Radiant energy – Ionic separation or analysis – Ion beam pulsing means with detector synchronizing means
Reexamination Certificate
2001-09-06
2004-04-06
Lee, John R. (Department: 2881)
Radiant energy
Ionic separation or analysis
Ion beam pulsing means with detector synchronizing means
C250S282000
Reexamination Certificate
active
06717134
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to a method for calibrating a mass spectrometer. In particular, this invention relates to a method for calibrating a mass spectrometer using the mass spectrum of daughter or fragment ions produced by post-source decay of a meta-stable ion in a reflectron time-of-flight (TOF) mass spectrometer.
2. Description of Related Art
In a TOF mass spectrometer, meta-stable ions (also referred to as pre-cursor ions) are generated in an ion source from a sample and repelled from the source into a drift region. In the drift region, these meta-stable ions may break into fragments in a process known as post-source decay. Alternatively, post-source decay may be induced by laser or within a collision cell to produce fragment ions. These fragment or daughter ions are useful for determining the structure of the sample from which the meta-stable ions are generated. For example, in the case of a peptide sample, these daughter ions are related to the amino acid composition of the sample molecule and can therefore be used to deduce sequence information.
In this specification the terms parent ion, meta-stable ion and pre-cursor ion will be used interchangeably as will the terms daughter ion and fragment ion.
When analysing a sample by normal TOF mass spectrometry i.e. with or without a reflectron, the user is presented with data relating to the time that the ions have taken to travel through the drift region. The time taken is dependent on the mass to charge ratio of the ion. In order to convert the time of flight data into the more useful mass data, it is necessary to calibrate the mass spectrometer using a spectrum of a known compound in which the molecular identity and therefore the molecular weight of the ions observed is known. In this way it is possible to correlate flight time and molecular weight so that on analysing an unknown compound, it possible to assign weights to the unknown peaks on the basis of the flight time for the peak.
In a reflectron TOF mass spectrometer, the daughter ions formed in post-source decay are separated according to their velocity and according to their energy (which is related to their mass); whereas normal, parent ions all have approximately the same energy (having been accelerated by the same potential) and are separated according to their velocity only. Therefore the mass calibration for the daughter ions is not the same as for the normal (original meta-stable) ions.
Ions which undergo post source decay (PSD) do so (by definition) in the field free region. Thus ions that fragment in the source or the reflectron are not detected in the PSD fragment spectrum—either because they are selected out or do not reach the detector in time focus. Because there are no external fields (no external forces on the ions) momentum is conserved and all the fragments retain the velocity of the pre-cursor ion i.e., the velocity with which it left the ion source. The kinetic energy of the ions is given by the following equations:
Pre-cursor:
E
p
=½
m
p
v
p
2
Fragment ion:
E
f
=½
m
f
v
p
2
where E
p
=Kinetic energy of precursor ion, E
f
=kinetic energy of fragment ion, m
p
=mass of precursor ion, m
f
=mass of fragment ion and v
p=
velocity of precursor ion).
Thus it follows that the ratio of the mass of a fragment ion to that of the pre-cursor is the same as the ratio of their kinetic energies:
m
f
/m
p
=E
f
/E
p
In a linear time-of-flight mass spectrometer we can see that because the velocities of the fragment and pre-cursor ions are the same there is no way of distinguishing between them—they arrive at the detector at the same time and therefore have the same measured mass.
In a reflectron time-of-flight mass spectrometer ions encounter a retarding field in the reflectron and travel into the reflectron to the point where their potential energy equals their kinetic energy. The ions are then turned around and reflected back out to emerge from the reflectron with the same speed but in the reverse direction. The reflectron is an energy analyser and can thus distinguish between pre-cursor ions and fragment ions and also fragment ions of different mass. This is the principle of fragment mass analysis in a reflectron time-of-flight mass spectrometer whatever type of reflectron is used. It applies to linear field reflectrons, where the voltage is stepped or scanned over multiple experiments in order to build up a complete fragment spectrum and also to curved field or quadratic field reflectrons which allow the fragment spectrum to be acquired in one shot.
The calibration of the time of flight spectrum for fragments is not the same as that of the pre-cursor ions. In the normal pre-cursor ion spectrum the ion energy is essentially the same for all mass whereas for the fragment ions there is a dependence of the ion energy on mass for the flight time in the reflectron. It is possible to calculate the calibration function for the fragment ions and relate this to the normal calibration function for the pre-cursor ions. Usually, the fragment mass calibration will depend on the ratio of the fragment mass with respect to the pre-cursor ion mass. However, for best mass accuracy and for practical reasons a calibration will be based typically on a fragment mass spectrum of a known compound. Typically a single known compound which gives rise to eight or so known fragments (of known masses) is used.
In the example of a curved field reflectron the basic calibration function has a form as follows. The actual mass, m
act
of the fragment ion can be related to the apparent mass, m
app
that would be measured using the normal mass calibration (i.e., that of the pre-cursor ions). The ratio m
act
/m
app
follows a curve which depends only on the ratio of m
act
to the pre-cursor mass, m
pre
. By knowing the m
act
for a standard compound and measuring the m
app
the calibration curve can be defined for all pre-cursor masses. An example of such a curve is shown in FIG.
1
. It can be seen from
FIG. 1
that if the fragment has the same mass as the precursor ion, the apparent measured mass will be the same as the real mass. If however the fragment ion's actual mass is less than the precursor ion, the apparent measured mass (m
app
) of the fragment ion will be greater than its actual mass (m
act
). In
FIG. 1
the apparent mass of the fragment ion is approximately 1.4 times its actual mass when the actual fragment mass is 10% of the precursor ion mass. The exact shape of the calibration curve will be different for each spectrometer depending upon the reflectron and drift tube dimensions.
The inventors have realised that conventional methods of calibrating for PSD fragments in a reflectron mass spectrometer introduce errors into the calibration and lead to inaccurate mass measurement. This is due to a complication caused by the fact that the parent meta-stable ion has a natural isotope distribution, for example, from the natural abundance of carbon
13
isotopes in the molecule. The current invention provides a method of correcting for or avoiding these errors.
The errors and a method of correcting for or avoiding them are explained below.
BRIEF SUMMARY OF THE INVENTION
One embodiment of the present invention is directed to a method of calibrating a reflectron time-of-flight mass spectrometer using a spectrum generated by fragment ions wherein a mass of a fragment ion is assigned using mono-isotopic peak only.
Another embodiment of the present invention is directed to a method of analysing a spectrum of fragment ions generated by a reflectron time-of-flight mass spectrometer. A mass of a fragment ion is assigned using a mono-isotopic mass peak only.
A further embodiment of the present invention is directed to a calibration apparatus for use in a mass spectrometer. The calibration apparatus includes means for selecting only a mono-isotopic peak in a distribution pattern of a fragment ion; and means for assigning a mass to the selected mono-isotopic peak.
REFERENC
Kalivoda Christopher M.
Kratos Analytical Limited
Lee John R.
Squire Sanders & Dempsey L.L.P.
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