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Use of a Robotic Solid Phase Extraction Clean-up of
QuEChERS Extracts to Give Improved Matrix Removal
for Pesticide Residue Analyses by GC-MS/MS and
LC-MS/MS.
Bruce Morris*, Richard Schriner*, Rick Youngblood† and Kim Gamble†
*RJ Hill Laboratories, Hamilton, New Zealand. †ITSP Solutions Inc., Hartwell, GA, U.S.A.
www.itspsolutions.com
www.itspsolutions.com
www.itspsolutions.com
Introduction
Why did we look at a robotic column SPE alternative to commonly used
dispersive SPE?
In our lab, QuEChERS for LC-MS/MS was successful, but less so for GC.
dSPE gave extracts that were poor for GC, with the samples we wanted to
analyse.
Bench cartridge SPE gave better clean-up, but seemed impractical for 100s
of samples per day.
With some experience in the use of CTC autosamplers, it seemed a robotic
method could be the answer.
ITSP SPE cartridges became available for CTCs, and we started a
collaboration developing these for QuEChERS.
www.itspsolutions.com
Robotic SPE clean-up Cartridges.
A miniaturised SPE cartridge invented by ITSP Solutions.
Stationary phase mixtures co-developed and trialled for QuEChERS at Hill Labs.
30 – 45mg of stationary phase, depending on mixture.
Cap/septum
Stationary phase bed
3.5
cm
Needle guide
www.itspsolutions.com
Robotic SPE clean-up - CTC autosampler
Robotized on a CTC autosampler
Hence ITSP “Instrument Top Sample Prep”, although it can also be done stand-alone on a bench top.
Well-plate dimensions, although 2-mL vials used rather than wells.
Raw sample
extracts Cartridge pre-
rinse tray
Load and
elute tray
Glass syringe
www.itspsolutions.com
Robotic SPE clean-up - Load and Elute tray
Developed specifically for QuEChERS-ITSP.
Samples eluted into 2-mL vials in a 54-well tray, allowing volume for LC-buffer addition.
Tray cover aligns cartridges and allows them to be removed from vials after elution, for instrument injection
www.itspsolutions.com
ITSP-QuEChERS Procedure
QuEChERS extraction (20g for fresh fruit)
LC-MS/MS GC-MS/MS
LC-ITSP
cartridge
Aliquot taken off into 2-mL vial,
ISTD added
Analytes eluted
Extract loaded
Diluted in aqueous buffer for
LC-MS/MS analysis.
GC-ITSP
cartridge
Aliquot taken off into 2-mL vial,
ISTD added
Analyte protectants added for
GC-MS/MS injection.
Ta
ke
s p
lace
on
Lo
ad
an
d E
lute
tra
y
Extract loaded
Analytes eluted
www.itspsolutions.com
Cartridge Development
LC-MS/MS cartridges.
The aim was to remove non-polar extract matrix (oils/waxes).
Drop out of solution when diluted in aqueous buffer for injection.
Are retained on the LC column which becomes fouled.
Cause matrix suppression in high organic end of chromatogram, or in the next injection.
Polar sugars/acids washed out at the start of the LC gradient, are not such a big problem.
GC-MS/MS cartridges.
Wanted to remove extracted sugars, fatty acids, sterols and pigments.
Foul the inlet liner/pre-column, creating active sites.
Cause interferences or suppression in the chromatogram.
GC can cope with some higher MW oils/waxes, especially with backflushing.
www.itspsolutions.com
LC-MS/MS Cartridge Sorbent Trials.
Various cartridge stationary phase mixtures were trialled with Avocado extract (oily).
5g fruit/20mL acetonitrile, 150µL of extract loaded onto cartridges (slightly overloaded), eluted with 150µL of acetonitrile.
MgSO4/PSA/C-18/
CarbonX 45mg
Z-Sep/C-18/
CarbonX 30mg Z-Sep+ 30mg Z-Sep 10mg
Z-Sep/HLB/
CarbonX 20mg
Raw extract
PSA/C-18 /CarbonX
Z-Sep/C-18 /CarbonX
Z-Sep+ Z-Sep Z-Sep/HLB/ CarbonX
0.41 0.23 0.15 0.07 0.18 0.20
Dry weight
Recovered (mg)
Best oil removal, but
lose many pesticides
2nd best oil removal, but
better pesticide recoveries
www.itspsolutions.com
Recoveries off Trial Cartridges
Recovery of Triazoles (acetonitrile elution, solvent-only
standards)
0
10
20
30
40
50
60
70
80
90
100
PSA/C18
/Cx
ZSep/C
18/C
x
Z-Sep
+
Z-Sep
HLB
/ZSep
/Cx
cartridge packing
% r
ec
ov
ery
Azaconazole
Cyproconazole
Difenoconazole
Epoxyconazole
Flusilazole
Flutriafol
Hexaconazole
Metconazole
Myclobutanil
Paclobutrazole
Penconazole
Propiconazole
Tebuconazole
Tetraconazole
Triadimefon
Triadimenol
Uniconazole
Hexaconazole -highly retained
Z-S
ep+
Tetraconazole -lesser retention
Fenhexamid
pKa=2.3
Pesticide spike on Avocado extract.
▪ For Z-Sep+, 68 out of 266 pesticides lost
(< 70% recovery).
▪ Z-Sep/C-18: 40 analytes < 70% recovery.
▪ As show by 17 triazole fungicide recoveries.
www.itspsolutions.com
Z-Sep/C-18 ITSP : Effect of Buffer Elution.
LC-ITSP: Triazole
Recoveries (Lemon).
Cypro
conazole
Cypro
conazole
Flu
tria
fol
Flu
tria
fol
Hexaconazole
Hexaconazole
0
20
40
60
80
100
acetonitrile
elution
buffer
elution
% r
eco
very
Z-Sep/C-18/Cx was chosen as the best compromise between retention of oils and recovery of analytes.
However 40 compounds were still “lost”, so we tried elution with formate buffer.
This improved recoveries of e.g. triazole fungicides, macrocyclic lactones, fenhexamid.
However, buffer can push some matrix oils off, so have to be careful with elution volumes.
LC-ITSP: Macrocyclic Lactone
Recoveries (Lemon)
Em
am
ectin
B1a
Milb
em
ectin
Spin
eto
ram
Spin
osad
Abam
ectin
Abam
ectin
Em
am
ectin
B1a
Milb
em
ectin
Spin
eto
ram
Spin
osad
0
20
40
60
80
100
acetonitrile elution buffer elution
% r
eco
very
Fenhexamid
(anilide fungicide)
Phenolic –OH
interacting with
Z-Sep?
LC-ITSP: Fenhexamid
Recovery (Lemon)
0
20
40
60
80
100
acetonitrile
elution
buffer elution
% r
eco
very
www.itspsolutions.com
Spike recoveries - LC-ITSP compared with Z-Sep/C-18 dSPE
(buffer elution, solvent only standards)
0
20
40
60
80
100
120
0.00 2.00 4.00 6.00 8.00 10.00 12.00 14.00 16.00
retention time (min)
% r
ec
ov
ery
LC-ITSP
dSPE
Z-Sep/C-18 : dSPE vs. LC-ITSP - Avocado
LC-ITSP with buffer elution, only 4 out of 272 analytes have < 50% recovery.
e.g. Pymetrozine with poor extraction recovery. Solutions are clear.
Pymetrozine
Halfenprox
Flumethrin
Drop-out zone
dSPE, with buffer added, significant amounts of matrix oils are pushed off, giving cloudy solutions, resulting in drop-out of non-polar analytes.
Out of 272 analytes, 19 with retention times > 12 minutes (logPow≳ 5) have < 50% recovery. dS
PE
www.itspsolutions.com
LC-ITSP Citrus Percent Spike Recoveries vs. Percent Standard Deviation
(solvent-only standards)
0
10
20
30
40
50
60
70
80
0 20 40 60 80 100 120 140 160 180 200
% spike recovery
% s
tan
da
rd d
ev
iati
on
LC-ITSP spike recoveries for Citrus.
282 Pesticides (incl. metabolites/homologues) analysed by LC-MS/MS, shown in the plot below.
DDAC
Sulfentrazone
Thiabendazole
Anilazine
Forchlorfenuron
16 falling outside 70-120% recovery and 40% standard deviation (N = 10).
Low recoveries - during extraction, and/or some retention on Z-Sep/C-18/CarbonX, however highly reproducible with ITSP (e.g. Anilazine, Forchlorfenuron, Thiabendazole).
High recoveries (e.g. DDAC, Sulfentrazone), due to losses in solvent-only calibration standards.
Carbendazim 77%, 5% SD
www.itspsolutions.com
Cartridge Development
LC-MS/MS cartridges.
The aim was to remove non-polar extract matrix (oils/waxes).
Drop out of solution when diluted in aqueous buffer for injection.
Are retained on the LC column which becomes fouled.
Cause matrix suppression in high organic end of chromatogram, or in the next injection.
Polar sugars/acids washed out at the start of the LC gradient, are not such a big problem.
GC-MS/MS cartridges.
Wanted to remove extracted chlorophyll/pigments, sugars, fatty acids, sterols, HCs.
Foul the inlet liner/pre-column, creating active sites.
Cause interferences or suppression in the chromatogram.
GC can cope with some higher MW oils/waxes, especially with backflushing.
www.itspsolutions.com
GC-ITSP - Chorophyll removal
GC-ITSP stationary phase mixture uses the same sorbents as standard QuEChERS dSPE.
PSA/C-18/MgSO4 with CarbonX for chorophyll removal.
Spinach Extract
Raw extract
GC-ITSP
cartridge
dSPE -contents
of GC-ITSP
cartridge used
Extract after
dSPE
Extract after
GC-ITSP
Chlorophyll retention
seen on top of bed
CarbonX appears to be more effective in ITSP format than in dSPE.
www.itspsolutions.com
Recovery of Planar Aromatics off ITSP
GC-ITSP Spike Recoveries of
Planar Pesticides (Persimmon)
0
20
40
60
80
100
120
chor
othalo
nil
delta
met
hrin
hexa
chloro
benz
ene
cypr
odinil
coum
aphos
% r
ec
ov
ery
Using CarbonX, recovery of planar aromatic pesticides has been acceptable, without toluene eluent.
LC-ITSP Spike Recoveries of
Planar Pesticides (Persimmon)
0
20
40
60
80
100
thiabe
ndaz
ole
delta
met
hrin
cypr
odinil
carb
endaz
im
coum
aphos
% r
eco
very
Chlorothalonil
Hexachlorobenzene
Cyprodinil
Carbendazim
Coumaphos
www.itspsolutions.com
10g fruit/20mL acetonitrile, GC-ITSP compared with PSA/C-18 dSPE.
Full-scan GC-MS chromatograms show improved removal of oils/tocopherols/sterols compared with dSPE (same sorbent mixture and loading).
6.00 7.00 8.00 9.00 10.00 11.00 12.00 13.00 14.00 15.00 16.00 17.00
0
2000000
4000000
6000000
8000000
1e+07
1.2e+07
1.4e+07
1.6e+07
1.8e+07
Time-->
Abundance
TIC: BB RAW.D
TIC: BB DSPE.D (*)
TIC: BB ITSPB.D (*)
TIC: BB LCA2.D (*)
Sit
ost
ero
l C
am
pest
ero
l
Tocophero
ls
Squale
ne
Eic
osa
noic
acid
(C
20)
Feru
lic a
cid
Quin
ic a
cid
All
ose
2-m
eth
oxy-5
-vin
ylp
henol
Cate
chol
Z-Sep/C-18 ITSP
PSA/C-18 ITSP
PSA/C-18 dSPE
Raw extract
GC-ITSP clean-up of Blueberry extract.
6.00 7.00 8.00 9.00 10.00 11.00 12.00 13.00 14.00 15.00 16.00 17.00
0
2000000
4000000
6000000
8000000
1e+07
1.2e+07
1.4e+07
1.6e+07
1.8e+07
Time-->
Abundance
TIC: BB RAW.D
TIC: BB DSPE.D (*)
TIC: BB ITSPB.D (*)
TIC: BB LCA2.D (*)
Sit
ost
ero
l C
am
pest
ero
l
Tocophero
ls
Squale
ne
Eic
osa
noic
acid
(C
20)
Feru
lic a
cid
Quin
ic a
cid
All
ose
2-m
eth
oxy-5
-vin
ylp
henol
Cate
chol
Z-Sep/C-18 ITSP
PSA/C-18 ITSP
PSA/C-18 dSPE
Raw extract
10g fruit/20mL acetonitrile, GC-ITSP compared with PSA/C-18 dSPE.
Full-scan GC-MS chromatograms show improved removal of oils/tocopherols/sterols compared with dSPE (same sorbent mixture and loading).
contamination
www.itspsolutions.com
GC-ITSP Citrus Percent Spike Recoveries vs. Percent Standard Deviations
(solvent-only standards)
0.0
10.0
20.0
30.0
40.0
50.0
60.0
70.0
80.0
0 20 40 60 80 100 120 140 160
% spike recovery
% s
tan
da
rd d
ev
iati
on
GC-ITSP spike recoveries for Citrus.
228 Pesticides analysed by GC-MS/MS, in plot below.
Fenpropimorph
Imazalil
Etridiazole Naled
10 falling outside 70-120% recovery and 40% standard deviation (N = 10).
Those with some retention on the cartridge (e.g. imazalil), show highly reproducible recoveries.
Poor reproducibility is due to variable breakdown or losses (e.g. naled, etridiazole).
www.itspsolutions.com
Summary
Robotic clean-up means high-throughput, low labor input, and high reproducibility.
Column SPE format means improved clean-up compared with dispersive SPE.
Desirable for more difficult samples, reducing instrument fouling (esp. for GC).
Can generally use solvent-only calibration standards, due to fewer matrix effects.
Reduces MS/MS interferences and oil drop-out in-vial (for LC).
Avoids dSPE stationary phase transfer into analysis vials (ends up in LC injector or in-
line filter).
Careful choice of stationary phase mixtures and elution solvents allows an extended
suite of pesticides to be recovered, while retaining effective matrix removal.
Chlorophyll, pigments, sugars, sterols, oils/fatty acid removal, keeps columns and
inlets clean!
SPE integrated into the instrument cycle and takes place between injections.
Uses idle autosampler time (takes ~7 minutes per clean-up).
Gives freshly cleaned up extracts, with reduced potential for analyte breakdown,
especially for LC with the addition of aqueous buffer.
Has proven to be reliable and robust in a commercial laboratory environment.
www.itspsolutions.com
References
AOAC Official Method 2007.01, Pesticide Residues in Foods by Acetonitrile Extraction and Partitioning with Magnesium Sulfate.
EN15662:2008, Foods of plant origin – Determination of pesticide residues using GC-MS and/or LC-MS/MS following acetonitrile extraction/partitioning and cleanup by dispersive SPE – QuEChERS-method.
Increased Removal of Fat and Pigment from Avocado Extracts Prior to GC-MS Analysis of Pesticide and Metabolite Residues. Katherine K. Stenerson and Jennifer Claus, Reporter US Volume 31.2.
EURL-FV(2013-M11). Determination of pesticide residues in avocado and almond by liquid and gas chromatography tandem mass spectrometry (http://www.eurl-pesticides.eu/userfiles/
file/EURL-FV%20(2013-M11)Determination%20of%20pesticide%20residues%20in%20high% 20oil%20vegetal%20commodities.pdf).
Novel Porous Carbon Sorbent Materials for Use in Sample Preparation. Dwight Stoll, David C. Harmes, Jon Thompson, Doug Fryer, Conor Smith, and Bill Barber. EAS poster presentation, 2012. (http://uniscicorp.com/wp-content/uploads/2012/12/2012-Quechers-EAS-Presentation-v61.pdf)
www.itspsolutions.com