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MS
Internaticmd
of Mass Spectrometry
Journal
FORENSIC APPLICATIONS
J.
253
48 (1983) 253-256 Printed in The Netherlands
and Ion Physics,
Elsevier Scientific Publishing Company, Amsterdam -
OF LC/MS
YINON
Department
of
Isotope
Weizmann
Research,
Institute
of
Science,
Rehovot,
Israel
ABSTRACT A high performance liquid chromatograph (HPLC) has been interfaced with a magnetic sector mass spectrometer using a connnercial direct liquid introduction (DLI) interface allowing about 1% of the solvent/sample effluent into the ion The LC/MS system has been used for the analysis of forensic mixtures source. including explosives and drugs.
INTRODUCTION In
many
which
applications
combines
good
tive
detection.
over
GC/MS in
for
The
explosive
sives
and
is
been
characteristics system
suitable
used
with
has
such
for
thermally
successfully
(refs.l,2)
specific
an analytical
analysis,
for
sensitive
and
has
and
involatile
has
and
required
and an
sensi-
advantage com-
separation
spectrometry
detection
is
specific
an analytical
mass
the
highly
specifications
as
while
method
method
technique
proven
itself
identification
of
as
explo-
(refs.7,3).
Several
LC/MS
techniques
(refs
analysis the
LC/MS
it
mixtures
a sensitive
forensic
separation
that
HPLC has
pounds.
of
of
of
magnetic
sector
analysis
of
been an
using
drugs
Paper
have Such
exp?osives
analysis ‘In this
systems ,4-8).
described
LC/MS
using
system
negative
ion
has
various already
chemical
interface been
ionization
coupling
applied
to
(ref.9)
and
the to
(refs.lO,ll).
we describe mass
results
spectrometer
standard
mixtures
obtained and
of
from
using
explosives
interfacing
the
combined
and
drugs.
an H.PLC with
LC/MS
system
for
a the
EXPERIMENTAL The- LC/MS The
mass
system
with
an
(Menlo
The
7125
Park, Eldex
Sample
column
is
a high-speed
an
Prograrrmer, Model
shown
spectrometer
strument Eldex
is
used
in
a home
Calif.)
was
OOZO-7381/83/0000-0000/$03.00
1. built
differential
Model
Injector
Fig.
Model LP-II and
a RP-8
4-inch
A-30-S
a Waters
radius
an Eldex
Valve,
(Milford,
sector
Model
CMT-II (Cotati,
Model
Lichrosorb
in-
HPLC consists
a Rheodyne Mass.)
column,
magnetic The
system.
pump,
Low Pressure
reversed/phase 0
90”
pumping
441
of
Gradient Calif.).
UV detector.
10 Urn particle
1983 Elsevier Scientific Publishing Company
254
Fig. 1.
Photograph
showing
size, 4.6 mm x 10 cm length was methanol:water
(50:50)
the K/MS
(Brownlee
system.
Labs.,
Santa
Clara,
at a flow rate of 1 mL/min.
Calif.).
Mobile
UV detector
phase
wavelength
was 214 nm. The LC/MS Direct
interface
Liquid
interface.
The
electrically made
glass
vacuum RESULTS
Interface
probe
slides
which
(Palo Alto,
is a variable
into a heated
CaTif.) split-type
desolvation
the ion source
(which
is at 1500 Volts)
(Corning
Works,
Corning,
enters
Glass
vaporized
in the desolvation
the ion source
of the ion source
of the vacuum
chamber,
where
by means
but which
by a tube
N-Y.). chamber,
it is ionized.
of a valve which
connects
chamber,
and
the
It is possible
is located
the ion source
with
on the
AND DISCUSSION
the operation Only
from
Hewlett-Packard
housing.
A series
of standard
explosive
of the LC/MS
two examples
mixture
LC/MS
interface
ceramic
mixture
the opening
the outside
Probe
of the jet are
droplets
solvent/sample to vary
LC/MS
insulated
of Macor
The
Insertion
is a commercial
and Figs.
are given
system here.
3 and 4 show
and drug mixtures and
was analyzed
its application
Fig. 2 shows
the respective
in forensic
the HPLC-UV
mass
spectra
trace
to demonstrate analysis. of a RDX+TNT
of the two components.
255 COLUiMN METHANOL. UV
: RP-
8 WATER(50:
WAVELENGTH:
501, 2 t4
TfME Fig.
2.
HPLC-UV
Fig.
3.
K/MS
Iml/mfn
“m
[
min
trace
mass
1 of
RDX+TNT
spectrum
of
mixture.
RDX (Source
temp.
17OOC).
m/r
Fig.
4.
LC/MS
mass
spectrum
of
TNT
(Source
temp.
17OY).
256 Fig. 5 shows spective
the HPLC-UV
mass
spectra
of a drug mixture
of the two components,
and Figs.
6 and 7 show the re-
acetaminophen
and barbital.
100
COLUMN: RF-8 METHANOL: WATER UV
trace
(50:
WAVELENGTH
214
501,
LC/
I ml/ tin 109
-I
nm
MS
METHANOL:
Leo
WATER(50:
ACETAMINOPHEN M+
% 2
501
60
a
160 Fig. 6.
0
2
I
TIME
Fig. 5.
3
LC/MS mass
of acetaminophen.
4
[m,n]
HPLC-UV
trace
120
As the source
was mostly
of EI and CI spectra.
open,
A better
sure seems to be necessary. on distance
of jet from source
These
parameters
have
the obtained
continuous
Also,
spectrum
mass
variation
spectra
and on source to be kept
mass
of barbital
spectra
are a combination
possibility
depend
strongly
and desolvation
constant
+&i----
180
160 m/z
140
LC/MS mass
Fig. 7.
tures.
spectrum
in order
of source
pres-
on jet length,
chamber to obtain
temperareproduc-
ibility. REFERENCES 1
J. Yinon and S. Zitrin, The Analysis of Explosives, Pergamon Press, Oxford, 1981, 322 pp. 2 1-S. Krull and M.J. Camp, American Laboratory, May 1980, 63-76. 3 J. Yinon, Mass Spectrometry Reviews, in press. 4 P. Arpino, M.A. Baldwin and F.W. McLafferty, Biom. Mass Spectrom., 1 (1974)eO-82 5 W.H. McFadden, H.L. Schwartz and S. Evans, 3. Chromatogr., 122 (1976) 389-396. 6 J.D. Henion, J. Chromatogr. Sci., 19 (1981) 57-64. 7 K.H. Schafer and K. Levsen, J. Ghromatogr., 206 {1981) 245-252. 8 T. Takeuchi, D. Ishii, A. Saito and T. Ohki, J. of HRC & CC, 5 (1982) 91-92. 9 C.E. Parker, R.D. Voyksner, Y. Tondeur, J.D. Henion, J.R. Hass and J. Yinon, J. Forensic Sci., in press. 10 J.D. Henion and G.A. Maylin, Biom. Mass Spectrom., 7 (1980) 115-121, 11 P-J. Arpino
and P.
Krien,
J. Chromatogr.
Sci.,
18 11980)
104.
of Mass Spectrometry
Journal
FORENSIC APPLICATIONS
J.
253
48 (1983) 253-256 Printed in The Netherlands
and Ion Physics,
Elsevier Scientific Publishing Company, Amsterdam -
OF LC/MS
YINON
Department
of
Isotope
Weizmann
Research,
Institute
of
Science,
Rehovot,
Israel
ABSTRACT A high performance liquid chromatograph (HPLC) has been interfaced with a magnetic sector mass spectrometer using a connnercial direct liquid introduction (DLI) interface allowing about 1% of the solvent/sample effluent into the ion The LC/MS system has been used for the analysis of forensic mixtures source. including explosives and drugs.
INTRODUCTION In
many
which
applications
combines
good
tive
detection.
over
GC/MS in
for
The
explosive
sives
and
is
been
characteristics system
suitable
used
with
has
such
for
thermally
successfully
(refs.l,2)
specific
an analytical
analysis,
for
sensitive
and
has
and
involatile
has
and
required
and an
sensi-
advantage com-
separation
spectrometry
detection
is
specific
an analytical
mass
the
highly
specifications
as
while
method
method
technique
proven
itself
identification
of
as
explo-
(refs.7,3).
Several
LC/MS
techniques
(refs
analysis the
LC/MS
it
mixtures
a sensitive
forensic
separation
that
HPLC has
pounds.
of
of
of
magnetic
sector
analysis
of
been an
using
drugs
Paper
have Such
exp?osives
analysis ‘In this
systems ,4-8).
described
LC/MS
using
system
negative
ion
has
various already
chemical
interface been
ionization
coupling
applied
to
(ref.9)
and
the to
(refs.lO,ll).
we describe mass
results
spectrometer
standard
mixtures
obtained and
of
from
using
explosives
interfacing
the
combined
and
drugs.
an H.PLC with
LC/MS
system
for
a the
EXPERIMENTAL The- LC/MS The
mass
system
with
an
(Menlo
The
7125
Park, Eldex
Sample
column
is
a high-speed
an
Prograrrmer, Model
shown
spectrometer
strument Eldex
is
used
in
a home
Calif.)
was
OOZO-7381/83/0000-0000/$03.00
1. built
differential
Model
Injector
Fig.
Model LP-II and
a RP-8
4-inch
A-30-S
a Waters
radius
an Eldex
Valve,
(Milford,
sector
Model
CMT-II (Cotati,
Model
Lichrosorb
in-
HPLC consists
a Rheodyne Mass.)
column,
magnetic The
system.
pump,
Low Pressure
reversed/phase 0
90”
pumping
441
of
Gradient Calif.).
UV detector.
10 Urn particle
1983 Elsevier Scientific Publishing Company
254
Fig. 1.
Photograph
showing
size, 4.6 mm x 10 cm length was methanol:water
(50:50)
the K/MS
(Brownlee
system.
Labs.,
Santa
Clara,
at a flow rate of 1 mL/min.
Calif.).
Mobile
UV detector
phase
wavelength
was 214 nm. The LC/MS Direct
interface
Liquid
interface.
The
electrically made
glass
vacuum RESULTS
Interface
probe
slides
which
(Palo Alto,
is a variable
into a heated
CaTif.) split-type
desolvation
the ion source
(which
is at 1500 Volts)
(Corning
Works,
Corning,
enters
Glass
vaporized
in the desolvation
the ion source
of the ion source
of the vacuum
chamber,
where
by means
but which
by a tube
N-Y.). chamber,
it is ionized.
of a valve which
connects
chamber,
and
the
It is possible
is located
the ion source
with
on the
AND DISCUSSION
the operation Only
from
Hewlett-Packard
housing.
A series
of standard
explosive
of the LC/MS
two examples
mixture
LC/MS
interface
ceramic
mixture
the opening
the outside
Probe
of the jet are
droplets
solvent/sample to vary
LC/MS
insulated
of Macor
The
Insertion
is a commercial
and Figs.
are given
system here.
3 and 4 show
and drug mixtures and
was analyzed
its application
Fig. 2 shows
the respective
in forensic
the HPLC-UV
mass
spectra
trace
to demonstrate analysis. of a RDX+TNT
of the two components.
255 COLUiMN METHANOL. UV
: RP-
8 WATER(50:
WAVELENGTH:
501, 2 t4
TfME Fig.
2.
HPLC-UV
Fig.
3.
K/MS
Iml/mfn
“m
[
min
trace
mass
1 of
RDX+TNT
spectrum
of
mixture.
RDX (Source
temp.
17OOC).
m/r
Fig.
4.
LC/MS
mass
spectrum
of
TNT
(Source
temp.
17OY).
256 Fig. 5 shows spective
the HPLC-UV
mass
spectra
of a drug mixture
of the two components,
and Figs.
6 and 7 show the re-
acetaminophen
and barbital.
100
COLUMN: RF-8 METHANOL: WATER UV
trace
(50:
WAVELENGTH
214
501,
LC/
I ml/ tin 109
-I
nm
MS
METHANOL:
Leo
WATER(50:
ACETAMINOPHEN M+
% 2
501
60
a
160 Fig. 6.
0
2
I
TIME
Fig. 5.
3
LC/MS mass
of acetaminophen.
4
[m,n]
HPLC-UV
trace
120
As the source
was mostly
of EI and CI spectra.
open,
A better
sure seems to be necessary. on distance
of jet from source
These
parameters
have
the obtained
continuous
Also,
spectrum
mass
variation
spectra
and on source to be kept
mass
of barbital
spectra
are a combination
possibility
depend
strongly
and desolvation
constant
+&i----
180
160 m/z
140
LC/MS mass
Fig. 7.
tures.
spectrum
in order
of source
pres-
on jet length,
chamber to obtain
temperareproduc-
ibility. REFERENCES 1
J. Yinon and S. Zitrin, The Analysis of Explosives, Pergamon Press, Oxford, 1981, 322 pp. 2 1-S. Krull and M.J. Camp, American Laboratory, May 1980, 63-76. 3 J. Yinon, Mass Spectrometry Reviews, in press. 4 P. Arpino, M.A. Baldwin and F.W. McLafferty, Biom. Mass Spectrom., 1 (1974)eO-82 5 W.H. McFadden, H.L. Schwartz and S. Evans, 3. Chromatogr., 122 (1976) 389-396. 6 J.D. Henion, J. Chromatogr. Sci., 19 (1981) 57-64. 7 K.H. Schafer and K. Levsen, J. Ghromatogr., 206 {1981) 245-252. 8 T. Takeuchi, D. Ishii, A. Saito and T. Ohki, J. of HRC & CC, 5 (1982) 91-92. 9 C.E. Parker, R.D. Voyksner, Y. Tondeur, J.D. Henion, J.R. Hass and J. Yinon, J. Forensic Sci., in press. 10 J.D. Henion and G.A. Maylin, Biom. Mass Spectrom., 7 (1980) 115-121, 11 P-J. Arpino
and P.
Krien,
J. Chromatogr.
Sci.,
18 11980)
104.