Tetracycline Generated Red Luminescence Based on a Novel

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Agricultural and Environmental Chemistry

Tetracycline generated red luminescence based on a novel lanthanide functionalized layered double hydroxide nanoplatform Zhan Zhou, Xiangqian Li, Jinwei Gao, Yiping Tang, and Qianming Wang J. Agric. Food Chem., Just Accepted Manuscript • Publication Date (Web): 26 Mar 2019 Downloaded from http://pubs.acs.org on March 27, 2019

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Journal of Agricultural and Food Chemistry

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Tetracycline Generated Red Luminescence Based on a Novel

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Lanthanide Functionalized Layered Double Hydroxide

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Nanoplatform

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Zhan Zhou a, Xiangqian Li b, Jinwei Gao c, Yiping Tang d, Qianming Wang b*

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a. College of Chemistry and Chemical Engineering, Henan Key Laboratory of

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Function-Oriented Porous Materials, Luoyang Normal University, Luoyang 471934, PR

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China

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b. Key Laboratory of Theoretical Chemistry of Environment, Ministry of Education, School

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of Chemistry & Environment, South China Normal University, Guangzhou 510006, China

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c. Guangdong Provincial Engineering Technology Research Center For Transparent

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Conductive Materials, South China Normal University, Guangzhou 510006, China d. College of Material Science and Engineering, Zhejiang University of Technology, Hangzhou, Zhejiang, 310014, China

16 17 18 19 20 21 22

* Corresponding Author

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Tel.: 86-20-39310258, Fax: 86-20-39310187. E-mail: [email protected]; 1

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ABSTRACT : The considerable interests of lanthanide complexes in optics have been

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well known for a long period of time. But such molecular-based edifices have been excluded

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from practical application because of poor thermal or photo-stabilities. Here a novel europium

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embedded layered double hydroxide (Mg-Al LDH-Eu) has been established and such

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inorganic-organic framework demonstrates improved thermal performance due to hydrolysis

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and poly-condensation of trimethoxysilyl- unit. In addition, the incorporation of functional

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building block such as ethylenediamine triacetic acid can significantly minimize the negative

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effects of hydroxyl groups. In the presence of tetracycline (Tc), the nanoprobe exhibits an

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“off-on” change in aqueous solution and the red luminescence can be excited in the visible

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light range (405 nm). It provides a very sensitive signal response to Tc with an excellent

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linear relation in the range of 0.1 µM to 5.0 µM and the detection limit of this probe is

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measured to be 7.6 nM. This nanoplatform exhibits low cytotoxicity during in vitro

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experiments and can be employed for the detection of tetracycline in 293T cells.

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KEYWORDS: Layered double hydroxide, Lanthanide, Tetracycline, Fluorescence,

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Nanoprobe, Stability

40 41 42 43 44 45 2

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INTRODUCTION

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Tetracycline (Tc), one of the frequently-used antibiotics, may serve as effective drugs in

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human therapy or animal medicine for curing diseases and treating infections.1-3 But the

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uncontrollable usage of tetracycline would lead to a series of problems, such as bacterial

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resistances, ear injury, kidney damage, liver damage and gastrointestinal reactions.4-7

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Therefore, the development of high selectivity and sensitivity probes for monitoring Tc

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residues in environment and bio-medical analysis has caused considerable interests in

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scientific fields. Over the past decade, several analytical tools for the detection of Tc have

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been provided, such as high-performance liquid chromatography (HPLC), capillary

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electrophoresis (CE), mass spectrum (MS), fluorescence, electrochemical sensor and so on.8-12

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It has been explored that fluorescent probe possessed a few advantages because of its high

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sensitivity, ease of operation, fast-response, cost-effectiveness and real-time sensing. To date,

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numerous smart materials including gold nanoclusters, quantum dots and modified

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fluorescent dye were employed for Tc detection.13-18 However, such fluorophores would be

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easily influenced by external factors. Low thermo- or photo-stability and short-lived excited

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states would severely restrict their practical applications.

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Recently, lanthanide complexes are investigated in the range of chemical sensing in virtue

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of their special luminescence characteristics, including extraordinary color purity, high

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quantum efficiency, long lived excited states, large Stokes shifts and narrow emission

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bands.19-27 The sharp difference between lanthanide species (excited states from microsecond

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to millisecond) and conventional fluorophores (excited state in the nanosecond scale) will

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make time-resolved acquisition of emission curves and the influence of background signals 3

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would be negligible. However, the rational design of molecular-based lanthanide indicators

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still has much difficulty in real mediums due to the competitive coordination of polar solvents

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or water molecules. Consequently, quite a few new strategies have been developed for the

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integration of lanthanide complex systems into a wide range of solid supports.28-33 It is known

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that layered double hydroxide (LDH), a typical 2D inorganic layered solid host, is composed

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of positively charged layers and interlayer balancing anionic species and water molecules.34-41

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Its well-defined inorganic layered structure will certainly improve the chemical stability of

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luminescent centers and the natural basicity of LDH can effectively protect the lanthanide

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emissions. It will be the first case study for the coordination entrapment of europium complex

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into LDH matrix and its sensing performance has been explored.

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In this study, a novel lanthanide functionalized layered double hydroxide based

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fluorescent nanoprobe (Mg-Al LDH-Eu) with “turned on” effect has been afforded. Its

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detection behavior for Tc has been completely carried out in aqueous solution (Scheme 1).

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Firstly, Mg-Al LDH was prepared according to the co-precipitation method. Subsequently,

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N-(trimethoxysilylpropyl) ethylenediamine triacetic acid (EDTA) and europium (III) ions

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were incorporated to achieve Mg-Al LDH-Eu. In the presence of Tc, the emission intensity at

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618 nm was substantially improved and displayed very striking red luminescence. As for the

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case of Tc, the emission intensities followed the linear equation Y = 11.8 X + 4.05 (R2 =

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0.999) with the various concentrations of Tc (from 0.1 to 5 µM). The detection limit was

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determined

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complex-encapsulated layered double hydroxide will contribute to the development of new

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intelligent optical sensors.

to

be

7.6

nM.

This

effective

strategy

for

assembling

lanthanide

4

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EXPERIMENTAL SECTION

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Chemicals and materials. N-(trimethoxysilylpropyl) ethylenediamine triacetic acid

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sodium (EDTA, 40 wt.%), Tetracyclinehydrate (Tc), L-Alanine, (Ala, 98%), L(+)-Arginine

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(Arg, 99%), L-Asparagine (Asn, 99%), L-Glutamine (Gln, 99%), L-Aspartic Acid (Asp, 98%),

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Glycine (Gly, 99%), L-Leucine (Leu, 99%), DL-Serine (Ser, 98%), L-Tryptophan (Trp, 99%),

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L-Histidine (His, 99%), L-Lysine (Lys, 98.5%), L-cysteine (Cys, 99%), Homocysteine (Hcy,

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95%) and Glutathione (GSH, 98%) were purchased from Aladdin Reagent Company.

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Analytical grade Mg(NO3)2·6H2O, Al(NO3)3·9H2O, NH3·H2O and other reagents were

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purchased from Guangzhou Chemical Reagent Factory and used without further purification.

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Ultrapure water was used throughout this research.

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Characterizations. Fluorescence and excitation spectra were measured using a Hitachi

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F-7000 fluorescence spectrophotometer with a 150 W xenon lamp as a light source (Hitachi,

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Tokyo, Japan). Time-gated emission spectra were measured on a Edinburgh FLS980

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luminescence spectrometer with the settings of delay time, 0.2 ms; gate time,0.4 ms; cycle

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time, 20 ms; excitation slit, 5 nm; and emission slit, 5 nm. Infrared spectra were recorded by a

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Nicolet Magna 550 FT-IR instrument (resolution: 1 cm-1; range 4000-750 cm-1) with the KBr

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pellet technique (Nicolet Magna, Illinois, USA). TEM images were obtained with a JEOL

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JEM-2100HR transmission electron microscope (Hitachi, Tokyo, Japan). SEM images were

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measured with a Zeiss Ultra 55 scanning electronic microscope (Zeiss, Oberkochen,

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Germany). X-ray diffraction measurements were carried out on powder samples through a

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Bruker D8 diffractometer using Cu-Kα1 radiation (λ = 1.54 Å) (Netzsch, Selb, Germany).

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Thermogravimetric analysis was explored by a STA409PC system under air at a rate of 5

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10℃/min (Bruker, Karlsruhe, Germany). All error bars represent standard deviations from

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three repeated experiments. High performance liquid chromatography (HPLC) analysis was

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carried out by using a LC2010A HPLC system (Shimadzu, Japan). C18 column (250×4.6 mm)

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and a UV detector were used.

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Synthesis of Mg-Al LDH. Mg-Al LDH were prepared according to the co-precipitation

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method with a slight modified described in the literature.42 In brief, solution A:

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Mg(NO3)2·6H2O (0.769 g, 3 mmol) and Al(NO3)3·9H2O (0.563 g, 1.5 mmol) were dissolved

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in 40 mL of ultrapure water. Solution B: NaOH (0.4 g, 10 mmol) was dissolved in 40 mL of

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ultrapure water. Solution A and solution B were simultaneously added to a 500 mL

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round-bottomed flask and mixed for 1 min using a rotor speed of 3000 rpm. The mixture was

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placed in a 100 mL Teflon-lined stainless-steel autoclave and heated at 100℃ for 24 hours.

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The obtained milky white sample (Mg-Al LDH) was recovered by centrifugation, washed

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with ultrapure water and ethanol until the pH = 7, and vacuum-dried at 65℃ for 7 hours.

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Synthesis of Mg-Al LDH-COOH. In order to obtain the polydentate ligands to chelate

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europium (III) ions in Mg-Al LDH surface, 0.1 g of Mg-Al LDH was added into a 250 mL

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round bottom flask with 100 mL of ethanol and dispersed through ultrasonication at 0℃ for

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30 min. 0.25 mL portion of a 40 wt% hexane solution of N-(trimethoxysilylpropyl)

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ethylenediamine triacetic (EDTA) acid sodium was then added and stirred for 12 hours at 65℃

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for silanization. Then, 100 mL of methanol was added to dilute the unreacted silane solution.

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The product was obtained by filtration and washed sequentially with methanol, water, and

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acetone. Then the samples were vacuum-dried at 65℃ for 7 hours.43,44

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Synthesis of Mg-Al LDH-Eu. The obtained carboxyl groups modified Mg-Al 6

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LDH-COOH (100 mg) was added in a round bottom flask with 20 mL bicarbonate buffer (10

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mM, pH = 9.6). Then, Eu(NO3)3·6H2O (50 mg) was added to the mixture with stirring for 2

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hours. After completely reaction, Mg-Al LDH-Eu was collected by centrifugation, washed

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with ultrapure water for three times to remove the excessive europium ions and vacuum-dried

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at 65℃ for 7 hours.

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Detection of Tc in aqueous solution. To verify the feasibility of the Mg-Al LDH-Eu as

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the biosensor for Tc, 1 mL of Mg-Al LDH-Eu aqueous solution (0.1 mg/mL) was injected to

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a spectrophotometer quartz cuvette. Then various concentrations of Tc (0-7 µM) were added,

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the fluorescence emission spectra were recorded under excitation at 405 nm. For comparison,

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control experiments were conducted by replacing Tc with other interfering analytes (0.1 mM),

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including amino acids (GSH, Cys, Hcy, Ala, Arg, Asn, Gln, Asp, Gly, Leu, Ser, Trp, His,

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Lys), common cation ions (Cu2+, Fe2+, Fe3+, Zn2+, Cd2+, Hg2+) and common anions (ClO-,

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NO2-, NO3-, CO32-, HCO3-, Ac-, PO43-, HPO42-, MnO42-, Cr2O72-, SO42-, SO32-, HS-, F-, Cl-),

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respectively.

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Detection of Tc in real samples. For Tc detection in real sample, milk samples were

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collected from the local supermarket. The various volumes of the standard Tc were added into

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the corresponding vial to obtain the different final concentrations (1.0, 2.0 and 3.0 µM).

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Finally, the probe was added into the above solution and subjected to measure the

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concentration of Tc, respectively. The fluorescence emission spectra were recorded under

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excitation at 405 nm and calculated the concentration of Tc using the linear equation,

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respectively. As for HPLC analysis, the pretreatment process for the raw milk was performed

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according to the literature.45 The HPLC operation parameters were given as follows: mobile 7

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phase: 0.01 M oxalic acid/acetonitrile/methanol (80:15:5, v/v/v) at 1 mL/min; the column

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temperature was kept at 40 oC; UV detection wavelength was fixed at 350 nm; an aliquot of

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60 μL was injected. Tetracycline standard solutions of 0.5, 1.0, 1.5, 2.0, 2.5 and 3.0 µM were

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prepared and determined by HPLC for the establishment of a standard curve.

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Cell culture and viability assay. 293T cell was cultured in Dulbecco’s modified medium

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(DMEM) supplemented with 10% fetal bovine serum (FBS) and 1% antibiotics penicillin (PS)

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and maintained at 37℃ under an atmosphere of 5%CO2. To investigate the cytotoxicity of

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Mg-Al LDH-Eu, the 293T cells (106 cells/well) were dispersed within replicated 12-well

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microtiter plates and incubated for 24 h at 37℃ under an atmosphere of 5% CO2. After

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removal of the medium, cells were cultured with fresh medium containing various

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concentrations of Tc(0, 2, 7 M) for another 24 h. The cytotoxicity of Mg-Al LDH-Eu (0.1

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mg/mL) was evaluated by MTT assay based on ISO 1099.

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Cell imaging. Cells were added on polylysine-coated cell culture glass slides inside the 30

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mm glass culture dishes. The cells were washed with DMED medium and incubated in the

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fresh medium containing Mg-Al LDH-Eu (0.1 mg/mL) at 37℃ for 2 h. Cells were washed

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with medium again and further cultured for another 0.5 h with the various concentrations of

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Tc (0, 2, and 7 M). The cells were imaged on a Leica confocal laser scanning microscope

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(TCS SP5 CLSM) equipped with a UV laser (405 nm).

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RESULTS AND DISCUSSION

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The inorganic layered compounds possess excellent surface features to be modified for

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the construction of host-guest interactions and its microstructure has been explored. The size 8

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and morphology of the as-prepared Mg-Al LDH and Mg-Al LDH-Eu were examined by

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transmission electron microscopy (TEM) and scanning electron microscope (SEM). Mg-Al

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LDH gave rise to a moderately narrow particle size distribution with a polydispersity index

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(PDI) of 0.162, suggesting Mg-Al LDH was homogenously dispersed in aqueous solution.

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The average particle size of Mg-Al LDH was 126.8 nm (Figure S1). TEM images (Figure 1A,

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B) showed that Mg-Al LDH was randomly dispersed and possessed plate-like morphology. It

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has been observed that Mg-Al LDH was composed of numerous sheets from side views and

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the lateral dimension of the nanosheets was determined to be about 100 nm (Figure 1C,D),

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which was consistent with the particle size distribution given by DLS (Figure S1). The lattice

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fringe spacing of about 0.15 nm was attributed to the (110) plane of an Mg-Al LDH phase

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(Figure 1B, inset).46 SEM images indicated that the Mg-Al LDH samples possessed uniform

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plate-like morphology and the surface was smooth (Figure 1C,D). Elemental analysis of

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Mg-Al LDH by using energy-dispersive X-ray spectroscopy (EDS) indicated that it’s

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composed of C, N, O, Mg and Al elements (Figure 2A). After the surface was functionalized

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with EDTA group and the encapsulation of europium ions, the microstructures of Mg-Al

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LDH-Eu with round shapes and average particle size of 100 nm were identified (Figures S1,

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S2). A lattice spacing of 0.15 nm with (110) facet was also observed and the result was very

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similar to bare Mg-Al LDH. Several lamellar structures were observed in perpendicular

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directions. Although the grafting reaction induced slight changes, the influence on the internal

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structure of the free Mg-Al LDH due to the surface modification with lanthanide complexes

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would be limited. Elemental analysis of Mg-Al LDH-Eu by using energy-dispersive X-ray

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spectroscopy (EDS) indicated that it’s successful assembly and chelation of europium ions 9

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(Figure 2B).

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FT-IR spectra of Mg-Al LDH, Mg-Al LDH-COOH, Mg-Al LDH-Eu were carried out for

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the investigation of the modification and coordination processes. As provided in Figure 3, a

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broad band in Mg-Al LDH centered at 3405 cm-1 was observed, which was attributed to the

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stretching vibration of the hydroxyl group from both the interlayer water and hydroxide layers.

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The band at 1350 cm-1 was ascribed to the stretching vibration of nitrate anions.47 In the curve

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of Mg-Al LDH-COOH, the emerging intense absorption bands at about 2959, 2920 and 2849

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cm-1 were assigned to the stretching vibrations of methylene groups from EDTA units.48 The

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band at 1034 cm-1 was ascribed to the stretching vibration of Si-O bond.49 In addition, two

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typical bands at 1680 and 1580 cm-1 were corresponding to the stretching vibrations of

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carboxylate units. These results revealed that EDTA has been successfully grafted to the

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Mg-Al LDH surface by Mg(Al)-O-Si bonds and the surface contained quantities of functional

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carboxyl groups. Notably, after the introduction of europium ions, the peaks in Mg-Al

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LDH-COOH at 1680 and 1580 cm-1 were shifted to 1665 and 1535 cm-1 in the curve of

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Mg-Al LDH-Eu, respectively. It was clear that the carboxyl groups were involved in the

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chelation reaction with europium ions.

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The powder X-ray diffraction (XRD) patterns of the synthesized Mg-Al LDH, Mg-Al

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LDH-COOH and Mg-Al LDH-Eu were given in Figure 4. Mg-Al LDH prepared by the

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conventional co-precipitation method showed the typical LDH diffraction peaks. The

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diffraction peaks indexed to the (003), (006), (009) and (110) planes supported the presence

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of Mg-Al LDH as the matrix.42,50 The sharpness and symmetry of these peaks indicated that

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the prepared LDH was in a highly crystalline phase. Upon grafting EDTA groups and 10

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chelated europium ions, the obtained Mg-Al LDH-Eu displayed almost the same reflections

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as that of Mg-Al LDH, showing that the silanization and the incorporation of lanthanide

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complexes could hardly affect the crystalline integrity of Mg-Al LDH. So far as Mg-Al

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LDH-Eu was concerned, the diffraction peaks were nearly identical with the Mg-Al LDH and

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slight changes of the peak intensities were monitored. Hence, the surface functionalized with

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EDTA groups and the incorporation of europium ions would lead to negligible changes of the

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structural regularity of original layered double hydroxide.

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The thermogravimetric (TGA) analysis of Mg-Al LDH-Eu and EDTA-Eu complex was

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performed to evaluate their thermal stability. As presented in Figure 5, the first weight loss of

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10% in the range of 30-180℃ was primarily caused by the adsorbed solvent species and

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coordinated water molecules from EDTA-Eu complex. The results revealed that the

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EDTA-Eu complex had decomposed at around 340℃, while the weight of the Mg-Al

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LDH-Eu nanocomposites decreased much slower in the temperature range from 30-340℃.

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The formation of strong hydrogen bonds between the carbonyl oxygen atoms of coordinated

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carboxylate groups and the LDH layers can be closely related to such results. Based on the

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TGA curves of EDTA-Eu complex and Mg-Al LDH-Eu, it could be said that the Mg-Al LDH

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would substantially improve the thermal stability of EDTA-Eu complex.

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pH value is a key factor and can possibly exert influence on the formation of resultant

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materials. The effects of pH on the microstructure of Mg-Al LDH-Eu were investigated and

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the diffraction peaks remained almost unchanged between pH = 5 and pH = 11 (Figure S3).

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When the pH value was less than 5.0 (pH = 4.0), the acidic environment would dissolve the

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hydroxide precipitates and its crystalline structure would be affected. Since the layered double 11

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hydroxides were considered to be alkaline supports, the increasing pH values would be

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favorable for maintaining the stability. But the higher alkaline solution (pH = 12) would also

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induce leaching problem of europium ions and such lanthanide element with positive charges

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might be involved in the coordination with hydroxide. It was found that europium ions were

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absent in the corresponding EDS spectrum (Figure S4). Temperature is also very important

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for its practical uses. Based on XRD evolution curves, it has been found that its crystalline

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structure was kept relatively stable until the heating treatment was elevated to 100 oC (Figure

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S5) and higher temperature (150 oC) would cause the dissociation of the internal structure.

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Fluorescent sensing allowed the control of chemical process and the host-guest

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interactions would result in a detectable optical response. The capability of Mg-Al LDH-Eu to

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recognize Tc was examined by introducing Tc to the Mg-Al LDH-Eu aqueous solution. As is

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described in Figure 6, in the presence of various concentrations of Tc (0-7 µM), the Mg-Al

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LDH-Eu solution exhibited narrow emission bands that were assigned to the deactivation of

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the Eu (III) excited states (5D0-7F0, 5D0-7F1, 5D0-7F2, 5D0-7F3 and 5D0-7F4) under 405 nm

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excitation (excitation spectrum was shown in Figure S6). In particular, the fluorescence

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changes could be perceived clearly by naked-eye under the UV-light excitation at 365 nm

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(Figure 6, inset photo). The correlation between the emission ratio intensity F/F0 (F0

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represents the fluorescence intensity of Mg-Al LDH-Eu at 618 nm without Tc, F represents

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the fluorescence intensity of Mg-Al LDH-Eu at 618 nm at various concentrations of Tc) and

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the concentration of Tc followed the linear equation Y = 11.8 X + 4.05 (R2 = 0.999) and the

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calibration curve was achieved (Figure 6, inset). The detection of limit (DL) was calculated to

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be 7.6 nM through the equation DL = 3 × SD/slope. SD refers to the standard deviation of the 12

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blank solutions and the value of denominator is corresponding to the slope of the calibration

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curve.

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As for clarification of detection process, it is closely related to electronic configurations of

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lanthanide ions. These elements possess f-f forbidden transitions and the extinction

270

coefficients are quite small. The nature of lanthanide luminescence is completely different

271

from molecular signal of organic compounds. Direct excitation of lanthanide ion will be very

272

inefficient and generally a sensitizing chromophore would be incorporated to realize the

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antenna effect via intramolecular energy transfer.51 In this contribution, the organic ligand

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N-(trimethoxysilylpropyl) ethylenediamine triacetic acid was selected for the coordination

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with europium ions. However, such EDTA type ligand generated very weak absorbance in

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ultra-violet region and no effective lanthanide emission was monitored based on Mg-Al

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LDH-Eu (Fig. 6, starting line). Tetracycline owns several proton-donating groups and

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carbonyl units which would show strong affinity to the binding reaction with europium ions.

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Moreover, it effectively harvested ultra-violet energy and the peak wavelength was located at

280

360 nm (Fig. S7). Because of complexation with europium ions, tetracycline would form

281

stable chelates which demonstrated broad-band excitation (Fig. S6) and the sharp emission

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peaks derived from 5D0-7FJ transitions.

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The interference study of the probe is a highly significant factor for the evaluation of

284

fluorescence sensor performance. To evaluate the selectivity of the developed nanomaterial, a

285

series of interferential amino acids (GSH, Cys, Hcy, Ala, Arg, Asn, Gln, Asp, Gly, Leu, Ser,

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Trp, His, Lys), common cations ions (Cu2+, Fe2+, Fe3+, Zn2+, Cd2+, Hg2+) and anions (ClO-,

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NO2-, NO3-, CO32-, HCO3-, AcO-, PO43-, HPO42-, MnO42-, Cr2O72-, SO42-, SO32-, HS-, F-, Cl-) 13

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were examined. Within expectation, no specific optical responses were achieved in the

289

presence of various species (Figure S8). Additionally, several analogues including

290

chloramphenicol, oxytetracycline, gentamycin, amoxicillin, hemoglobin, human albumin,

291

sparfloxacin, marbofloxacin and glucose were measured and no specific “turned-on” effects

292

were observed (Fig. S9). Sarafloxacin could lead to a slight change at a concentration of 20

293

μM. But its improvement ratio was much less than that of tetracycline. These results revealed

294

that nanoprobe owned excellent selectivity towards Tc.

295

In recent years, the new system concerning the detection of tetracycline has also been

296

developed.52 In this work, the layered double hydroxides have been employed in terms of

297

their special layered frameworks, large surface area and extended internal structures. These

298

excellent adsorption capabilities would be very favorable for improving the resultant

299

sensitivity and detection potentials. In addition, LDHs were derived from very cheap

300

precursors (magnesium and aluminum salts) and regarded as cost-effective. Moreover, LDHs

301

possessed very low toxicity and in this study, it has been found in the following study that

302

Mg-Al LDH-Eu gave rise to live cell-staining features in the presence of tetracycline. As for

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the choice of lanthanides, a few literatures described the preparation of rare earth doped

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upconversion nanoparticles and their sensing abilities were extensively evaluated.53,54

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Different from the published work, our study was focused on the down-conversion mode of

306

lanthanide luminescence. Furthermore, the emissive lanthanide ion (Eu3+) was not located

307

within the inorganic crystal lattice such as NaYF4 and we established coordination structure in

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this hybrid system. It is accepted that lanthanide luminescence would be affected by high

309

frequency vibrations of hydroxyl groups.51 Here we used the powerful organic ligand 14

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(ethylenediamine triacetic acid units) with multiple carboxyl groups and nitrogen atoms to

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firmly bind with europium ions and the negative influence of water molecules would be

312

suppressed. More importantly, the low thermal stability of lanthanide complex structure could

313

be reinforced (Fig. 5) by the incorporation of it into solid matrice such as LDH and the

314

inorganic-organic hybrid material was achieved.

315

As for the stability of original material (Mg-Al LDH-Eu), we measured its XRD curve

316

when it was synthesized initially in the middle of last December, 2018. In the middle of

317

January, 2019, its XRD pattern was measured for the second time. Recently, we prepared the

318

material again and it was also explored by XRD analysis. The collected results exhibited that

319

the crystalline structures maintained relatively stable after almost two months (Fig. S10).

320

During the photoluminescence studies in the presence of Tc on different days, the

321

enhancement ratio of peak intensity at 618 nm was almost the same (Fig. S11). It revealed

322

Mg-Al LDH-Eu possessed enough stability for the monitoring of tetracycline.

323

In order to investigate the application of nanoprobe, it was employed to determine Tc in

324

milk samples. Different amounts of Tc were spiked into the samples, and the measured

325

concentrations were determined in real environments. The obtained results were provided in

326

Table S1. The recovery of the spiked sample was ranged from 97.0% to 100.8% with relative

327

standard deviation (RSD) less than 1.08%. For the sake of elucidating the reliability of the

328

proposed method, we have employed high performance liquid chromatography (HPLC)

329

analysis for the comparison purpose. Three milk samples spiked with different concentrations

330

of tetracycline were measured by HPLC. Based on Table S2, it can be found that the

331

recoveries varied from 95 to 99.5 % and the results were in agreement with the 15

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332

above-mentioned technique. It indicated that fluorescent method in this contribution would be

333

reproducible and accurate for the detection of tetracycline and such nanoprobe can

334

quantitatively detect Tc in practical samples with good performance.

335

With the aim of expanding its applicability, a fat-containing concentrated milk sample

336

(Nestle, Carnation Evaporated Milk) was selected. It has been well-documented that the

337

special property of trivalent lanthanide ions with long excited states would be valuable in

338

practical fields. The employment of time-resolved spectra will effectively decrease the

339

background signals and auto-fluorescence effects. The red emission was turned on in the

340

presence of different concentrations of Tc in a well-resolved manner and the spectra were

341

recorded over a period of 0.2 ms by using of long lifetime of lanthanide elements (Fig. S12).

342

Based on the reported literatures concerning several different lanthanide appended

343

nanostructures, generally they had negligible toxicity during in vitro studies.55,56 To explore

344

the cytotoxicity of Mg-Al LDH-Eu in live cells, methyl thiazolyl tetrazolium (MTT) assay

345

was used (Fig. S13). Following incubation with Mg-Al LDH-Eu (0.2 mg/mL) for 24 hours,

346

the cellular viabilities of 293 T cells were well above 90 %, indicating that the achieved

347

material possessed very low cytotoxicity. After the cells were incubated with Mg-Al LDH-Eu

348

for 2 h, confocal microscopic images exhibited no emissions and such phenomenon was

349

consistent with the photoluminescence results (Fig. 6). Interestingly, the red luminescence

350

was switched on upon exposure of cells to 2 μM of Tc and the red signal was improved in the

351

presence of 7 μM of Tc, suggesting that tetracycline can be monitored inside living cells (Fig.

352

7).

353

The detection of Tc would be very important and beneficial for many applications. Herein, 16

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we have designed and developed a novel lanthanide functionalized layered double hydroxide

355

(LDH) fluorescent nanoprobe for light-up and detection of Tc. The probe could quantitatively

356

determine the concentrations of Tc with excellent selectivity, high sensitivity, as well as low

357

limit of detection (7.6 nM). The nanoprobe has been successfully applied to the determination

358

of Tc in milk sample and also in 293 T cells. This research will enable the utilization of

359

unique luminescence properties of lanthanides in the development of new intelligent optical

360

sensors.

361 362

ASSOCIATED CONTENT

363

Supporting information available

364

Size distribution, SEM and TEM images of Mg-Al LDH and Mg-Al LDH-Eu; XRD patterns

365

and EDS survey at different conditions; Excitation spectrum of nanoprobe and UV-visible

366

spectrum of Tc; Emission responses in the presence of various interfering species; Stability

367

experiments; Time-gated spectra of Mg-Al LDH-Eu in fat-containing milk sample upon the

368

addition of various concentrations of Tc; Viability of 293T cells were treated with various

369

concentrations of Mg-Al LDH-Eu; Recoveries of Tc in milk samples detected by the

370

proposed approach and HPLC method.

371 372

Funding

373

J. W. thanks grants from National Natural Science Foundation of China (NSFC)-Guangdong

374

Joint funding support (No. U1801256) and Innovation team project by the Department of

375

Education of Guangdong Province (2016KCXTD009). Z. Zhou is grateful to the Scientific 17

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Research Fund of Henan Provincial Education Department (17A150016) and Natural Science

377

Foundation of Henan (162300410200).

378 379

REFERENCES

380

(1) Liu, X. G.; Huang, D. L.; Lai, C.; Zeng, G. M.; Qin, L.; Zhang, C.; Yi, H.; Li, B. S.;

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Deng, R.; Liu, S. Y.; Zhang, Y. J. Recent advances in sensors for tetracycline antibiotics and

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(53) Liu, Y.; Ouyang, Q.; Li, H.H.; Chen, M.; Zhang, Z.Z.; Chen, Q.S. A turn-on

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538

(55) Chauvin, A.S.; Comby, S.; Song, B.; Vandevyver, C.D.B.; Thomas, F.; Bunzli, J.C.G. A

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polyoxyethylene-substituted bimetallic europium helicate for luminescence staining of living

540

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Trans. 2016, 45, 7435-7442.

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Figure captions

553

Scheme 1 Schematic illustration of preparation and sensing processes of Mg-Al LDH-Eu for

554

Tc (Step I: Co-precipitation reaction among Mg(NO3)2·6H2O, Al(NO3)3·9H2O and NaOH;

555

Step II: Hydrothermal treatment for 24 h and Mg-Al LDH was afforded; Step III: Silanization

556

reaction with N-(trimethoxysilylpropyl) ethylenediamine triacetic (EDTA) acid sodium; Step

557

IV: Encapsulation of europium ions and Mg-Al LDH-Eu was obtained; Step V: An “off-on”

558

recognition process in the presence of tetracycline ).

559

Figure 1 TEM image of Mg-Al LDH (A), Lattice fringe and TEM image of Mg-Al LDH (B),

560

SEM images of as-prepared Mg-Al LDH (C and D).

561

Figure 2 EDS survey of Mg-Al LDH (A) and Mg-Al LDH-Eu (B).

562

Figure 3 FT-IR spectra of Mg-Al LDH (a), Mg-Al LDH-COOH (b) and Mg-Al LDH-Eu (c).

563

Figure 4 XRD patterns of Mg-Al LDH, Mg-Al LDH-COOH and Mg-Al LDH-Eu.

564

Figure 5 TG curves of the prepared Mg-Al LDH-Eu and EDTA-Eu complex.

565

Figure 6 Fluorescence titration spectra of Mg-Al LDH-Eu aqueous solution (0.1 mg/mL)

566

upon addition of different concentrations of Tc (0-7 µM). (Inset: (left) photographs of Mg-Al

567

LDH-Eu (0.1 mg/mL) alone and in the presence of 7 µM Tc exposed to a UV lamp at 365 nm,

568

(right) linear relationship between the fluorescence intensity ratio (F/F0) and the

569

concentrations of Tc (0.1-5 µM), (λex = 405 nm; λem = 618 nm)).

570

Figure 7 Confocal microscopy images of Mg-Al LDH-Eu (0.1 mg/mL) in 293T cells. The

571

cells were incubated with only Mg-Al LDH-Eu (0.1 mg/mL) for 2 h as control (A). The cells

572

were further incubated with 2 µM (B), or 7 µM (C)Tc for 1 h.

573 26

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574 575 576 577

578 579

Scheme 1

580 581 582 583

27

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584 585

Figure 1

586 587

588 589

Figure 2

590 591 592 593 594 28

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a

-

1350 (NO3 )

Transmittance

b

3405 (O-H) 2963, 2913, 2847 (-CH2-) 1034 (Si-O)

-

1680 (COO , asymmetric)

c

-

1580 (COO , symmetric)

-

1665 (COO , asymmetric) -

1535 (COO , symmetric)

4000

3500

3000

2000

Wavenumber cm

596 597

2500

1500

1000

-1

Figure 3

598 599

Intensity / a.u.

Mg-Al LDH-Eu

Mg-Al LDH-COOH

(003)

(006)

Mg-Al LDH (009)

10

30

40

50

60

70

2  / degree

600 601

20

(110)

Figure 4

602 603

29

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604 605

1.0

EDTA-Eu complex Mg-Al LDH-Eu

Mass / %

0.8 0.6 0.4 0.2 0.0

400

600

800

Temperature / C

606 607

200

Figure 5

608 609

1000 Y = 11.8 X + 4.05 2 R = 0.999

800

40 20

600 400

0

7 M

0

1

2

3

4

5

Tc concentrations / M

Tc 0 M

200 0 550

600

650

700

Wavelength / nm

610 611

F/F0

Relative intensity / a.u.

60

Figure 6

612 30

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613 614 615 616 617

618 619

Figure 7

620 621 622 623 624 625 626 627 628 629 630 31

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Table of Contents Graphic

634

635 636 637

A novel europium embedded layered double hydroxide (Mg-Al LDH-Eu) offers an alternative

638

way to newly-developed analytical approaches. It displays rapid and highly selective

639

detection to tetracyclines (Tc) in water and milk. This nanoplatform exhibits low cytotoxicity

640

during in vitro experiments and can be employed for the detection of tetracycline in 293T

641

cells.

642 643 644

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