Table Info

Table 7.

DLLME and variants, reviews and food application papers

DLLME	Subject	Author(s)	Year	References
DLLME reviews	DLLME classification and terminology	Šandrejová et al.	2016	[153]
	DLLME with derivatization	Sajid	2018	[154]
	DLLME applications	Teshale, Taye	2019	[155]
	DLLME, overview of reviews	Dmitrienko et al.	2020	[156]
	DLLME, modes and solvents	Kokosa	2020	[157]
	Effervescence-assisted (EA)-DLLME	Lasarte-Aragonés et al.	2020	[158]
	Magnetic DESs in microextraction techniques	Grau et al.	2022	[159]
	Coacervation, DLLME strategies in hydrophilic media	Pacheco-Fernández et al.	2021	[160]
	DLLME, HLLME with DESs, review	Ramezani et al.	2022	[161]
	Challenges in DLLME: advanced strategies	Faraji	2024	[162]
	In situ dispersion formation/decomposition in situ-DLLME	Ahmadi et al.	2023	[163]
	SS-DLLME	Ullah, Tuzen	2023	[164]
	Dispersion techniques for DLLME	El-Deen et al.	2023	[165]
DLLME food applications: surfactant assisted (SA)-DLLME	SA-DLLME, HPLC/DAD, aromatic amines, barbequed meat	Barzegar et al.	2019	[166]
	SA-DLLME-SFO^c, GC/ECD, OCPs, cocoa	Mardani et al.	2021	[167]
	SA-DLLME, GC-FID, chlorpyrifos, green tea, GC-FID	Tian et al.	2022	[168]
DLLME food applications: vortex assisted (VA)-DLLME	MDES-VA-DLLME, QTOF-MS, PFAS, edible oils	Fan et al.	2021	[169]
	VA-DLLME with DES for sulfonamides in water	Mostafa et al.	2022	[170]
	DES-VA-DLLME-SFO, Vis, Fe, food, water	Zhang et al.	2022	[171]
	High density DES-VA-DLLME, HPLC/UV, herbicides, milk	Feng et al.	2022	[172]
	MDES-VA-DLLME, HPLC/DAD, fungicides, juice, vinegar	Wang et al.	2023	[173]
	DES, VA-DLLME, HPLC/DAD, flavonoids, vinegar	Bai et al.	2023	[174]
DLLME food applications: ultrasound-assisted (UA)-DLLME	UA-DLLME, LC-MS, chloramphenicol, honey	Campone et al.	2019	[175]
	DES-UA-DLLME-SFO, FAAS, NI, Co, food, water	Tavakoli et al.	2021	[176]
	DES-UA-DLLME-SFO, HPLC/DAD, antibiotics, food	Shirani et al.	2022	[177]
	UA-DLLME-SFO of propineb in water, food, water	Elik, Altunay	2023	[178]
DLLME food applications: air-assisted (AA)-DLLME	MDES-AA-DLLME, UV, melamine, milk products	Elik et al.	2023	[179]
DLLME food applications: SS-DLLME	DES-SS-DLLME, GC-FID, phenolic antioxidants, oils	Mogaddam et al.	2021	[180]
	Octanoic acid, SS-DLLME, flow-Vis, Co, food	Santos et al.	2022	[181]
	Salicylic acid, SS-DLLME, HPLC/UV, insecticides, honey	Wang et al.	2023	[182]
DLLME food applications: in situ-DLLME	In situ-DLLME, pH induced, antibiotics in water	Ma, Row	2021	[183]
	MIL-in situ-DLLME, HPLC/UV, sulfonamides in milk	Yao, Du	2020	[184]
	SUPRAS-in situ-DLLME, HPLC-FLD, PAHs, tea	Timofeeva et al.	2021	[185]
	DES-in situ-DLLME-SFO, LC-MS, antibiotic, honey	Nemati et al.	2021	[186]
	MDES-in situ-DLLME, HPLC/UV, triazine herbicides, rice	Piao et al.	2021	[187]

DLLME: dispersive liquid-liquid microextraction; DESs: deep eutectic solvents; HLLME: homogeneous liquid-liquid microextraction; DAD: diode array detector; SFO: solidified floating organic droplet; OCPs: organochlorine pesticides; GC: gas chromatography; ECD: electron capture detector; FID: flame ionization detector; QTOF: quadrupole time of flight; PFAS: polyfluorinated aliphatic solvents; Vis: visible; UV: ultraviolet; FAAS: flame atomic absorption spectroscopy; MIL: magnetic ionic liquid; SUPRAS: supramolecular solvent; FLD: fluorescence detector; PAHs: polycyclic aromatic hydrocarbons; MDES: magnetic deep eutectic solvent

Note. Adapted from “Green microextraction methodologies for sample preparations” by Kokosa JM, Przyjazny A. Green Anal Chem. 2022;3:100023 (https://www.sciencedirect.com/science/article/pii/S2772577422000222?via%3Dihub). CC BY 4.0 Deed.

Declarations

Author contributions

JMK: Conceptualization, Investigation, Visualization, Writing—original draft, Writing—review & editing.

Conflicts of interest

The author declares that he has no conflicts of interest.

Ethical approval

Not applicable.

Consent to participate

Not applicable.

Consent to publication

Not applicable.

Availability of data and materials

Not applicable.

Funding

Not applicable.

Copyright

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