acs.org by 193.56.66.115 on 03/06/19. For personal use only.



S Supporting Information *

ABSTRACT: A one-pot greener methodology has been adopted for the synthesis of a simple 4H-chromene core-based fluorescent tag of (S)-2-amino-4-(anthracen9-yl)-7-hydroxy-4H-chromene-3-carbonitrile (AHC), and its structure has been analyzed using NMR spectroscopy. The physicochemical properties of AHC were well-studied by UV−vis and fluorescent spectroscopy techniques. As a result of excellent emitting property (ϕ ≈ 0.75), it has been coupled with anti-AH through amide linkage, and the AHC-tagged anti-AH has been used as an immunoassay for the selective detection of Aeromonas hydrophila in the presence of interfering pathogens. Under optimized conditions, immunosensors could successfully quantify A. hydrophila from 4 to 736 CFU/mL, and the LOD was 2 CFU/mL. Saliently, the immunoassay has been successfully demonstrated for the analysis of A. hydrophila in the organs of Oreochromis mossambicusfingerlings, and results have shown a very good agreement with our optimized neat AH fluorimetric titration results.



INTRODUCTION Genus of Aeromonas mainly consists of oxidase-positive, facultative, anaerobic Gram-negative bacteria; among these disease-causing pathogen community, Aeromonas hydrophila (AH) is noted as an important motile Gram-negative bacillus pathogen which is mostly found in water sources, and it is more pathogenic, especially for fish and other cold-blooded species.1 It is also pathogenic for both humans and animals.2−5 On the basis of the physiological and host properties, they are mainly divided into two major groups. The first group which mainly includes the motile aeromonads with AHas, a typical representative, and the other group consists of nonmotile species, which is represented by Aeromonas salmonicida.6 Aeromonas species are said to be pathogenic because of the production of a wide range of extracellular enzymes and possess all of the requirements of pathogenic bacteria through the production of flagella, pili, and adhesins.7,8 The main isolation source for the AH is food materials such as fish, meat products, milk, and vegetables, which ranges from 102 to 105 CFU/g.9 The amount of Aeromonas percentage in some food products such as meat and poultry (3−70%), dairy products (4%), and vegetables (26−41%) has also been reported. However, the sea food (31−72%) is the major source for the isolation of Aeromonas-positive samples.10 The motile aeromonads with AH possess some virulence factors including hemolysins, aerolysins, proteases, adhesins, © 2019 American Chemical Society

enterotoxins, phospholipases, and lipases; simultaneously, the infections caused by this could lead to gastroenteritis, septicemia, meningitis, respiratory, and hemolytic uremic. As a consumer, human community has been receiving gastroenteritis because of the intake of stressed or illn fish, and those who are easily affected with this AH will also undergo hemorrhagic septicemia.11−15 In humans, the gastrointestinal tract carries the Aeromonas species in both of their symptomatic and asymptomatic individuals. For nondiseased conditions, the rate of fecal carriage ranges from 0 to 4%,16 whereas for diarrheal illness, it ranges from 0.8 to 7.4%.17 Because of these adverse effects, people undergo so many clinical diagnosis procedures to detect the pathogenicity of Aeromonas species, but it requires both sensitivity and specificity.18,19 Culture-based detection methods are generally used to grow Aeromonas species in differential isolation media, and it has been developed for the recovery of Aeromonas species from the environment samples such as foods and clinical specimens.20 EPA method 1605, membrane filtration method, and culture enrichment have also been authenticated for the isolation of AH from drinking water samples, foods, and so forth.21,22 Received: October 29, 2018 Accepted: January 14, 2019 Published: March 5, 2019 4814

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

Figure 1. UV−vis absorption spectral data for synthesized AHC (a), anti-AH-tagged AHC at various equivalents (b), [inset captions: greenAH (0.001 M) + 2 equiv of anti-AH, redAH (0.001 M) + 4 equiv of anti-AH, blackAH (0.01 M) + a equiv of anti-AH] absorbance changes after the amide formation (c), and confirmation of complete amidation through washing (d) [concentration of AHC is 0.001 M; bulk concentration of anti-AH is 100 μg/100 μL and anti-AH−AHC is 0.002 μg/2000 μL in PBS buffer pH = 7.4, incubation temperature is 4 °C for one night].

These methods are only focused on the isolation of Aeromonas species from food and water samples. From the detection point of view, till date, only polymerase chain reaction (PCR) method has been mainly addressed for the recognition of AH. A simple PCR method has been reported for the detection of AH in raw milk within the limit of 2 log10 CFU/g, and the detection rate was found to be 23% for this method and 14% for culture method.23 In addition, some microarray-based method is constructed using DNA probes to study the population dynamics of microbial communities, such as marine bacteria in coastal waters in which aeromonads were found to make up a large proportion of the microbial flora.24 Another microarray method has also been reported for the detection of AH cytotoxic enterotoxin-inducing genes in macrophages.25−27 Some researchers have developed probes for the detection of various Aeromonas species.28,29 The chromene moieties often appear as an important structural component in both biologically active and natural compounds. Chromene fragments occur in alkaloids, flavonoids, tocopherols, and anthocyanins. Moreover, functionally substituted chromenes have played increasing roles as promising compounds in the field of medicinal chemistry.30−33 On the basis of deep tunneling of all reports for AH, let us conclude that no immunosensor has been reported so far for the detection of AH in laboratory as well as in real samples. Among the already-reported PCR techniques, DNA probe methods are used only for isolation and to find the detection rate of AH and not for precise quantification. These methods are costly, more time-consuming, and a lot of steps have to be taken care of. On the basis of this, we assure that our group is reporting for the first time about a fluorescent-based immunoassay for the very selective and ultrasensitive detection of A. hydrophila. The 4H-chromenecore(S)-2-amino-4-(anthracen-9-yl)-7-hydroxy-4H-chromene-3-carbonitrile (AHC)

was specially designed via a one-pot greener approach using ultrasonication method with high yield in a short time, that is, 20 min, and it was applied as a tag for the qualitative and quantitative detection of A. hydrophila from 4 to 736 CFU/mL with an LOD of 2 CFU/mL, and the immunoassay developed has been applied for the quantification of AH in the organs of Oreochromis mossambicusfingerlings.



RESULTS AND DISCUSSION Conformation of Tagging of AHC with Anti-AH by UV−Vis Spectra. In general, 1-ethyl-3-(3dimethylaminopropyl)carbodiimide hydrochloride (EDC)/Nhydroxysuccinimide (NHS) reagent offers a very good coupling platform for the immunosensors based on the amide linkage between antibodies and sensing materials.34−36 In this aspect, UV−vis spectral analysis assists us to confirm the tagging of anti-AH with our synthesized AHC. The normal amide formation in EDC/NHS coupling generally occurs based on the reaction between −COOH and −NH2 group.37,38 In our case, the amide formation occurred between the −COOH group of anti-AH and −NH2 group of our AHC probe in MES buffer at optimized condition.39 First, absorption maxima of AHC were recorded in phosphatebuffered saline (PBS) working buffer, and it showed two major absorption maxima at 218 and 277 nm because of the existence of π−π* and n−π* transitions, respectively (Figure 1a). We optimized the equivalents of AHC with respect to the number of −COOH group present in the anti-AH by UV−vis spectral analysis at lower and higher concentrations of AHC. Two equivalents (2 mL, 0.001 M) and four equivalents (4 mL, 0.001 M) of AHC were treated with one equivalent of anti-AH (containing four −COOH group).40 The corresponding absorbance changes were recorded, and it was clearly shown that 4 equiv of AHC at lower concentrations (0.001 M) 4815

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

Figure 2. Fluorescent spectral data for AHC (a) and AHC-tagged anti-AH (b) [concentration of AHC is 0.001 M; bulk concentration of anti-AH is 100 μg/100 μL and anti-AH−AHC is 0.002 μg/2000 μL in PBS buffer pH = 7.4, incubation temperature is 4 °C for one night].

Figure 3. Fluorescent response of anti-AH−AHC while attaching various concentrations of AH (a) and corresponding linear plot (b) [concentration of AHC is 0.001 M; bulk concentration of anti-AH is 100 μg/100 μL and anti-AH−AHC is 0.002 μg/2000 μL; AH is 10−1 to 10−11 CFU/g in PBS buffer pH = 7.4, incubation time is 5 min, Figure b labels: (a) 10−11, (b) 10−10, (c) 10−9, (d) 10−8, (e) 10−7, (f) 10−6, (g) 10−5,(h) 10−4, (i) 10−3, (j) 10−2, and (k) 10−1].

containing four −NH2 groups may be allowed to form amide link with four −COOH groups of anti-AH, thereby leading to maximum absorbance (Figure 1b). Whereas at higher concentration of AHC (0.01 M), the absorbance intensity was lower which may be because of the poor solubility of AHC. Hence, the precipitate was obtained. Initially, AH has showed a maximum absorbance because of twisted international critical table (ICT) state of the AH structure. After the formation of amide linkage, the peaks at 218 and 277 nm were blue-shifted to 212 and 269 nm, respectively, which may be because of the inhibition of initial twisted intramolecular charge transfer as a result of complex formation between antiAH (acceptor) and AHC (donor) via amide linkage (Figure 1c), and hence decrement in absorbance was absorbed. We have also cross-checked if any unbound AHC was present in the resulting anti-AH−AHC. Briefly, the settled anti-AH− AHC was washed with phosphate-buffered solution for 5 min and then centrifuged. The resulting supernatant solution was analyzed by UV−vis spectra. No peak corresponding to free AHC appeared for supernatant solution in the UV spectra. This seems to be that all of the 4 equiv of AHC were utilized for the amide linkage. Therefore, the UV−vis spectral shift has clearly evinced and supported the completion of anti-AH tagging with our AHC probe. The corresponding UV data are shown in Figure 1d. Confirmation of Tagging of AHC with Anti-AH by Emission Analysis. The tagging was further studied with the help of fluorescent emission analysis. Precisely, the initial emission maximum of AHC was analyzed at the absorption maxima of 277 nm in PBS buffer, and the corresponding emission was occurred at 390 and 505 nm. As a result of amide

coupling, the emission maxima at 505 nm was blue-shifted to 485 nm along with a drastic decrement in the emission intensity as in the case of UV−vis absorption spectra which may once again confirm the existence of inhibited twisted ICT mechanism during the coupling of AHC with anti-AH. In general, antibody-fluorescent tagging protocol may lead to a blue shift and decrement in fluorescent intensity because of amide coupling.41,42 First, the AHC has shown maximum fluorescence because of the twisted ICT state mechanism.43 After the coupling of anti-AH via amide bond, the initial twisted ICT was inhibited, and the repulsive interaction between the donor−NH2 and −COOH of anti-AH may rise the energy level of anti-AH/AHC and hence shift to the lower wavelength was observed (blue shift) The Stoke’s shift of the AHC was found to be 228 nm which shows very excellent luminescent properties of AHC.44 After the anti-AH was tagged with AHC, the Stoke’s shift was calculated as 216 nm. Generally, proteins, bacterial-based tagging, will give a large Stoke’s shift greater than 200 nm-based.45−47 Likewise, our anti-AH tagged with AHC has shown excellent Stoke’s shift, and the respective emission spectra are shown in Figure 2. Development of Fluorescent Immunoassay for A. hydrophila Using Anti-AH−AHC. Generally, we have to be more aware on Aeromonas colonization as human pathogens because of its association with gastrointestinal diseases. Our developed simple fluorescent immunoassay will be a better analytical tool to quantify the colonies of A. hydrophila. Although varying the concentration of AH from 10−1 to 10−12 CFU/g, the emission intensity of peaks at 390 and 485 nm was increased with increasing AH concentrations without any peak shift; however, at higher concentration of AH, the above peaks 4816

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

Figure 4. Selective fluorescent responses of anti-AH−AHC toward AH in the presence of other pathogens (a) and the corresponding bar diagram (b) [concentration of AHC is 0.001 M; bulk concentration of anti-AH is 100 μg/100 μL and anti-AH−AHC is 0.002 μg/2000 μL; AH and other pathogens is 10−1 CFU/g in PBS buffer pH = 7.4; incubation time is 5 min].

Figure 5. Bar diagram for the competitive performances of developed immunoassay anti-AH−AHC toward AH in the presence of other pathogens (a) [(A) E. coli, (B) E. coli + SPA, (C) E. coli + SPA + Bacillus, (D) E. coli + SPA + Bacillus + P. aeruginosa, and (E) E. coli + SPA + Bacillus + P. aeruginosa + S. aeruginosa] and their corresponding emission diagram (b) [concentration of AHC is 0.001 M; bulk concentration of anti-AH is 100 μg/100 μL and anti-AH−AHC is 0.002 μg/2000 μL; AH and other pathogens is 10−1 CFU/g in PBS buffer pH = 7.4; incubation time is 5 min].

immunosensing of anti-AH−AHC was proved via a selective recognition study and firmly confirmed the immunocomplex formation only between AH and anti-AH−AHC (Figure 2). The selective nature was again confirmed by performing the competitive analysis using other possible interfering pathogens such as E. coli, Bacillus, P. aeruginosa, and S.aerus (Figure 5). Interaction of all of these pathogens slightly quenches the initial fluorescent intensity of anti-AH−AHC which may be because of nonfluorescent complex formation via FRET quenching.45 The competitive test was performed by incubating 1 equiv of 2 mL of anti-AH−AHC with 1 equiv (10 μL, 10−1 CFU/g) of AH and 1 equiv (10 μL, 10−1 CFU/g) of all interfering pathogens, and the corresponding fluorescent intensity changes were recorded. Remarkably, there was no quenching in the fluorescent intensity for anti-AH−AHC. Hence, the designed immunoassay has proved to be very selective only for the AH in the presence of other interfering pathogens. Observation of Fluorescent and Naked Eye Color Changes Using UV−Vis Trans Illuminator. Generally, fluorescent sensors show excellent color changes toward various analytes such as biomolecules,49 metal ions,50 and pathogens, specifically.51 In our case, we have used AHC as a fluorescent tag because of its excellent quantum yield of 0.90 which is comparable with the standard rhodamine 6G dye. First, the AHC has exhibited orange fluorescent color under UV−vis lamp in MES buffer medium (pH 5.4). After the amide coupling with anti-AH, the initial color was diminished and changed slightly into yellowish green. Finally, after the formation of an immunocomplex between the AH and antiAH−AHC, a bright-green fluorescent color change was

were merged into a single new peak at 411 nm with increment in intensity. The Stoke’s shift of 208 nm from its excitation wavelength was observed during this interaction. The respective emission data along with the linear regression plot are shown in Figure 3. The sensitivity of the developed immunoassay was analyzed using colony counting method based on the dilution of stock culture of A. hydrophila, and the corresponding linear range of detection was found from 4 to 736 CFU/mL with the LOD of 2 CFU/mL. Selectivity Study of Anti-AH−AHC Immunoassay toward A. hydrophila. The important aspect of any immunoassay is its selectivity toward the targeted pathogen among all possible interfering pathogens. The antibody-tagging technology opens a new pathway for the most selectivity toward particular pathogens.40,47 The fluorescent labeling has been keynoted as a very good immunoplatform without using any blocking agents as in the case of electrochemical immunoassay.48 In our present immunoassay, we have tagged the AHC with anti-AH, and hence there is no doubt that the resulting anti-AH−AHC will be attached with its pathogen more specifically. To check the selectivity of the above immunoassay, the pathogens that have an analog behavior to AH, such as Escherichia coli, Bacillus, Pseudomonas aeruginosa, and Staphylococcus aerus were analyzed. There was a slight decrease in the emission intensity of the peaks at 390 and 485 nm and was noted for all other pathogens instead of increase in intensity as in the case of AH. Therefore, the results firmly support the selectivity of anti-AH−AHC toward A. hydrophilaand shown in Figure 4. Competitive Performance of the Immunoassay in the Presence of Other Interfering Pathogens. The selective 4817

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

transfer mechanism among AH molecule was inhibited because of the amide coupling between donor −NH2 of AHC and −COOH of anti-AH. Therefore, the donating nature of −NH2 to anthracene moiety was arrested. As a result, a blue shift was observed which may be because of the electronic charge repulsion between the two strong electron charge entities of the −NH2 group in AHC and −COOH group in anti-AH via amide bond formation, and this repulsion finally might increase the energy levels of the anti-AH−AHC, which results in the blue shift. Interestingly, when the pathogen AH was incubated with the anti-AH−AHC, the fluorescent intensity was increased enormously. This phenomenon may be because of aggregated induced emission (AIE) of the resulting immunocomplex formation. After the incubation with pathogen, all of the AHC molecules in anti-AH−AHC might come closer to each other, and thereby the antharacene moiety in AHC can undergo dimerization or aggregation. In general, fluorescent intensity of anthracene-containing molecules will be enhanced in solution/solid phase because of the aggregation-induced phenomenon.56−58 Therefore, the fluorescent intensity of the immunoassay was increased.51,59,60 Therefore, based on these UV−vis and emission spectral changes, it is confirmed that two interesting mechanisms such as inhibition of twisted ICT and AIE are existing during the formation of anti-AH−AHC and AH/anti-AH−AHC immunocomplexes, respectively, under optimized conditions (Scheme 1). Determination of Quantum Yield (ϕ). Using the emission data, the fluorescence quantum yield (ϕ) at various steps were estimated by integrating the area under fluorescence curves using the following equation.46 The absorbance value of AHC, anti-AH, and AH/anti-AH−AHC was chosen from Figure 1. The integrated area under the emission spectra of AHC and its complexes were calculated at the excitation wavelengths of 505 nm (AHC), 485 nm (anti-AH−AHC), and 411 nm (AH/anti-AH−AHC), respectively, in a phosphate buffer (pH = 7.4) and compared with quantum yields of rhodamine 6G in ethanol.61

observed, and images are given in Figure 6a. Under naked eye condition, initially, the AHC was deep orange in color; after

Figure 6. Color changes observed during the development of immunoassay: (a) fluorescent color changes (a) and naked eye visualization (b) [(1) AHC, (2) anti-AH−AHC, and (3) AH/antiAH−AHC].

coupling with anti-AH, it became slightly yellow in color, and then, finally, it turned into deep-bright-green fluorescent after binding with AH (Figure 6b). These results supported the utility of AHC as a fluorescent tag for the detection of AH. The accumulation of AH in the organs of fish grown in contaminated water (where they were grown for different days) was analyzed through imaging the color change of antiAH−AHC during binding with AH using a transilluminator. The fluorescent color of anti-AH−AHC increases with the increasing growing time and is shown in Figure 7. All of these observations also supported the accumulation of AH in the fish organs and selectivity of immunoassay toward AH pathogen. Sensing Mechanism of the AH/Anti-AH−AHC Fluorescence Immunoassay. Among all fluorescent-sensing mechanisms, intra/intermolecular charge-transfer-based mechanism has been commonly existing in various fluorescent sensing assays.52−54 After tagging, the formation of amide linkage between anti-AH and AHC may be responsible for the spectral shift in both UV−vis as well as fluorescence emission spectra with decrement in absorbance/emission intensity. On the basis of the blue shift, it is confirmed that the synthesized AHC has shown maximum absorbance/emission which may be because of the twisted ICT mechanism among the molecule itself from donor −NH2 to acceptor anthracene moiety.55 After tagging with anti-AH, the initial twisted intramolecular charge-

ϕu =

ϕsIuA sλexsηu IuA sλexsηs

where, ϕ is the quantum yield; I is the integrated area under the corrected emission spectra; A is the absorbance at the

Figure 7. Fluorescent color changes observed in fish organs at different day intervals (a) and at the extract of the corresponding dissected samples in buffer solution (b). 4818

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

portion of AH in growing medium were analyzed. In addition, the photo images of the organs dissected from O. mossambicus fingerlings for 7 days are shown in the Supporting Information (Figure S2). After dissection, the organs of the fish were collected for each day, and samples were prepared as per the procedure given in Materials and Methods section and analyzed for the AH accumulation using the emission method (Figure 8a−c). Among these organs, higher accumulation of AH was found at guts than at liver and tissue. The results obtained were compared and also confirmed using the colony counting method. The colony formation of AH on a disc was also analyzed at the biologically simulated conditions of fish guts (Figure S3). The calculated CFU values are given in Table 1 and compared with the plate count method. For cross-checking, the amount of AH in contaminated water was also tested using emission method for each day. The concentration of AH was found higher in the medium on the first day, and it started to decrease as the day goes up to fifth day, whereas in fish organs, a reverse trend was observed. However, after the fifth day, the amount of AH found in fish organs and the medium attained saturation (Figure 8d). Meanwhile, we have also performed the control experiments (Figure 8e). The results obtained from emission and colonyforming techniques have shown very good agreement. No doubt, the real potent application and the other main theme of our work are successfully demonstrated in fish samples.

Scheme 1. Schematic Representation of Mechanisms Followed During the Formation of Anti-AH−AHC and AH/ Anti-AH−AHC Complex in the Immunoassay

excitation wavelength; λex is the excitation wavelength; η is the refractive index of the solution; and the subscripts u and s refer to the unknown and the standard, respectively. The quantum yield of rhodamine 6G dye was calculated as 0.94 in absolute ethanol medium at an excitation wavelength of 470 nm.62 The quantum yield of AHC, anti-AH−AHC, and AH/anti-AH− AHC was calculated as 0.80, 0.328, and 0.90, respectively, and calculations were given at the end of the section. The aggregation may lead to an increment in quantum yield after binding with AH.56−58,63,64 Analysis of Accumulation of A. hydrophila in Organs of O. mossambicusFingerlings. The fingerlings of O. mossambicuswere grown in A. hydrophila contaminated water for 7 days and the images of growing vessels are shown in the Supporting Information (Figure S1). The detailed protocol was given in the above Materials and Methods section. The accumulation of AH in three different organs such as guts, liver, and tissue of O. mossambicusfingerlings and the remaining



CONCLUSIONS Hence, a very first fluorescent-based immunoassay is developed for the specific and ultrasensitive detection of A. hydrophila. We have designed a natural 4H-chromene corebased, AHC, as a fluorescent tag via the one-pot greener approach using ultrasonication method. Then, it was tagged

Figure 8. Fluorescent responses of anti-AH−AHC for the addition of AH extracted from different fish organs at different day interval guts (a), liver (b), tissue (c), water source (d), and control experiments (e) [concentration of AHC is 0.001 M; bulk concentration of anti-AH is 100 μg/100 μL and anti-AH−AHC is 0.002 μg/2000 μL; AH is 10−1 CFU/g in PBS buffer pH = 7.4; incubation time is 5 min]. 4819

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

Table 1. Comparison of Results Obtained for the Detection A. hydrophila in Fingerlings of O. mossambicusfish Organs Current Developed Fluorescence Immunoassay Protocol with the Normal Plate-Count Method name of the fish part

water sample guts control

spiked

control

NIL NIL NIL NIL NIL NIL NIL

VHC VHC VHC VHC VHC 726 736

NIL NIL NIL NIL NIL NIL NIL

day order 1 2 3 4 5 6 7

liver spiked

control

a*

b*

25 33 50 70 405 410 413

20 42 55 65 385 400 395

NIL NIL NIL NIL NIL NIL NIL

tissue spiked

control

a*

b*

8 20 30 50 80 90 200

15 30 42 65 72 120 190

NIL NIL NIL NIL NIL NIL NIL

spiked a*

b*

5 5 7 8 10 12 15

4 5 9 12 15 20 22

Figure 9. 1H NMR of the synthesized AHC.

(MTCC 735), Bacillus (MTCC 430), S. aureus (MTCC96), E. coli (MTCC 448), and P. aeruginosa (MTCC 2534) were originally obtained from Microbial Type Culture Collection Centre, Institute of Microbial Technology, Chandigarh, India. Pure culture of all bacterial strains was procured from MTCC, Pune, and maintained in Luria Bertani medium at 37 °C for 16 h. NMR studies were carried out using Bruker-400 MHz spectrometer for 1H and 13C NMR analysis using CDCl3 and DMSO-[d6] as solvents containing a trace quantity of tetramethylsilane as the internal standard, and the chemical shifts are reported in parts per million at 25 °C. UV spectra were recorded using Shimadzu single-beam UV−vis spectrophotometer. Finally, fluorescent measurements were done with the help of Cary Eclipse spectrophotometer having a 450 W xenon lamp. Bandwidths of 5 and 2.5 nm were maintained as excitation and emission slit widths, respectively, throughout the experiments. Ethical Statement. Fish were maintained in accordance with the guidelines of the American fisheries society (Guidelines for the use of fish, 2014) and approved by the institutional ethical committee of Madurai Kamaraj University [Internal Research and Review Board (IRB), Ethical Clearance (EC), Biosafety and Animal Welfare Committee].

with the anti-AH successfully and applied for the qualitative and quantitative detection of A. hydrophila from 4 to 736 CFU/mL with the LOD of 2 CFU/mL. To further enhance the application of our developed immunoassay, it was applied for the real-time quantification of A. hydrophila accumulation in organs of O. mossambicusfingerlings. Results have shown excellent agreement with the plate-counting method, and we assure that it would be a better immunoanalytical tool for the quantification of A. hydrophilain fish and some food samples.



MATERIALS AND METHODS We have used analytical grade solvents and double distilled water throughout the studies. Malononitrile, resorcinol, anthracene-1-carboxaldehyde, HCl, disodium mono hydrogen phosphate, monosodium dihydrogen phosphate, glacial acetic acid, ammonium acetate, sodium acetate, absolute ethanol, high-performance liquid chromatography methanol, ammonium chloride, liquid ammonia, piperidine, NaOH, and KCl were purchased from Sigma-Aldrich Chemical Company. The acetate salts of metal ions analyzed were purchased from Merck and Avra Chemicals. Anti A. hydrophila IgG fraction monocolonal antibody [Clone 6B10/A5] was purchased from Santa Cruz Biotechnology Inc, California, via dealers from Synergy Scientific Services Pvt. Ltd., India. Bacterial strains such as A. hydrophila (MTCC1739), Salmonella paratyphi A 4820

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

Figure 10. 13C NMR of the synthesized AHC.

One-Pot Greener Synthesis of AHC. 4H-chromene derivative was synthesized via one-pot greener approach using ultrasonication method. In brief, antharacene-1-carboxaldehyde (1.0 mmol), malononitrile (1.0 mmol), and resorcinol (1.0 mmol) were dissolved one by one in 5 mL of absolute ethanol and stirred for 2 min. Then, catalytic amount of piperidine (300 μL) was added with constant stirring. Then, the resulting solution mixture was kept in an ultrasonication bath (1.5 Hz) and was sonicated for 20 min (Scheme S1). In between the reaction times, the crude reaction mixture was analyzed for the completion of the reaction by using TLC (by observing a single spot). After the confirmation of reaction, the reaction mixture was poured into ice-cold water, and a light yellow precipitate was obtained. This solid was filtered and washed thoroughly for three times with diethyl ether and absolute ethanol, and finally, it was dried over anhyd. CaCl2. It was further separated through organic separation method using diethyl ether and water mixture as a solvent. The ether layer was separated, evaporated, and then the obtained yellow color solid was recrystallized using absolute hot ethanol to obtain a pure product. The yield was calculated to be 98.5% (1.92 g). The structure of the synthesized 4H-chromene derivatives (1a−d) was thoroughly characterized by NMR technique, and the corresponding coupling constant values are given below. 1 H NMR (400 MHz, DMSO-d6): 7.23 (s, 1H), 6.99 (s, 1H, −OH), 6.55 (s, 2H, −NH2), 6.03−5.98 (m, 4H), 5.86−5.77 (m, 4H), 5.25 (s, 2H), 4.77 (s, 1H), 4.52 (d, 1H) and 4.26 (d, 1H) ppm.13C NMR (400 MHz, DMSO-d6): 157.88 (C1), 99.15 (C2), 131.38 (C3), 102.85 (C4), 156.65 (C5), 93.94 (C6), 30.38 (C7), 57.68 (C8), 159.82 (C9), 150.48 (C12), 132.13 (C13, C17), 137.28 (C14, C16), 127.34 (C15), 120.83 (C27), 130.03 (C18, C25), 129.32 (C19, C24), 129.04 (C20, C23), and 131.04 (C21, C22) ppm. C24H16N2O2; calcd mass: 364.40. The melting point (uncorrected) of the synthesized AHC was found to be 220 °C (Figures 9 and 10). Protocol for the Tagging of AHC with the AH Antibody. The AHC was tagged with anti-AH via standard EDC/NHS coupling protocol.30−32 In briefly, 1 equiv of antiAH (1 mL, 100 μg/μL) in MES buffer and 4 equiv (4 mL, 0.001 M) of AHC were mixed, and then 100 μL of each solution of EDC and NHS were added one by one to the

above solution. It was gently stirred for 1−2 h and then kept for incubation at 4 °C for 1 day. Then, the resultant tagged anti-AH/AHC (0.002 μg) was allowed to stand at room temperature for 5−10 min, and then it was completely centrifuged at 30 000 rpm for 20 min at 4 °C. The resulting pellets were collected and washed thoroughly with PBS buffer for five times. The unbound AHC was removed by simply washing with PBS buffer and confirmed by analyzing the supernatant solution using UV−vis spectra until the disappearance of standard UV−vis peak of AHC. The final antiAH/AHC in buffer solution was stored at 4 °C for further studies (Scheme S2). Bacterial Cultivation. Pure culture of AH bacteria was procured from MTCC1739 strain, Pune, India. It was grown initially in tryptic soya broth and maintained in Luria Bertani medium at 30 °C for 16 h for further studies. The bacterial cells were then separated through centrifugation (6000 rpm, 20 min) and then rinsed thrice with PBS. The culture was serially diluted with physiological saline solution, and the viable cell number was determined via the most probable number method. Development of Immunosensor (AH/Anti-AH−AHC). Under optimized conditions, 2 mL of AHC/anti-AH (0.002 μg) was mixed thoroughly with 10 μL of AH pathogens diluted in different CFU, and then they were incubated at 4 °C for 25 min. The major absorption maxima at 277 nm were fixed as excitation wavelength, and the corresponding fluorescence spectra were recorded at 411 nm, and all of these experiments were carried out in the phosphate buffer (PBS, pH = 7.4) medium throughout the studies. Fish Maintenance and Treatment Procedure. Fingerlings of O. mossambicus were grown in artificial condition (plastic turf in laboratory condition) for 1 month, subsequently; they were transferred in to 250 mL conical flask in the presence of sterile water (200 mL) and kept for acclimatization for 15 days inside the sterile laminar hood. After acclimatization, AH was inoculated in seven different conical flasks along with fingerlings of O. mossambicus, and 100 μg/mL concentration of filter-sterilized glucose was added to enhance the growth of AH. From first day to seventh day, fingerlings were sacrificed using sterile dissection apparatus in 4821

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

phenotypic identification schemes. J. Clin. Microbiol. 2003, 41, 2348−2357. (5) Villari, P.; Crispino, M.; Montuori, P.; Boccia, S. Molecular typing of Aeromonas isolates in natural mineral waters. Appl. Environ. Microbiol. 2003, 69, 697−701. (6) Igbinosa, I. H.; Igumbor, E. U.; Aghdasi, F.; Tom, M.; Okoh, A. I. EmergingAeromonasSpecies Infections and Their Significance in Public Health. Sci. World J. 2012, 2012, 625023. (7) Trower, C. J.; Abo, S.; Itzstein, M. V.; Majeed, K. N. Production of an enterotoxin by a gastro-enteritis-associated Aeromonas strain. J. Med. Microbiol. 2000, 49, 121−126. (8) Gavin, R.; Merino, S.; Tomas, J. M. Molecular mechanisms of bacterial pathogenesis from an emerging pathogen: Aeromonas spp. Recent Res. Dev. Infect. Immun. 2003, 1, 337−354. (9) Neyts, K.; Huys, G.; Uyttendaele, M.; Swings, J.; Debevere, J. Incidence and identification of mesophilic Aeromonas spp. from retail foods. Lett. Appl. Microbiol. 2000, 31, 359−363. (10) Janda, J. M.; Abbott, S. L. The genus Aeromonas: taxonomy, pathogenicity, and infection. Clin. Microbiol. Rev. 2010, 23, 35−73. (11) Vasaikar, S.; Saraswathi, K.; De, A.; Varaiya, A.; Gogate, A. Aeromonas species isolated from cases of acute gastroenteritis. Indian J Med Microbiol 2002, 20, 107−9. (12) Aslani, M. M.; Alikhani, M. Y. The role of Aeromonas hydrophilain diarrhea. Iran. J. Public Health 2004, 33, 54−59. (13) Guerra, I. M. F.; Fadanelli, R.; Figueiró, M.; Schreiner, F.; Delamare, A. P. L.; Wollheim, C.; Costa, S. O. P.; Echeverrigaray, S. Aeromonas associated diarrhoeal disease in south Brazil: prevalence, virulence factors and antimicrobial resistance. Braz. J. Microbiol. 2007, 38, 638−643. (14) Costa, Q.; Shi, G.-Q.; Tiang, G.-P.; Zou, Z.-T.; Yao, G.-H.; Zeng, G. A foodborne outbreak of Aeromonas hydrophila in a college, Xingyi City, Guizhou, China, 2012. West Pac. Surveill. Response J. 2012, 3, 39. (15) Saavedra, M.; Guedes-Novais, S.; Alves, A.; Rema, P.; Tacao, M.; Correia, A.; Martínez-Murcia, A. Resistance to lactam antibioticsinAeromonas hydrophilaisolated from rainbow trout( Oncorhynchus mykiss). Int. Microbiol. 2004, 7, 207−211. (16) Svenungsson, B.; Lagergren, A.; Ekwall, E.; Evengard, B.; Hedlund, K. O.; Karnell, A.; Lofdahl, S.; Svensson, L.; Weintraub, A. Enteropathogens in adult patients with diarrhea and healthy control subjects: a 1-year prospective study in a Swedish clinic for infectious diseases. Clin. Infect. Dis. 2000, 30, 770−778. (17) Albert, MJ; Ansaruzzaman, M.; Talukder, KA; Chopra, AK; Kuhn, I.; Rahman, M.; Faruque, AS; Islam, MS; Sack, RB; Mollby, R. Prevalence of enterotoxin genes in Aeromonas spp. isolated from children with diarrhea, healthy controls, and the environment. J Clin Microbiol 2000, 38, 3785−90. (18) Abbott, S. L.; Cheung, W. K. W.; Janda, J. M. The genus Aeromonas: biochemical characteristics, atypical reactions, and phenotypic identification schemes. J. Clin. Microbiol. 2003, 41, 2348−2357. (19) Carnahan, A. M.; Joseph, S. W. Aeromonadaceae. In The Proteobacteria, Part B, Bacteriology Bergey’s Manual of Systematic; Brenner, D. J., Krieg, J. T., Garrity, G. M., Eds.; Springer: New York, NY, USA, 2005. (20) Villari, P.; Pucino, A.; Santagata, N.; Torre, I. A comparison of different culture media for the membrane filter quantification of Aeromonas in water. Lett. Appl. Microbiol. 1999, 29, 253−257. (21) United States Environmental Protection Agency. Method 1605. Aeromonas in Finished Water by Membrane filtration using AmpicillinDextrin Agar with Vancomycin; (ADA-V), United States Environmental Protection Agency: Washigton, DC, USA, 2001. (22) McMahon, M.; Wilson, I. G. The occurrence of enteric pathogens and Aeromonas species in organic vegetables. Int. J. Food Microbiol. 2001, 70, 155−162. (23) Ö zbaş, Z. Y.; Lehner, A.; Wagner, M. Development of a multiplex and semi-nested PCR assay for detection of Yersinia enterocolitica and Aeromonas hydrophilain rawmilk. Food Microbiol. 2000, 17, 197−203.

sterile condition, and liver, guts, and tissues samples were collected in sterile PBS (pH = 7.4), and a loop-full suspension was inoculated in the AH growth-specific media to check the increasing number of bacterial colony. O. mossambicus in sterile water without AH was used as a control, and the experiment was performed thrice in a triplicate manner.



ASSOCIATED CONTENT

S Supporting Information *

The Supporting Information is available free of charge on the ACS Publications website at DOI: 10.1021/acsomega.8b02467.



Synthetic scheme of AHC, tagging of anti-AH with AHC, fish maintaining, dissection, and plate-count method images for the developed immunoassay (PDF)

AUTHOR INFORMATION

Corresponding Author

*E-mail: [email protected]. Fax: + 91 - 452 - 245 8449 (V.V.). ORCID

VairathevarSivasamy Vasantha: 0000-0001-8391-8682 Notes

The authors declare no competing financial interest.



ACKNOWLEDGMENTS The first author is financially supported by DST-INSPIRE Fellowship Scheme, New Delhi, India (grant no. DST/ INSPIRE-Fellowship/2012/251). Therefore, the author thanks DST for offering the fellowship for pursuing his Ph.D program. The corresponding author sincerely acknowledges DST-SERB for the further support.



ABBREVIATIONS AHC, (S)-2-amino-4-(anthracen-9-yl)-7-hydroxy-4H-chromene-3-carbonitrile AH, Aeromonas hydrophila NMR, nuclear magnetic resonance UV−vis, ultraviolet−visible CFU, colony forming unit EPA, environmental protection agency’s PCR, polymerase chain reaction DNA, deoxyribose nucleic acid MTCC, Microbial Type Culture Collection and Gene Bank EDC, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride NHS, N-hydroxysuccinimide PBS, phosphate buffer saline



REFERENCES

(1) Daskalov, H. The importance of Aeromonas hydrophila in food safety. Food Control 2006, 17, 474−483. (2) Colwell, R. R.; Macdonell, M. T.; De Ley, J. Proposal to Recognize the Family Aeromonadaceae fam. nov. Int. J. Syst. Bacteriol. 1986, 36, 473−477. (3) Abbott, S. L.; Seli, L. S.; Catino, M., Jr; Hartley, M. A.; Janda, J. M. Misidentification of unusual Aeromonas species asmembers of the genus vibrio: a continuing problem. J. Clin. Microbiol. 1998, 36, 1103−1104. (4) Abbott, S. L.; Cheung, W. K. W.; Janda, J. M. The genus Aeromonas: biochemical characteristics, atypical reactions, and 4822

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

(24) Stine, O. C.; Carnahan, A.; Singh, R.; Powell, J.; Furuno, J. P.; Dorsey, A.; Silbergeld, E.; Williams, H. N.; Morris, J. G. Characterization of microbial communities fromcoastal waters using microarrays. Environ. Monit. Assess. 2003, 81, 327−336. (25) Galindo, C. L.; Sha, J.; Ribardo, D. A.; Fadl, A. A.; Pillai, L.; Chopra, A. K. Identification of Aeromonas hydrophila cytotoxic enterotoxin-induced genes in macrophages using microarrays. J. Biol. Chem. 2003, 278, 40198−40212. (26) Galindo, C. L.; Fadl, A. A.; Sha, J.; Chopra, A. K. Microarray Analysis of Aeromonas hydrophila Cytotoxic Enterotoxin-Treated Murine Primary Macrophages. Infect. Immun. 2004, 72, 5439−5445. (27) Galindo, C. L.; Fadl, A. A.; Sha, J.; Pillai, L.; Gutierrez, C.; Chopra, A. K. Microarray and Proteomics Analyses of Human Intestinal Epithelial Cells Treated with the Aeromonas hydrophila Cytotoxic Enterotoxin. Infect. Immun. 2005, 73, 2628−2643. (28) Demarta, A.; Tonolla, M.; Caminada, A.-P.; Ruggeri, N.; Peduzzi, R. Signature region within the 16S rDNA sequences of Aeromonas popoffii. FEMS Microbiol. Lett. 1999, 172, 239−246. (29) Khan, A. A.; Nawaz, M. S.; Khan, S. A.; Cerniglia, C. E. Identification of Aeromonas trota(hybridization group 13) by amplification of the aerolysin gene using polymerase chain reaction. Mol. Cell. Probes 1999, 13, 93−98. (30) Elinson, M. N.; Dorofeev, A. S.; Feducovich, S. K.; Gorbunov, S. V.; Nasybullin, R. F.; Stepanov, N. O.; Nikishin, G. I. Electrochemically induced chain transformation of salicylaldehydes and alkyl cyanoacetates into substituted 4H-chromenes. Tetrahedron Lett. 2006, 47, 7629−7633. (31) Sun, W.; Cama, L. D.; Birzin, E. T.; Warrier, S.; Locco, L.; Mosley, R.; Hammond, M. L.; Rohrer, S. P. 6H-Benzo[c]chromen-6one derivatives as selective ERβ agonists. Bioorg. Med. Chem. Lett. 2006, 16, 1468−1472. (32) Stachulski, A. V.; Berry, N. G.; Low, A. C. l.; Moores, S. L.; Row, E.; Warhurst, D. C.; Adagu, I. S.; Rossignol, J.-F. Identification of Isoflavone Derivatives as Effective Anticryptosporidial Agents in Vitro and in Vivo. J. Med. Chem. 2006, 49, 1450−1454. (33) Hormi, M.; Rumum, R. Md.; Iadeishisha, K.; Badaker, M. L.; Icydora, K.; Mantu, R.; Bekington, M. L -Proline as an efficicent catalyst for the multi-component synthesisof 6-amino-4-alkyl/aryl-3methyl-2,4-dihydropyrano[2,3-c ]pyrazole-5-carbonitriles in water. Tetrahedron Lett. 2011, 52, 3228−3231. (34) Jarocka, U.; Sawicka, R.; Góra-Sochacka, a.; Sirko, A.; ZagórskiOstoja, W.; Radecki, J.; Radecka, H. Electrochemical immunosensor for detection of antibodies against influenza A virus H5N1 in hen serum. Biosens. Bioelectron. 2014, 55, 301−306. (35) Mukundan, H.; Xie, H.; Price, D.; Kubicek-Sutherland, J. Z.; Grace, W. K.; Anderson, A. S.; Martinez, J. S.; Hartman, N.; Swanson, B. I. Quantitative Multiplex Detection of Pathogen Biomarkers on Multichannel Waveguides. Anal. Chem. 2010, 82, 136−144. (36) Hasan, K.; Meral, Y.; Babar, H.; Hikmet, B. Dual-excitation upconverting nanoparticle and quantum dot aptasensor for multiplexed food pathogen detection. Biosens. Bioelectron. 2016, 81, 280− 286. (37) Sam, S.; Touahir, L.; Andresa, J. S.; Allongue, P.; Chazalviel, J.N.; Gouget-Laemmel, A. C.; de Villeneuve, C. H.; Moraillon, A.; Ozanam, F.; Gabouze, N.; Djebbar, S. Semiquantitative Study of the EDC/NHS Activation of Acid Terminal Groups at Modified Porous Silicon Surfaces. Langmuir 2010, 26, 809−814. (38) Wang, C.; Yan, Q.; Liu, H.-B.; Zhou, X.-H.; Xiao, S.-J. Different EDC/NHS Activation Mechanisms between PAA and PMAA Brushes and the Following Amidation Reactions. Langmuir 2011, 27, 12058− 12068. (39) Puertas, S.; Moros, M.; Fernández-Pacheco, R.; Ibarra, M. R. .; Grazú, V.; de la Fuente. Designing novel nanoimmunoassays: antibody orientation versus sensitivity. J. Phys. D: Appl. Phys. 2010, 43, 474012. (40) Kaur, G.; Raj, T.; Kaur, N.; Singh, N. Pyrimidine-based functional fluorescent organic nanoparticle probe for detection of Pseudomonas aeruginosa. Org. Biomol. Chem. 2015, 13, 4673−4679.

(41) James, T. V.; Patrik, R. C. Mechanisms of Tryptophan Fluorescence Shifts in Proteins. Biophys. J. 2001, 80, 2093−2109. (42) Szabó, Á .; Szendi-Szatmári, T.; Ujlaky-Nagy, L.; Rádi, I.; Vereb, G.; Szöllő si, J.; Nagy, P. The Effect of Fluorophore Conjugation on Antibody Affinity and the Photophysical Properties of Dyes. Biophys. J. 2018, 114, 688−700. (43) Sasaki, S.; Drummen, G. P. C.; Konishi, G.-i. Recent advances in twisted intramolecular charge transfer (TICT) fluorescence and related phenomena in materials chemistry. J. Mater. Chem. C 2016, 4, 2731−2743. (44) Cho, i.-C.; Mauer, L.; Irudayaraj, J. In-situ fluorescent immuno magnetic multiplex detection of food borne pathogens in very low numbers. Biosens. Bioelectron. 2014, 57, 143−148. (45) Jiao, X.; Fei, X.; Li, S.; Lin, D.; Ma, H.; Zhang, B. Design Mechanism and Property of the Novel Fluorescent Probes for the Identification of Microthrixparvicella In Situ. Materials 2017, 10, 804. (46) Lakowicz, J. R. Principles of Fluorescence Spectroscopy, 2nd ed.; Springer: Kluwer, New York, 1999. (47) Li, Y.; Zhong, Z.; Chai, Y.; Song, Z.; Zhuo, Y.; Su, H.; Liu, S.; Wang, D.; Yuan, R. Simultaneous electrochemical immunoassay of three liver cancer biomarkers using distinguishable redox probes as signal tags and gold nanoparticles coated carbon nanotubes as signal enhancers. Chem. Commun. 2012, 48, 537−539. (48) Krithiga, N.; Viswanath, K. B.; Vasantha, V. S.; Jayachitra, A. Specific and Selective electrochemical immunoassay for Pseudomonas aeruginosa based on Pectin-Gold Nano composite. Biosens. Bioelectron. 2016, 79, 121−129. (49) Ellairaja, S.; Shenbagavalli, K.; Ponmariappan, S.; Vasantha, V. S. A green and facile approach for synthesizing imine to develop optical biosensor for wide range detection of bilirubin in human biofluids. Biosens. Bioelectron. 2017, 91, 82−88. (50) Ellairaja, S.; Manikandan, R.; Vijayan, M. T.; Rajagopal, S.; Vasantha, V. S. A simple highly sensitive and selective TURN-ON fluorescent chemosensor for the detection of cadmium ions in physiological conditions. RSC Adv. 2015, 5, 63287−63295. (51) Ellairaja, S.; Krithiga, N.; Ponmariappan, S.; Vasantha, V. S. Novel Pyrimidine Tagged Silver Nanoparticle Based Fluorescent Immunoassay for the Detection of Pseudomonas aeruginosa. J. Agric. Food Chem. 2017, 65, 1802−1812. (52) Valeur, B.; Leray, I. Design principles of fluorescent molecular sensors for cation recognition. Coord. Chem. Rev. 2000, 205, 3. (53) de Silva, A. P.; Gunaratne, H. Q. N.; Gunnlaugsson, T.; Huxley, A. J. M.; McCoy, C. P.; Rademacher, J. T.; Rice, T. E. Signaling Recognition Events with Fluorescent Sensors and Switches. Chem. Rev. 1997, 97, 1515. (54) Lu, C.; Xu, Z.; Cui, J.; Zhang, R.; Qian, X. Ratiometric and Highly Selective Fluorescent Sensor for Cadmium under Physiological pH Range: A New Strategy to Discriminate Cadmium from Zinc. J. Org. Chem. 2007, 72, 3554−3557. (55) Chudomel, J. M.; Yang, B.; Barnes, M. D.; Achermann, M.; Mague, J. T.; Lahti, P. M. Highly Twisted Triarylamines for Photoinduced Intramolecular Charge Transfer. J. Phys. Chem. A 2011, 115, 8361−8368. (56) Zhang, X.; Chi, Z.; Zhang, J.; Li, H.; Xu, B.; Li, X.; Liu, S.; Zhang, Y.; Xu, J. Piezofluorochromic Properties and Mechanism of an Aggregation-Induced Emission Enhancement Compound Containing N-Hexyl-phenothiazine and Anthracene Moieties. J. Phys. Chem. B 2011, 115, 7606−7611. (57) Sun, B.; Yang, X.; Ma, L.; Niu, C.; Wang, F.; Na, N.; Wen, J.; Ouyang, J. Design and Application of Anthracene Derivative with Aggregation- Induced Emission Charateristics for Visualization and Monitoring of Erythropoietin Unfolding. Langmuir 2013, 29, 1956− 1962. (58) Densil, S.; Chang, C.-H.; Chen, C.-L.; Mathavan, A.; Ramdass, A.; Sathish, V.; Thanasekaran, P.; Li, W.-S.; Rajagopal, S. Aggregationinduced emission enhancement of anthracene derived Schiff base compounds and their application as a sensor for bovine serum albumin and optical cell imaging. Luminescence 2018, 33, 780−789. 4823

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824

ACS Omega

Article

(59) Sun, B.; Yang, X.; Ma, L.; Niu, C.; Wang, F.; Na, N.; Wen, J.; Ouyang, J. Design and Application of Anthracene Derivative with Aggregation- Induced Emission Characteristics for Visualization and Monitoring of Erythropoietin Unfolding. Langmuir 2013, 29, 1956− 1962. (60) Mazumdar, P.; Das, D.; Sahoo, G. P.; Salgado-Morán, G.; Misra, A. Aggregation induced emission enhancement of 4,40 -bis(diethylamino)benzophenone with an exceptionally large blue shift and its potential use as glucose sensor. Phys. Chem. Chem. Phys. 2015, 17, 3343−3354. (61) Casey, K. G.; Quitevis, E. L. Effect of solvent polarity on nonradiative processes in xanthene dyes: Rhodamine B in normal alcohols. J. Phys. Chem. 1988, 92, 6590−6594. (62) Magde, D.; Wong, R.; Seybold, P. G. Fluorescence Quantum Yields and Their Relation to Lifetimes of Rhodamine 6G and Fluorescein in Nine Solvents: Improved Absolute Standards for Quantum Yields. Photochem. Photobiol. 2002, 75, 327−333. (63) Xu, S.; Bai, X.; Ma, J.; Xu, M.; Hu, G.; James, T. D.; Wang, L. Ultrasmall Organic Nanoparticles with Aggregation Induced Emission and Enhanced Quantum Yield for Fluorescence Cell Imaging. Anal. Chem. 2016, 88, 7853−7857. (64) Mehdi, H.; Gong, W.; Guo, H.; Watkinson, M.; Ma, H.; Wajahat, A.; Ning, G. Aggregation-Induced Emission (AIE) Fluorophore Exhibits a Highly Ratiometric Fluorescent Response to Zn2+ in vitro and in Human Liver Cancer Cells. Chem.Eur. J. 2017, 23, 13067−13075.

4824

DOI: 10.1021/acsomega.8b02467 ACS Omega 2019, 4, 4814−4824