中空纳米材料的制备及其在样品前处理中的应用进展

doi:10.3724/SP.J.1123.2022.09027

摘要/Abstract

摘要：

样品前处理技术在复杂样品(如生物、食品和环境等样品)的分析过程中起着至关重要的作用,是整个分析过程的关键,其主要目的是使待测物与样品基质或样品中的干扰物质分离,并达到仪器可以分析检测的状态。对于样品前处理技术而言,有着优异吸附性能的吸附剂是核心和关键,因此开发具有高选择性和高富集性的吸附材料是该技术目前面临的最大挑战。近年来,各类性能优异的纳米材料被应用于样品前处理领域,发展了众多具有功能多样化、高选择性、高富集性的纳米萃取材料。中空纳米材料是一类在固体壳内具有很大空隙的纳米粒子,因有较大的有效表面积、丰富的内部空间、短的质量传输路径和较高的承载能力等优点,在样品前处理领域表现出了巨大的应用潜力,其主要是通过π-π堆积、静电、氢键以及疏水作用等相互之间的协同作用实现对目标分析物的高效分离和富集。同时由于中空纳米材料优异的物理化学性能,也获得了各个研究领域的广泛关注,成为材料科学的研究前沿。但是,中空纳米材料的合成方法仍存在步骤复杂、成本较高、条件相对严苛、涉及剧毒物质等问题。本文总结了中空纳米材料的主要类型、合成方法以及在样品前处理中的研究进展,探讨了中空纳米材料在合成方法上遇到的挑战。最后,对中空纳米材料在样品前处理中的应用及发展进行了展望。

关键词: 中空纳米材料, 样品前处理, 应用, 研究进展

Abstract:

Sample pretreatment technology plays a vital role in the analysis of complex samples and is key to the entire analytical process. Its main purpose is to separate the substance to be measured from the sample matrix or interfering substances in the sample and to achieve a state in which the instrument can be analyzed and detected. Traditional sample pretreatment techniques include liquid-liquid extraction, liquid-solid extraction, precipitation separation, solvent volatilization-rotary evaporation, filtration, and centrifugation. However, the applications of these methods are limited by their low extraction efficiency, complicated operation, long time consumption, unstable recovery, use of large amounts of organic solvents, and large error rates. Several new sample pretreatment techniques, including solid-phase extraction, magnetic solid-phase extraction, solid-phase microextraction, and dispersive solid-phase extraction, have been developed and rapidly applied to various fields to overcome the shortcomings of traditional sample pretreatment methods. However, the development of adsorbent materials with high selectivity and enrichment capability remains a challenge in sample pretreatment technology, in which adsorbents with excellent adsorption performance are crucial. In recent years, various nanomaterials with remarkable properties have been introduced and applied to sample pretreatment, and numerous nano-extraction materials with diverse functions and high selectivity and enrichment capability have been developed. Hollow nanomaterials are nanoparticles with large voids in their solid shells. Owing to their advantageous properties, which include a large effective surface area, abundant internal space, low density, variety of preparation methods, structural and functional tailorability, short mass transmission path, and high carrying capacity, hollow nanomaterials show great application potential in sample pretreatment. The extraction mechanism of these materials is based on the synergistic effects of π-π stacking, electrostatic, hydrogen-bonding, and hydrophobic interactions to achieve the efficient separation and enrichment of the target analytes. Given their noteworthy physicochemical properties, hollow nanomaterials have gained wide attention in various research fields and are considered a research frontier in the field of materials science. Changing the structure or surface properties of the core and shell can lead to various hollow nanomaterials with unique properties. Such changes can create synergy between the physicochemical properties and structural function of the original core-shell material, leading to novel materials with superior performance compared with the starting materials and broad application prospects in sample pretreatment. Nevertheless, only a few hollow nanomaterials with diverse structures and functions are currently used for sample pretreatment, and their adsorption capacity for target analytes is often unsatisfactory. Consequently, enhancing the adsorption selectivity of these materials toward various analytes is the most important step in sample pretreatment. First, hollow nanomaterials with a large specific surface area and suitable pore size can be designed to achieve the specific adsorption of target analytes of varying sizes. The combination of hollow nanomaterials with other materials presenting desirable adsorption properties could also lead to synergistic effects and enhance the performance of composite hollow nanomaterials. In addition, more green methods to prepare hollow nanomaterials with outstanding selectivity can be explored to achieve the superior adsorption of a specific target analyte. Efforts to synthesize hollow nanomaterials have been met with great success, but the available synthesis methods still suffer from complicated steps, high costs, relatively harsh conditions, and the use of highly toxic substances. This paper summarizes the main types of hollow nanomaterials, their synthesis methods, and research progress on sample pretreatment technologies (solid-phase extraction, solid-phase microextraction, magnetic solid-phase extraction, and dispersive solid-phase extraction) and describes the challenges encountered in the synthesis of hollow nanomaterials. The applications and developments of hollow nanomaterials in sample pretreatment are also discussed.

Key words: hollow nanomaterials, sample pretreatment, application, research progress

中图分类号:

O658

王雪梅, 黄丽霞, 袁娜, 黄鹏飞, 杜新贞, 卢小泉. 中空纳米材料的制备及其在样品前处理中的应用进展[J]. 色谱, 2023, 41(6): 457-471.

WANG Xuemei, HUANG Lixia, YUAN Na, HUANG Pengfei, DU Xinzhen, LU Xiaoquan. Progress in preparation of hollow nanomaterials and their application to sample pretreatment[J]. Chinese Journal of Chromatography, 2023, 41(6): 457-471.

图/表 15

图1 采用溶剂热法合成壳层厚度和空穴空间可控的C掺杂ZnO微球[14]

Fig. 1 Synthesis of C-doped ZnO microspheres with controllable shell layer thickness and cavity space by solvothermal method[14]

图2 核壳纳米颗粒Fe3O4@Carbon@ZIF-8的合成路线[19]

Fig. 2 Detailed synthesis route of magnetic carbon@zeolite imidazole ester skeleton-8 (Fe3O4@Carbon@ZIF-8) core-shell nanoparticles[19]

图3 五壳层SnO2空心微球形成过程示意图[23]

Fig. 3 Schematic illustration of the formation process of quintuple-shelled SnO2 hollow microspheres[23]

图4 m-BiVO4的形态演变示意图[26]

Fig. 4 Sketch map of the evolution of morphology changing of m-BiVO4[26]

图5 所制备的TiO2纳米结构的溶剂特性和形态行为之间的相关性示意图[29]

Fig. 5 Schematic diagram of the correlation between solvent properties and morphological behaviors of the prepared TiO2 nanostructures[29]

图6 独特中空纳米材料八面体NiO的形成机理示意图[31]

Fig. 6 Schematic illustration of formation mechanism of unique hollow NiO nanooctahedron[31]

图7 (a)ZnO空心微球的形成示意图与(b-e)ZnO空心微球在溶热时间分别为2、6、12、24 h的演变过程[33]

Fig. 7 (a) Schematic illustration of the formation of ZnO hollow microspheres and (b-e) the evolution of ZnO hollow microspheres with solvothermal time of 2, 6, 12, 24 h, respectively[33]

图8 多壳氧化铜空心球的形成示意图[37]

Fig. 8 Schematic illustration of formation of multi-shelled copper oxide hollow spheres[37]

图9 (a)MMTNS@CS-HMPHS的合成过程示意图及其(b)独特微观结构和潜在应用[40]

Fig. 9 (a) Schematic illustration of the route for preparing, and (b) unique microstructure and potential applications of montmorillonite hollow and graded mesoporous microspheres (MMTNS@CS-HMPHS)[40]

图10 制备稳定的硫化空心LMNO的示意图[42]

Fig. 10 Schematic illustration for the fabrication of stable vulcanized hollow lithium-rich layered cathode nanomaterials (LMNO)[42]

图11 h-PDA@L-lys的合成过程[49]

Fig. 11 Synthesis process of the L-lysine modified polydopamine coated shell (h-PDA@L-lys)[49]

图12 Co3O4/C中空纳米材料的合成机理[59]

Fig. 12 Synthetic mechanism of Co3O4/C hollow nanomaterials[59]

图13 MSPE的示意图和CoO@C的制备过程[70]

Fig. 13 Schematic of magnetic solid-phase extraction (MSPE) and preparation process of porous cage-like hollow magnetic carbon doped cobalt oxide nanocomposites (CoO@C)[70]

图14 核壳纳米复合材料In2S3@MIL-125(Ti)的合成过程示意图[83]

Fig. 14 Synthesis procedure of the core-shell nano-composite indium(Ⅲ) sulfide@metal-organic backbone (In2S3@MIL-125(Ti))[83]

表1 中空纳米材料在样品前处理中的应用

Table 1 Application of hollow nanomaterials in sample pretreatment

Method	Type of materials	Analytes	Combined method	Linear range	LODs	Ref.
SPE	CHPMs	V(Ⅴ), Cr(Ⅲ), Cu(Ⅱ), Cd(Ⅱ), Pb(Ⅱ)	ICP-MS	0.05-15 μg/L	0.8-3.2 ng/L	[47]
	NiCo₂O₄	Pb(Ⅱ)	FAAS	0.5-10 mg/L	5.9 μg/L	[48]
	h-PDA@L-lys	BR	HPLC	-	-	[49]
SPME	HCNCs	PAHs	GC-MS	5-2000 ng/L	0.03-0.70 ng/L	[57]
	Co₃O₄/C	PAHs	HPLC	0.005-1000 μg/L	0.002-2.680 μg/L	[59]
	Fe₂O₃/CeO₂@MnO₂	PAHs	GC-MS	0.04-100 μg/L	0.38-3.57 ng/L	[60]
MSPE	CoO@C	PAHs	HPLC	0.5-1000 μg/L	0.06-1.30 μg/L	[70]
	Fe₃O₄@C	PBDEs	GC-MS	1-1000 ng/L	0.07-0.17 ng/L	[72]
	Fe₃O₄@COFs	DPA	HPLC	0.1-100 mg/L	0.02-0.08 mg/L	[73]
	Fe₃O₄@MIL-100	triclosan	HPLC	0.1-50 mg/kg	0.03 mg/kg	[74]
DSPE	BNHSs	PCBs	GC-MS	0.15-250 ng/L	0.04-0.09 ng/L	[82]
	In₂S₃@MIL-125(Ti)	NPAHs	GC-MS	10-1000 ng/L	2.9-83.0 ng/L	[83]

参考文献

[1]	Ouyang X Y, Lu Z C, Hu Y L, et al. J Sep Sci, 2021, 44(4): 879
[2]	Liu W X, Song S, Ye M L, et al. Nanomaterials(Basel), 2022, 12(11): 2079
[3]	Feng J J, Sun M X, Feng Y, et al. Chinese Journal of Chromatography, 2022, 40(11): 953
[3]	冯娟娟, 孙明霞, 冯洋, 等. 色谱, 2022, 40(11): 953
[4]	Zhu F, Ruan W H, He M H, et al. Anal Chim Acta, 2009, 650(2): 202
[5]	Diuzheva A, Dejmková H, Fischer J, et al. Microchem J, 2019, 150: 104071
[6]	Zhao J L, Huang P F, Wang X M, et al. Sep Purif Technol, 2022, 287: 120608
[7]	Geng L, Liu Q N, Chen J Z, et al. Nano Res, 2021, 15(3): 2650
[8]	Wang J Y, Wan J W, Wang D. Acc Chem Res, 2019, 52(8): 2169
[9]	Wang J Y, Yang M, Wang D. Chinese J Chem, 2022, 40: 1190
[10]	Wang J Y, Wang Z M, Mao D. et al. Sci China Chem, 2021, 65(1): 7
[11]	Wei Y Z, Yang N L, Huang K K. et al. Adv Mater, 2020, 32(44): e2002556
[12]	Zhao X H, Li Y Y, Gong Q M, et al. Carbon, 2021, 183: 158
[13]	Yang Z X, Shang Z C, Liu F, et al. Nanotechnology, 2021, 32(20): 205602
[14]	Wang S B, Zhang X W, Li S, et al. J Hazard Mater, 2017, 331: 235
[15]	Zou H W, Luo Z R, Yang X, et al. J Mater Sci, 2022, 57(24): 10912
[16]	Kalambate P K, Dhanjai, Huang Z M, et al. TrAC-Trends Anal Chem, 2019, 115: 147
[17]	Sun Z K, Kaliaguine S. Int J Chem React Eng, 2016, 14(3): 667
[18]	Singh R, Bhateria R. Environ Geochem Hlth, 2021, 43(7): 2459
[19]	Xiong Z K, Zheng H L, Hu Y D, et al. Sep Purif Technol, 2021, 277: 119053
[20]	Zhu M Y, Cheng Y K, Luo Q, et al. Mater Chem Front, 2021, 5(6): 2552
[21]	Liu F, Cheng Y, Tan J C, et al. Front Chem, 2021, 9: 668336
[22]	Mirzaei A, Kim J H, Kim H W, et al. Sensor Actuat B-Chem, 2018, 258: 270
[23]	Dong Z, Ren H, Hessel C M, et al. Adv Mater, 2014, 26(6): 905
[24]	Jin R C, Chen G, Wang Q. Mater Lett, 2011, 65(8): 1151
[25]	Xu H, Wang W Z, Zhou L. Cryst Growth Des, 2008, 8: 3486
[26]	Sun J X, Chen G, Wu J Z, et al. Appl Catal B: Environ, 2013, 132/133: 304
[27]	Tahri Y, Kožíšek Z, Gagnière E, et al. Cryst Growth Des, 2016, 16(10): 5689
[28]	Nikhila M P, Renuka N K. RSC Adv, 2016, 6(29): 24210
[29]	Guo R Y, Bao Y, Kang Q L, et al. Colloid Surface A, 2022, 633: 127931
[30]	Du C, Li P, Zhuang Z H, et al. Coord Chem Rev, 2022, 466: 214604
[31]	Park S K, Choi J H, Kang Y C. Chem Eng J, 2018, 354: 327
[32]	Malgras V, Tang J, Wang J, et al. Nano Nanotechnol, 2019, 19(7): 3673
[33]	Li Y J, Wang S M, Hao P, et al. Sensor Actuat B-Chem, 2018, 273: 751
[34]	Shao P H, Tian J Y, Shi W X, et al. J Mater Chem A, 2017, 5(1): 124
[35]	Xie L L, Jin Z, Dai Z D, et al. Carbon, 2020, 170: 100
[36]	Mao D, Wan J W, Wang J Y, et al. Adv Mater, 2019, 31(38): e1802874
[37]	Xu J, Yao X, Wei W Y, et al. Mater Res Bull, 2017, 87: 214
[38]	Salhabi E H M, Zhao J L, Wang J Y, et al. Angew Chem Int Ed Engl, 2019, 58(27): 9078
[39]	Chen Z Z, Li J, Zhang Z, et al. J Nanomater, 2021, 2021: 1
[40]	Chen P, Zhao Y L, Chen T X, et al. J Mater Sci Technol, 2019, 35(10): 2325
[41]	Zou H, Shang K. Mater Chem Front, 2021, 5(10): 3765
[42]	Wang L H, Chen Y Z, Wen X, et al. Sustain Energy Techn, 2022, 52: 102006
[43]	Ling Y, Gao Q, Ma C F, et al. RSC Adv, 2016, 6(28): 23360
[44]	Huertas-Perez J F, Arroyo-Manzanares N, Garcia-Campana A M, et al. Crit Rev Food Sci Nutr, 2017, 57(16): 3405
[45]	Liu H M, Jin P, Zhu F C, et al. TrAC-Trends Anal Chem, 2021, 134: 116132
[46]	Krasevec I, Prosen H. Molecules, 2018, 23(10): 1420
[47]	Qin J X, Su Z, Mao Y H, et al. Ecotoxicol Environ Saf, 2021, 208: 111729
[48]	Yavuz E, Tokalıoğlu Ş, Şahan H, et al. Microchim Acta, 2017, 184(4): 1191
[49]	Tong Y K, Guo B L, Zhang B Y, et al. Microchem J, 2020, 158: 105175
[50]	Vas G, Vekey K J. Mass Spectrom, 2004, 39(3): 233
[51]	Spietelun A, Marcinkowski L, Guardia M D L, et al. J Chromatogr A, 2013, 132: 1
[52]	Zhang W M, Li Q Q, Fang M, et al. Chinese Journal of Chromatography, 2022, 40(11): 1022
[52]	张文敏, 李青青, 方敏, 等. 色谱, 2022, 40(11): 1022
[53]	Hu M Z, Lian X H, Liu H, et al. Chinese Journal of Chromatography, 2017, 35(11): 1145
[53]	胡明珠, 连显会, 刘晗, 等. 色谱, 2017, 35(11): 1145
[54]	Jalili V, Barkhordari A, Ghiasvand A. Microchem J, 2020, 152: 104319
[55]	Peng S, Huang X Y, Huang Y Y, et al. J Sep Sci, 2022, 45(1): 282
[56]	Llompart M, Celeiro M, García-Jares C, et al. TrAC-Trends Anal Chem, 2019, 112: 1
[57]	Hu X R, Wang C H, Li J S, et al. ACS Appl Mater Interfaces, 2018, 10(17): 15051
[58]	Hu X R, Wang C H, Luo R, et al. Nanoscale, 2019, 11(6): 2805
[59]	Wang F B, Wang X M, Cui X L, et al. Sep Purif Technol, 2021, 276: 119367
[60]	Xu S R, Dong P L, Qin M, et al. Microchim Acta, 2021, 188(10): 337
[61]	Cheng Z, Wen Z F, Liu Z F, et al. Crit Rev Anal Chem, 2022, 197: 1
[62]	Ethurovic-Pejcev R D, Bursic V P, Zeremski T M. J AOAC Int, 2019, 102(1): 46
[63]	Capriotti A L, Cavaliere C, La Barbera G, et al. Chromatographia, 2019, 82(8): 1251
[64]	Ibarra I S, Rodriguez J A, Galán-Vidal C A, et al. J Chem, 2015, 2015: 1
[65]	Yu M, Wang L M, Hu L Q, et al. TrAC-Trends Anal Chem, 2019, 119: 115611
[66]	Hagarova I. J Anal Methods Chem, 2020, 2020: 8847565
[67]	Zhao Y M, Wang M, Zhang L Y, et al. Chinese Journal of Chromatography, 2019, 37(8): 831
[67]	赵雅梦, 王敏, 张凌怡, 等. 色谱, 2019, 37(8): 831
[68]	Bai H H, Fan C, Shen B Q, et al. Chinese Journal of Chromatography, 2015, 33(3): 221
[68]	白海红, 范超, 沈丙权, 等. 色谱, 2015, 33(3): 221
[69]	Jiang H L, Li N, Cui L, et al. TrAC-Trends Anal Chem, 2019, 120: 115632
[70]	Huang P F, Kou H X, Wang X M, et al. Talanta, 2021, 227: 122149
[71]	Wang X M, Yang J, Zhao J L, et al. Chinese Journal of Chromatography, 2022, 40(10): 910
[71]	王雪梅, 杨静, 赵佳丽, 等. 色谱, 2022, 40(10): 910
[72]	Zhou J B, She X K, Xing H Z, et al. J Sep Sci, 2016, 39(10): 1955
[73]	Gao M J, Deng L L, Kang X, et al. J Chromatogr A, 2020, 1629: 461476
[74]	Yang Y, Ma X W, Feng F, et al. Microchim Acta, 2016, 183(8): 2467
[75]	Liu T, Wu D. Int J Cosmetic Sci, 2012, 34: 489
[76]	Chisvert A, Cárdenas S, Lucena R. TrAC-Trends Anal Chem, 2019, 112: 226
[77]	Ghorbani M, Aghamohammadhassan M, Chamsaz M, et al. TrAC-Trends Anal Chem, 2019, 118: 793
[78]	Islas G, Ibarra I S, Hernandez P, et al. Int J Anal Chem, 2017, 2017: 8215271
[79]	Jayasinghe G D T M, Moreda-Piñeiro A. Separations, 2021, 8(7): 99
[80]	Scigalski P, Kosobucki P. Molecules, 2020, 25(21): 4869
[81]	Ghorbani M, Aghamohammadhassan M, Ghorbani H, et al. Microchem J, 2020, 158: 105250
[82]	Fu M Z, Xing H Z, Chen X F, et al. J Chromatogr A, 2014, 1369: 181
[83]	Jia Y Q, Zhao Y F, Zhao M, et al. J Chromatogr A, 2018, 1551: 21