Zirconium-based metal-organic framework composites for solid phase extraction of brevetoxin-A from seawater

doi:10.3724/SP.J.1123.2024.02026

Abstract

Abstract:

Red tides are a type of natural marine disaster caused by harmful algae characterized by a high toxicity, wide distribution, and long duration. Since the concentration of algal toxins in seawater increases with the occurrence of red tides, algal toxins detected in seawater could be used to predict the occurrence and evolution of red tides. Brevetoxin-A (BTX-A) is a secondary metabolite produced by the harmful algae Karenia brevis, whose detection in seawater could form the basis of an accurate warning system for incoming red tides. However, due to the inherent complexity of the seawater matrix and the extremely low levels of BTX-A in seawater, the use of instruments for its direct detection is difficult. Therefore, there is an urgent need to develop a sample pretreatment method for the efficient enrichment of BTX-A in seawater. In this study, a metal-organic backbone material (UiO-66) and its composite with silica microspheres (SiO₂@UiO-66) were successfully synthesized using the solvothermal method. The prepared SiO₂@UiO-66 exhibited good hydrophilicity, water stability, and large specific surface area. Furthermore, it also exhibited hydrogen bonding and electrostatic interactions with BTX-A, had a strong affinity for BTX-A, and was able to efficiently adsorb BTX-A in complex matrices. Therefore, SiO₂@UiO-66 showed potential as a novel packing material for the extraction of BTX-A from solid phase extraction columns. Combined with high performance liquid chromatography-tandem mass spectrometry (HPLC-MS/MS), a highly sensitive detection method for the determination of BTX-A in marine water was established. The established analytical method had a low detection limit (3.0 pg/mL), a wide linear range (10.0 -200.0 pg/mL), and a good linear relationship (R=0.9992). Combined with the Fujian Province Red Tide Monitoring and Early Warning Information 2021 issued by the Fujian Provincial Oceanic and Fisheries Bureau, the analytical method established herein was successfully applied to analyze and monitor the content of BTX-A in actual seawater samples. This highlights the proposed system’s potential for use as an early warning factor in the monitoring of red tides, representing a simple and fast pretreatment methodology for the detection of BTX-A in seawater.

Key words: metal-organic frameworks (MOFs), brevetoxin-A, solid phase extraction (SPE), high performance liquid chromatography-tandem mass spectrometry (HPLC-MS/MS), red tide

CLC Number:

O658

CHEN Zongbao, XIE Shiye, LIU Yongjun, ZHANG Wenmin, FANG Min, ZHANG Lan. Zirconium-based metal-organic framework composites for solid phase extraction of brevetoxin-A from seawater[J]. Chinese Journal of Chromatography, 2024, 42(9): 819-826.

Figures/Tables 7

Fig. 1 Schematic illustration of SiO2@UiO-66 preparation process APTES: (3-aminopropyl)triethoxysilane; PTA: p-phthalic acid.

Fig. 2 Scanning electron microscope images of (a) UiO-66 and (b) SiO2@UiO-66

Fig. 3 (a) X-ray diffraction (XRD) patterns, (b) FT-IR spectra, (c) N2 adsorption-desorption isotherms and (d) the pore size distribution of UiO-66 and SiO2@UiO-66

Fig. 4 (a) Water contact angles, (b) adsorption isotherm curves (n=3), (c) adsorption dynamics curves (n=3) of UiO-66 and SiO2@UiO-66, and (d) the Zeta potential before and after adsorption of UiO-66 and SiO2@UiO-66 BTX-A: brevetoxin-A.

Fig. 5 Optimization of (a) sample loading, (b) washing solution volume, (c) ammonium formate concentration and (d) eluent volume, and (e) maximum adsorption capacity and (f) the leakage experiment of UiO-66 and SiO2@UiO-66 SPE cartridges (n=6)

Table 1 Test results of actual samples (n=3)

Sample No.	Date	Found/ (pg/mL)	Recoveries/%			RSD^*/%
Sample No.	Date	Found/ (pg/mL)	10 pg/mL	50 pg/mL	100 pg/mL	RSD^*/%
1	6.70	N. D.	87.2	98.3	82.5	7.7
2	6.15	N. D.	94.4	92.5	86.5	7.3
3	6.21	N. D.	88.1	92.7	103.7	7.3
4	6.28	N. D.	94.2	93.4	103.9	6.7
5	7.19	N. D.	80.3	107.5	91.2	8.1
6	8.16	N. D.	87.9	81.7	96.3	8.5
7	9.17	N. D.	108.7	108.5	99.8	7.4

Fig. 6 Spiked chromatograms of actual seawater samples

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