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Comparison of field desorption and Fast Atom Bombardment mass spectrometry
International
Journal of Mass Spectrometry
and Ioon Physics,
46 (1983)
379
379-382
Elsetier Scientific Publishing Company, Amsterdam - Printed in The Netherlands
OF
COkPARISON
FIELD
AND
DESORPTION
FAST
BOMBARDMENT
ATOM
MASS
SPECTkOMETRY
J.
uer
van
Greef
and
Institutes
CIVO
ten
M.C.
TNO,
Noever
de
Box
360,
P.O.
Brauw 3700
AJ
Zeist
(The
Netherianas)
A6 STRACT Investigations carried out to compare fast atom bombardment in positive and negative ion mode - combined w%th low or high resolution - with field desorption snowed that the former technique is more easily feasible. It proauces more fragment ions as compared with field aesorption, which is a but a drawback in favouraole aspect as regards structure elucidation, the difference in information obtained with mixture analysis. Considering tne two tecnniques, it seems more practicable to use a combination than to apply only one of them.
INTRODUCTIOh Field 'soft
desorption
the
analysis
for
reasons
of
for
pared
to
sults
than
the
largely to
number
it
a
are
also
a
well
known
successfully Fast
been
(ref. of
FABMS
in
atom
proved
FDMS
in
analytical
this
bom-
suitable
the
near
of
the com-
better
that
future
re-
FABMS (ref.
of with
obtained
will Tn
2).
applicability
results
is
as
produce
to
the
One
simplicity
its
suggested
into
technique
publications. is
therefore
insight
l),
seems
FABMS
was
better
several
FABIVIS,
of
cases
supersede
obtain
techniques
increasing
and
used
compounds. has
recently
some
being
is
compounds.
popularity
FDMS
is
only
In
(FDMS)
polar (FABMS)
these
an
FDMS.
probably
and
of
introduced
subject
order
spectrometry
analysis
the
that
non-volatile
of
mass
Although the
technique
ionization'
bardment
spectrometry
mass
FDMS oath
discussed.
METHODS FD
and
Finnigan
System
Spectra and
FAB MAT
data
spectra 212 SS
mass 100
were
obtained
with
spectrometer, and
SS
200
a
Varian
MAT
were
used
for
731 A
respectively. data
acquisition
processing_
0020-7381/83/0000-0000/$03.00
0
and
Finnigan
1983 ElsevierScientific J?ublishingCompany
a
380
KESltLTS Identification
anu
quailtit?itiOri
of
1
solution
A FAB
in
mode
tne
positive
(-FD,-FAb)(ref.
were
obtaineii
ana
Na2F
+
for
ions
peaks
+
87
-FAn
+FAB
%
ground isotope
These
With it
was
hampered
by
a
the and
signals
currents
for
Na+
this
about
of
peaks
of
only
dominating
1:4('0
6=19.8
%,
pg.
The
glycerol
the
I0 B
back-
containing
87
197
(BF4-L
TNa(BF4121-,
provide
much
-FD
Moreover
can
and
250
the
and
and
glycerol
('"BF4-)
m/z
not
of
-FD
and two
.
-FAB
anionic
Na+,
only
aDout
and
does
quantitation
that
86
BF41-,
salt.
the
witn
of
[Na2(BFG)3]-
+FAB,
of +
NazBFq]
limit
183)
+FD
of
signals
peaKs:
307
whereas
to
found
ion
+FC
m/z
ratio
that
show
respect
at
+
and
information
salt.
and
negative
spectrum
tollowing
identification
provide
FD
lasting
strong
simple
[Glycerol
information,
the
ion
sy
the
+
-FD
91
the
results
teristic
High
detection
89,
179
[Glycerol-H+NaBF4]-
A
besides
peaks,
201
short
in
a a
71,
[NaBF5]-,
and
[Glycerol
contains
129
and
ions.
with
with
59,
analyzed
+FAB)
weak
+
ions.
in
(m/z
was
(+FD,
j+,
and
)
salt
resulted
obtained
spectrum
3)
iM+Naj
a NaBF4
observed.
( l'8Fq-)
-5=8".2
for
Only
Na21SFL:~+
is
m/z
3).
iNa2BF4
tilycerol
ot
moae
witn
Na2F+,
of
PI-'
ion
the
were
Experiments
iz
119
are
both
be
uSed
ppb
at
of
-FAB the
levels
since
background
and
part
at
useful
+FA&
cationic
BF4-
charac-
very
(ref.
+/-FAB
these
are
low
con-
centrations.
Detection
of
F DNS
an
organoarsenic
has
(CH3)++CH2COO-) (ref.
Hecent marine
weak
very
LM+H]'
ions
of
other
spectrum
of
pure a
contains
few
However,
no
significant
(0.1-l
in
more
provides
isolated
oe
products
and
tions
can
were
detected.
fragment
too
This
products
as
cases
was
due
no to
The spectrum,
compared
to
or the
'FAB but
the
+FD
information.
obtained
since
from
isolated some
+FD
structural be
plaice
fractions. the
peaks
could
low.
in
isolated
more
spectra marine
that
resembles
therefore
from Vg)
showed
the
from
fractions
on 5)
arsenobetaine
spectrum
tities
(ref.
arsenabetaine
isolated
measurements
+FD
identify
to
fractions
products
presence
it
used in
4).
various
COInpOUnd
been
the
from available
the
fracquan-
381
problem
if
situated hign
in
the
protonated The
at
m/z
using
to
record
in
found,
of LM+H]*
i.e.
doublet
arising analyzed
obtained
at
for
the
this
as
of
of
fractions
which
this
The
fraction
problem, analyzer around
[2Fi+H]+
isolated
Figure
in
1.
the
peak
high gave
of
FD
crab were
peaks
an
unresolved
Various
resolution poor
from
Two
and
background.
and
is
reference.
a
glycerol
interest
region
arsenobetaine
method
a
multichannel mass
179.0053.
stiown
peak
from by
m/z
especially
of
circumvent
counting
\nias used
are
is
region
relevant
analysis
way
the To
ion
the
ion
the
tnis
-
region. an
185.1OiS
results
obtained
were
FAE
molecular
glycerol
case
this mass
I ow
used
was
i 11
as
resolution
system
be
-
background
glycerol
witn
interference
The
fractions
data
could
even
results.
.. *s
c5 “12 02 179.M53
‘.
.._
i .,. . .: ..
-_
-:..
Figure
1:
High from
Analysis
of
Interesting study tration given
of by
using
isomeric
fumaric
acid acid).
of
was in
acids of
(trans-butenedioic +FD
an
fraction
isolated
analyzer.
obtained
behaviour
Upon
a
carboxylic
carboxylic
differences
(cis-butenedioic
analysis
a multichannel
information
unsaturated
on
FAB
unsaturated
‘.. I..
.
resolution crab
I_
__ .. z,:;:
‘.,
M+*
acids with
(ref. cis
FD 6).
and acid)
peak
for
and A
good
trans and
FAD
in illus-
isomers maleic
fumaric
a
acid
is acid
382 and
LM+Hj+
an
reflects
the
explained
by
carboxylic This
the
aifference
and
acid
upon
simi
mode fumaric
Iat-
acid
at
results is
strong
high
be
bound
is
also
(M+Hj+ fUmariC
is
can
spectrum
of
fumaric
be
the in
twc
gives negative
-FAB
acid
no
its
+FAB-spectrum.
-f for
the
the
than
both
observed
hardly
In but
better
shown
acid
obtainer,
considerably
which
between
peak
concentrations.
are
result
This
acid
sigion
spectrum l
+FAB
the are
even
found.
isomer. isomers
wnereas
+FAB,
peaks,
can
cis two
A
was maleic
of
proton
the
the
experiments.
nificant
a
in
between
-FAB
maleic
that
groups
acid
affinity
proton fact
acid
maleic
for
peak
higher
indication
of
M
of In
.
ions
found.
CONCLUSIONS The
application
easier
is
and
presence FD
not
more
a
+FAB
analysis.
observed
with
in merits
an
by
This
which
can
background the
Moreover,
selective
effected
fumaric
by
are
acid,
true
in be
used
as
with by
not
references.
FD, a
of
to
2 3 4 5 6
FAB is
a in
components heating.
In
affinity, occur
as
with
high
applied
at
compounds. it
may
be
the
field
of
and
defects.
observed polar
that non-volatile
FD
and
FAB
-
as
compounds
REFERENCES 1
be
disadvantage
proton
expected
might
which
controlled low
the
compounds.
with but
for is
but
other
mode
also
respect
resorption
FD
caused
holds
ion
this
of
compared
determination
negative
prob’tems,
presence
structure
be
and
advantage
as
problems
weight
conclusion
present own
can
experiments
molecular
analysis.
fragmentions in
mixture
FD
severe
strongly
advantage
mixture
positive
peaks
by
ion
in
while
solvent
more
generates
in
the hampereti
influenced clear
than
work,
of
is
FAB
faster
resolution
hign
In
of
U. J. Surman and J.C. Vickerman, J. Chem. Sot. Chem. Commun., (1981) 324 M. Barber, B.S. Bordoli, R.D. Sedgwick and A.N. Tyler, ibid (lYB1) 325. Bradley, G. Williams, C. Bojesen, S. Santikarn and D.H. L.C.E. Taylor, 3. Am. Ch-em. Sac. 103 (1981) 5700. 3. van der Greef, M-C.. Ten Noever de Brauw, J.J. Zwinselman and N.M.M. Nibbering, Biomed, Mass Spectrom., in press. J.B. Luten, G. Riekwel-Booy and A. Rauchbaar, in preparation. J_ van der Greef and M.C. Ten J.B. Luten, G, Riekwel-3ooy, Noever de Brauw, in preparation. J.W. Dallinga, N.M.M. Nibbering, J. van der Greef and M-C. Ten Noever de Brauw, in preparation.
have
their
Journal of Mass Spectrometry
and Ioon Physics,
46 (1983)
379
379-382
Elsetier Scientific Publishing Company, Amsterdam - Printed in The Netherlands
OF
COkPARISON
FIELD
AND
DESORPTION
FAST
BOMBARDMENT
ATOM
MASS
SPECTkOMETRY
J.
uer
van
Greef
and
Institutes
CIVO
ten
M.C.
TNO,
Noever
de
Box
360,
P.O.
Brauw 3700
AJ
Zeist
(The
Netherianas)
A6 STRACT Investigations carried out to compare fast atom bombardment in positive and negative ion mode - combined w%th low or high resolution - with field desorption snowed that the former technique is more easily feasible. It proauces more fragment ions as compared with field aesorption, which is a but a drawback in favouraole aspect as regards structure elucidation, the difference in information obtained with mixture analysis. Considering tne two tecnniques, it seems more practicable to use a combination than to apply only one of them.
INTRODUCTIOh Field 'soft
desorption
the
analysis
for
reasons
of
for
pared
to
sults
than
the
largely to
number
it
a
are
also
a
well
known
successfully Fast
been
(ref. of
FABMS
in
atom
proved
FDMS
in
analytical
this
bom-
suitable
the
near
of
the com-
better
that
future
re-
FABMS (ref.
of with
obtained
will Tn
2).
applicability
results
is
as
produce
to
the
One
simplicity
its
suggested
into
technique
publications. is
therefore
insight
l),
seems
FABMS
was
better
several
FABIVIS,
of
cases
supersede
obtain
techniques
increasing
and
used
compounds. has
recently
some
being
is
compounds.
popularity
FDMS
is
only
In
(FDMS)
polar (FABMS)
these
an
FDMS.
probably
and
of
introduced
subject
order
spectrometry
analysis
the
that
non-volatile
of
mass
Although the
technique
ionization'
bardment
spectrometry
mass
FDMS oath
discussed.
METHODS FD
and
Finnigan
System
Spectra and
FAB MAT
data
spectra 212 SS
mass 100
were
obtained
with
spectrometer, and
SS
200
a
Varian
MAT
were
used
for
731 A
respectively. data
acquisition
processing_
0020-7381/83/0000-0000/$03.00
0
and
Finnigan
1983 ElsevierScientific J?ublishingCompany
a
380
KESltLTS Identification
anu
quailtit?itiOri
of
1
solution
A FAB
in
mode
tne
positive
(-FD,-FAb)(ref.
were
obtaineii
ana
Na2F
+
for
ions
peaks
+
87
-FAn
+FAB
%
ground isotope
These
With it
was
hampered
by
a
the and
signals
currents
for
Na+
this
about
of
peaks
of
only
dominating
1:4('0
6=19.8
%,
pg.
The
glycerol
the
I0 B
back-
containing
87
197
(BF4-L
TNa(BF4121-,
provide
much
-FD
Moreover
can
and
250
the
and
and
glycerol
('"BF4-)
m/z
not
of
-FD
and two
.
-FAB
anionic
Na+,
only
aDout
and
does
quantitation
that
86
BF41-,
salt.
the
witn
of
[Na2(BFG)3]-
+FAB,
of +
NazBFq]
limit
183)
+FD
of
signals
peaKs:
307
whereas
to
found
ion
+FC
m/z
ratio
that
show
respect
at
+
and
information
salt.
and
negative
spectrum
tollowing
identification
provide
FD
lasting
strong
simple
[Glycerol
information,
the
ion
sy
the
+
-FD
91
the
results
teristic
High
detection
89,
179
[Glycerol-H+NaBF4]-
A
besides
peaks,
201
short
in
a a
71,
[NaBF5]-,
and
[Glycerol
contains
129
and
ions.
with
with
59,
analyzed
+FAB)
weak
+
ions.
in
(m/z
was
(+FD,
j+,
and
)
salt
resulted
obtained
spectrum
3)
iM+Naj
a NaBF4
observed.
( l'8Fq-)
-5=8".2
for
Only
Na21SFL:~+
is
m/z
3).
iNa2BF4
tilycerol
ot
moae
witn
Na2F+,
of
PI-'
ion
the
were
Experiments
iz
119
are
both
be
uSed
ppb
at
of
-FAB the
levels
since
background
and
part
at
useful
+FA&
cationic
BF4-
charac-
very
(ref.
+/-FAB
these
are
low
con-
centrations.
Detection
of
F DNS
an
organoarsenic
has
(CH3)++CH2COO-) (ref.
Hecent marine
weak
very
LM+H]'
ions
of
other
spectrum
of
pure a
contains
few
However,
no
significant
(0.1-l
in
more
provides
isolated
oe
products
and
tions
can
were
detected.
fragment
too
This
products
as
cases
was
due
no to
The spectrum,
compared
to
or the
'FAB but
the
+FD
information.
obtained
since
from
isolated some
+FD
structural be
plaice
fractions. the
peaks
could
low.
in
isolated
more
spectra marine
that
resembles
therefore
from Vg)
showed
the
from
fractions
on 5)
arsenobetaine
spectrum
tities
(ref.
arsenabetaine
isolated
measurements
+FD
identify
to
fractions
products
presence
it
used in
4).
various
COInpOUnd
been
the
from available
the
fracquan-
381
problem
if
situated hign
in
the
protonated The
at
m/z
using
to
record
in
found,
of LM+H]*
i.e.
doublet
arising analyzed
obtained
at
for
the
this
as
of
of
fractions
which
this
The
fraction
problem, analyzer around
[2Fi+H]+
isolated
Figure
in
1.
the
peak
high gave
of
FD
crab were
peaks
an
unresolved
Various
resolution poor
from
Two
and
background.
and
is
reference.
a
glycerol
interest
region
arsenobetaine
method
a
multichannel mass
179.0053.
stiown
peak
from by
m/z
especially
of
circumvent
counting
\nias used
are
is
region
relevant
analysis
way
the To
ion
the
ion
the
tnis
-
region. an
185.1OiS
results
obtained
were
FAE
molecular
glycerol
case
this mass
I ow
used
was
i 11
as
resolution
system
be
-
background
glycerol
witn
interference
The
fractions
data
could
even
results.
.. *s
c5 “12 02 179.M53
‘.
.._
i .,. . .: ..
-_
-:..
Figure
1:
High from
Analysis
of
Interesting study tration given
of by
using
isomeric
fumaric
acid acid).
of
was in
acids of
(trans-butenedioic +FD
an
fraction
isolated
analyzer.
obtained
behaviour
Upon
a
carboxylic
carboxylic
differences
(cis-butenedioic
analysis
a multichannel
information
unsaturated
on
FAB
unsaturated
‘.. I..
.
resolution crab
I_
__ .. z,:;:
‘.,
M+*
acids with
(ref. cis
FD 6).
and acid)
peak
for
and A
good
trans and
FAD
in illus-
isomers maleic
fumaric
a
acid
is acid
382 and
LM+Hj+
an
reflects
the
explained
by
carboxylic This
the
aifference
and
acid
upon
simi
mode fumaric
Iat-
acid
at
results is
strong
high
be
bound
is
also
(M+Hj+ fUmariC
is
can
spectrum
of
fumaric
be
the in
twc
gives negative
-FAB
acid
no
its
+FAB-spectrum.
-f for
the
the
than
both
observed
hardly
In but
better
shown
acid
obtainer,
considerably
which
between
peak
concentrations.
are
result
This
acid
sigion
spectrum l
+FAB
the are
even
found.
isomer. isomers
wnereas
+FAB,
peaks,
can
cis two
A
was maleic
of
proton
the
the
experiments.
nificant
a
in
between
-FAB
maleic
that
groups
acid
affinity
proton fact
acid
maleic
for
peak
higher
indication
of
M
of In
.
ions
found.
CONCLUSIONS The
application
easier
is
and
presence FD
not
more
a
+FAB
analysis.
observed
with
in merits
an
by
This
which
can
background the
Moreover,
selective
effected
fumaric
by
are
acid,
true
in be
used
as
with by
not
references.
FD, a
of
to
2 3 4 5 6
FAB is
a in
components heating.
In
affinity, occur
as
with
high
applied
at
compounds. it
may
be
the
field
of
and
defects.
observed polar
that non-volatile
FD
and
FAB
-
as
compounds
REFERENCES 1
be
disadvantage
proton
expected
might
which
controlled low
the
compounds.
with but
for is
but
other
mode
also
respect
resorption
FD
caused
holds
ion
this
of
compared
determination
negative
prob’tems,
presence
structure
be
and
advantage
as
problems
weight
conclusion
present own
can
experiments
molecular
analysis.
fragmentions in
mixture
FD
severe
strongly
advantage
mixture
positive
peaks
by
ion
in
while
solvent
more
generates
in
the hampereti
influenced clear
than
work,
of
is
FAB
faster
resolution
hign
In
of
U. J. Surman and J.C. Vickerman, J. Chem. Sot. Chem. Commun., (1981) 324 M. Barber, B.S. Bordoli, R.D. Sedgwick and A.N. Tyler, ibid (lYB1) 325. Bradley, G. Williams, C. Bojesen, S. Santikarn and D.H. L.C.E. Taylor, 3. Am. Ch-em. Sac. 103 (1981) 5700. 3. van der Greef, M-C.. Ten Noever de Brauw, J.J. Zwinselman and N.M.M. Nibbering, Biomed, Mass Spectrom., in press. J.B. Luten, G. Riekwel-Booy and A. Rauchbaar, in preparation. J_ van der Greef and M.C. Ten J.B. Luten, G, Riekwel-3ooy, Noever de Brauw, in preparation. J.W. Dallinga, N.M.M. Nibbering, J. van der Greef and M-C. Ten Noever de Brauw, in preparation.
have
their