Research progress in application of metal-organic framework-derived materials to sample pretreatment

doi:10.3724/SP.J.1123.2021.05017

Abstract

Abstract:

Sample pretreatment technology plays a vital role throughout the analysis of complex samples. Sample pretreatment can not only increase the concentration of trace targets in the sample, but also effectively eliminate interference from the sample matrix in instrumental analysis. Adsorbent materials are a key component of sample pretreatment technology. Therefore, the development of efficient and stable new adsorbent materials has acquired significance in research on pretreatment technology. Porous materials are advantageous for use in diverse applications, such as in adsorbents, when they possess controllable nanostructures, a tailored pore surface chemistry, and abundant porosity, and are inexpensive. Particularly in recent years, porous materials derived from metal-organic frameworks (MOFs) feature excellent properties, such as diverse morphology and structure, adjustable pore size, high specific surface area, good thermal stability, and chemical resistance. MOF-derived materials, when used as adsorbents for sample pretreatment, offer the following advantages: (1) The porous materials derived from MOFs typically possess a larger specific surface area than other porous materials. This characteristic is beneficial to improve the extraction capacity and extraction efficiency via an increase in the contact area between the materials and targets; (2) The microscopic porous structure of MOF-derived materials can be easily tuned (by controlling the temperature and time during pyrolysis, gas atmosphere, and heating rate), which is conducive to improve the selectivity of sample pretreatment methods; (3) The metal active sites can be evenly distributed. Owing to the ordered distribution of metal ions in the precursor MOFs and a good periodic framework structure, the metal active sites of the derivatives formed can still maintain a corresponding distance. These metal active sites will not form agglomerates and affect the extraction performance; conversely, other porous materials often require extremely complicated processes to achieve a uniform distribution; (4) Heteroatoms such as nitrogen and sulfur can be easily doped on the framework of MOF-derived porous materials. This doping enables the materials to induce additional interactions such as hydrogen bonding and π-π stacking for adsorbing target analytes. The excellent properties of MOF-derived materials make them promising for use in sample pretreatment. Novel sample pretreatment methods that use MOF-derived materials are constantly being developed. However, the use of MOF-derived materials is limited by the complex preparation process and high production cost of MOF precursors, along with difficulties in mass production. Further, the precise design or functionalization of MOF-derived materials according to the characteristics of targets is a new direction with immense challenges as well as application potential. This review summarizes the application of MOF-derived materials in sample pretreatment methods, including dispersive solid phase extraction (dSPE), magnetic solid phase extraction (MSPE), solid phase microextraction (SPME), stir bar sorptive extraction (SBSE), and dispersive micro solid phase extraction (DMSPE). The preparation methods, functional control, and enrichment efficiencies of various MOF-derived materials are also reviewed. Finally, the application prospects of MOF-derived materials in sample pretreatment are discussed to provide a clear outlook and reference for further related research.

Key words: metal-organic frameworks, derivative materials, pretreatment technique, review

CLC Number:

O658

ZHANG Wenmin, LI Qingqing, FANG Min, GAO Jia, CHEN Zongbao, ZHANG Lan. Research progress in application of metal-organic framework-derived materials to sample pretreatment[J]. Chinese Journal of Chromatography, 2021, 39(9): 941-949.

Figures/Tables 1

References

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Material	Precursor		Analyte		Method		Technique		Sample		Reference
MOF-C	ZIF-8		benzoylurea		dSPE		HPLC-UV		water and fruits		[17]
Cu@graphitic octahedron carbon cages	Cu₃(BTC)₂		fluoroquinolones		dSPE		UPLC-UV		water and food		[18]
Carboxylated carbon porous	ZIF-8		methamphetamine		dSPE		HPLC-UV		biological urine		[22]
ZIF-8-NC	ZIF-8		metal ions		dSPE		FAAS		tea		[24]
Zn/Co/C	ZIF-8/ZIF-67		metal ions		dSPE		FAAS		water		[25]
MNC	ZIF-67		phenylurea herbicides		MSPE		HPLC-UV		food		[29]
Ni/NiO@C	Ni-MOF		benzoylurea insecticides		MSPE		HPLC-UV		food		[30]
Fe₂O₃@C	MOF-235		benzoylurea insecticides		MSPE		HPLC-UV		tea		[31]
N-CNTCs	MOF-67		okadaic acid		MSPE		HPLC-MS/MS		seafood		[32]
Co@CNTs	ZIF-67		flurbiprofen and ketoprofen		MSPE		HPLC-UV		human serum		[33]
BMZIF-derived magnetic porous carbon	BMZIF		organochlorine pesticides		MSPE		GC/MS		water		[35]
Material		Precursor		Analyte		Method		Technique		Sample	Reference
Co/HPC		Co/ZIF-8		triazine herbicides		MSPE		HPLC-DAD		water and plants	[36]
MOF-5-C		MOF-5		carbamate		MSPE		HPLC-UV		fruits	[37]
C-Al-MOF		Al-MOF		PAHs		SPME		GC-MS		water and soil	[43]
Co-NPC		ZIF-67		organochlorine pesticides		SPME		GC/μECD		vegetables	[44]
HCNC		hollow-ZIF-8		PAHs		SPME		GC/MS		water	[45]
N-CNTCs		ZIF-67		PCBs		SPME		GC/MS		water	[46]
Co&thiourea@MIL-101-NH₂- derived NPC		Co&thiourea@ MIL-101-NH₂		BTEX		SPME		GC-MS		water	[47]
Mesoporous carbon-ZrO₂		Zr-MOF		BTEX		SPME		GC-FID		water	[55]
Double-shelled hollow ZnO/C		ZIF-8		BTEX and chlorophenols		SPME		GC-MS		water	[58]
MOF-74-C		MOF-74		odorous organic contaminants		SPME		GC-MS		water	[59]
Co@ZIF-67-C		ZIF-67		PAHs		SPME		HPLC-UV		water	[60]
Co-NPC		ZIF-67		fluorouracil and phenobarbital		SBSE		HPLC-UV		human serum and urine	[62]
MPC		MOF-67		estrogen		DMSPE		GC-MS		water	[63]

Material	Precursor		Analyte		Method		Technique		Sample		Reference
MOF-C	ZIF-8		benzoylurea		dSPE		HPLC-UV		water and fruits		[17]
Cu@graphitic octahedron carbon cages	Cu₃(BTC)₂		fluoroquinolones		dSPE		UPLC-UV		water and food		[18]
Carboxylated carbon porous	ZIF-8		methamphetamine		dSPE		HPLC-UV		biological urine		[22]
ZIF-8-NC	ZIF-8		metal ions		dSPE		FAAS		tea		[24]
Zn/Co/C	ZIF-8/ZIF-67		metal ions		dSPE		FAAS		water		[25]
MNC	ZIF-67		phenylurea herbicides		MSPE		HPLC-UV		food		[29]
Ni/NiO@C	Ni-MOF		benzoylurea insecticides		MSPE		HPLC-UV		food		[30]
Fe₂O₃@C	MOF-235		benzoylurea insecticides		MSPE		HPLC-UV		tea		[31]
N-CNTCs	MOF-67		okadaic acid		MSPE		HPLC-MS/MS		seafood		[32]
Co@CNTs	ZIF-67		flurbiprofen and ketoprofen		MSPE		HPLC-UV		human serum		[33]
BMZIF-derived magnetic porous carbon	BMZIF		organochlorine pesticides		MSPE		GC/MS		water		[35]
Material		Precursor		Analyte		Method		Technique		Sample	Reference
Co/HPC		Co/ZIF-8		triazine herbicides		MSPE		HPLC-DAD		water and plants	[36]
MOF-5-C		MOF-5		carbamate		MSPE		HPLC-UV		fruits	[37]
C-Al-MOF		Al-MOF		PAHs		SPME		GC-MS		water and soil	[43]
Co-NPC		ZIF-67		organochlorine pesticides		SPME		GC/μECD		vegetables	[44]
HCNC		hollow-ZIF-8		PAHs		SPME		GC/MS		water	[45]
N-CNTCs		ZIF-67		PCBs		SPME		GC/MS		water	[46]
Co&thiourea@MIL-101-NH₂- derived NPC		Co&thiourea@ MIL-101-NH₂		BTEX		SPME		GC-MS		water	[47]
Mesoporous carbon-ZrO₂		Zr-MOF		BTEX		SPME		GC-FID		water	[55]
Double-shelled hollow ZnO/C		ZIF-8		BTEX and chlorophenols		SPME		GC-MS		water	[58]
MOF-74-C		MOF-74		odorous organic contaminants		SPME		GC-MS		water	[59]
Co@ZIF-67-C		ZIF-67		PAHs		SPME		HPLC-UV		water	[60]
Co-NPC		ZIF-67		fluorouracil and phenobarbital		SBSE		HPLC-UV		human serum and urine	[62]
MPC		MOF-67		estrogen		DMSPE		GC-MS		water	[63]