• Review •
Hao Tian, Zimu Li, Changzheng Wang, Ping Xu, Shoufang Xu. Construction and Application of Molecularly Imprinted Fluorescence Sensor[J]. Progress in Chemistry, 2022, 34(3): 593-608.
Polymerization mechanism | Polymerization method | Advantage | Disadvantage | ref |
---|---|---|---|---|
Radical Polymerization | Bulk polymerization | Simple operation, high purity of MIPs | MIPS has an irregular shape, and larger sizes require grinding | |
Suspension polymerization | MIPs is spherical and can be made in one step | The effect of MIPs is poor, template is difficult to elute completely | ||
Precipitation polymerization | Simple operation process, easy control of particle size and morphology of polymer | Requires a large amount of solvent and long polymerization time | ||
Emulsion polymerization | Easily form monodisperse polymers | The whole process cycle is relatively long, and the molecular imprinting efficiency is low | ||
Reversible addition- fragmentation chain transfer (RAFT) | Wide range of monomers; no interference from organometallic catalysts; simple operation | Requires chain transfer agent and chain terminator; residual impurities are difficult to remove | ||
Atom transfer radical polymerization (ATRP) | Mild polymerization conditions; simple operation; high controllability | Large amount of catalyst; toxic initiator | ||
Sol-gel polymerization | Sol-gel method | Synthesis at room temperature, environmentally friendly reaction solvent | There are fewer choices of types of functional monomers and crosslinker that can be used | |
Self-polymerization of dopamine | Self-polymerization of dopamine method | With many non-covalent functional groups, easy to be further modified | Poor controllability |
Detection field | Fluorescent material | Sensor type | Target substance | Detection matrix | Linear range | Detection limit | ref |
---|---|---|---|---|---|---|---|
Metal ion | CDs, Au NCs | Double reference type | Pb2+, Ag+ | Real water | 50 ~ 900 nmol/L 0.2 ~ 12.5 nmol/L | 26 nmol/L 86 nmol/L | |
Amino modified CDs, carboxyl modified CDs | Double reference type | Cu2+, Fe3+ | Real water | 0.5 ~ 50 μmol/L 1 ~ 100 μmol/L | 130 nmol/L 340 nmol/L | ||
ZnSe QDs | Microfluidic paper chip | Cd2+, Pb2+ | Real water | 1 ~ 70 μg/L 1 ~ 60 μg/L | 0.245 μg/L 0.335 μg/L | ||
Blue and red CDs | Two-channel detection | Cr3+, Pb2+ | Real water | 0.1 ~ 6.0 μmol/L 0.1 ~ 5.0 μmol/L | 27 nmol/L 34 nmol/L | ||
Blue and red CDs | Two-channel detection | Cr6+, Cr3+ | Real water | 0.01 ~ 10.0 μmol/L 0.1 ~ 15.0 μmol/L | 3.8 nmol/L 46 nmol/L | ||
CdTe QDs | Microfluidic paper chip | Cu2+, Hg2+ | Real water | 0.11 ~ 58.0 μg/L 0.26 ~ 34.0 μg/L | 0.035 μg/L 0.056 μg/L | ||
CQDs | Single emission quenching | Cu2+ | Tap Water | 0.25 ~ 2 mg /L 3 ~ 10 mg /L | 2.86μmol/L | ||
Organic molecules | CQDs, CdTe QDs | Ratiometric type | Dopamine | Human serum | 0.2853~ 5 μmol/L | 0.2853μmol/L | |
3-(anthracen-9- ylmethyl)-1-vinyl-1H- imidazol-3-ium chloride | Single emission quenching | P-nitroaniline | Wastewater | 10-8 ~ 10 mol/L | 9 nmol/L | ||
ZnS QDs | Single emission quenching | Sparfloxacin | Biological serum | 0.05~ 2.0 μg/mL | 0.012 μg/mL | ||
Nitrogen-doped CDs | Single emission quenching | Aspirin | Human urine and saliva | 0.9~ 9.0 mg/L | 0.198 mg/L | ||
CQDs | Single emission quenching | Tetracycline | Real water | 1.0 ~ 60 μmol/L | 0.17 μmol/L | ||
Calcium fluoride CDs | Ratiometric type | 5-Hydroxymethyl- furfural | Honey | 0.1~ 6.0 μg/mL | 0.043 μg/mL | ||
CQDs, CdTe QDs | Ratiometric type | Sulfadiazine | Real water and milk | 0.25~ 20 μmol/L | 0.042 μmol/L | ||
Biomacromolecule | ATTO 647N | Signal amplification | Porcine serum albumin | Porcine serum | 0.25~ 5 nmol/L | 40 pmol/L | |
Cadmium telluride QDs | Single emission quenching | Myoglobin | Human serum | 7.39 ~ 291.3 pg/mL | 3.08 pg/mL | ||
Silanized CDs | Single emission quenching | Bovine hemoglobin | Bovine serum | 0.31~ 1.55μmol/L | 1.55μmol/L | ||
ZnS QDs | Single emission quenching | Lysozyme | Real biologic sample | 0.1 ~ 1μmol/L | 10.2 nmol/L | ||
CdTe QDs | Single emission quenching | Myoglobin | Human serum | 0.304 ~ 571 pg/mL | 0.045 pg/mL | ||
Green and red CdTe QDs | Ratiometric type | Bovine hemoglobin | Bovine urine | 0.050 ~ 3.0μmol/L | 9.6 nmol/L | ||
Tetra(4- carboxyphenyl) porphyrin | Signal amplification | Horseradish peroxidase | Urine | 10-4 ~ 10 mg/L | 0.042 μg/L | ||
Phycocyanin and CdTe QDs | Ratiometric type | Phycocyanin | Seawater | 0 ~ 1.8 μmol/L | 3.2 nmol/L |
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