Patent Description:
In a liquid chromatograph mass spectrometer (which may be hereinafter abbreviated as the "LC-MS"), a so-called "atmospheric pressure ionization (API) method", such as an electrospray ionization (ESI) method, atmospheric pressure chemical ionization (APCI) method or atmospheric pressure photoionization (APPI) method, is employed to ionize compounds in an eluate supplied from a column of a liquid chromatograph. In an atmospheric pressure ion source employing an atmospheric pressure ionization method, the eluate is sprayed through a spray nozzle into an ambience of substantially atmospheric pressure, and the compounds in the fine droplets produced by the spraying process are ionized to generate gaseous ions. Therefore, in order to improve the ionization efficiency, it is important to promote atomization and vaporization of the sprayed droplets.

The largest portion of the eluate introduced into the atmospheric pressure ion source is the mobile phase used in the liquid chromatograph. If the mobile phase is simply composed of water, alcohol, acetonitrile (ACN) or other basic substances, the characteristics of the mobile phase may not be suitable for performing satisfactory ionization in an atmospheric pressure ion source. Accordingly, for an LC-MS, an appropriate kind of reagent is often used as an additive to the mobile phase according to the characteristics of the sample, kind of mobile phase used, kind of ionization method and other related factors in order to improve the ionization efficiency (for example, see Non Patent Literature <NUM>). Normally, such an additive is often mixed into the mobile phase. For an additive which may affect the separation characteristics of the column in the liquid chromatograph, the so-called "post-column" method is used, in which the reagent is mixed into the eluate exiting from the outlet of the column instead of being mixed into the mobile phase before the mobile phase is introduced into the column (for example, see Patent Literature <NUM>).

In the case of adding a reagent by the post-column method, the compounds in the sample have already been separated at the point of the addition of the reagent. Accordingly, it is essential to appropriately determine not only the kind and amount of reagent to be added, but also the timing of the addition according to the compound, because the effectiveness of the reagent varies depending on the characteristics and concentration of the compound even when the same reagent is used. Besides, in the case of a gradient analysis, since the mixture ratio of the mobile phases changes with time, the effectiveness of the reagent may change with the mixture ratio even when the same reagent is used. Furthermore, in the case of the post-column method, an increase in the amount of addition of the reagent directly increases the amount of eluate introduced into the atmospheric pressure ion source. Therefore, for example, adding a highly volatile reagent in greater quantity does not always enhance the ionization efficiency.

However, in the case of performing a measurement on a sample containing various compounds with different characteristics, it is difficult to set the addition condition of the reagent so that a high level of ionization efficiency can be achieved for each of those various compounds. Accordingly, in conventional LC-MSs, the addition condition of the reagent is not always optimized for all various compounds to achieve the highest or nearly highest level of ionization efficiency. In some cases, the detection sensitivity in the mass spectrometer is sacrificed.

<CIT> discloses a method of ionising a sample comprising performing an initial experiment comprising: (i) adding one or more reagents to an analyte sample; (ii) varying the composition and/or concentration of the one or more reagents; (iii) ionising the analyte sample including the one or more reagents; (iv) determining the composition and/or concentration of the one or more reagents which results in a desired, improved or optimised ionisation or other condition or parameter for one or more analytes of interest; and (v) determining one or more first retention times or one or more first retention time windows for the one or more analytes of interest; and then separating an analyte sample using a first separation device and during the course of a single experimental run or acquisition varying the composition and/or concentration of one or more reagents which are added to an eluent which emerges from the first separation device, the composition and/or concentration of the one or more reagents which are added to the eluent is varied at the one or more the first retention times or during the one or more the first retention time windows so that an ionisation or other condition or parameter for the one or more analytes of interest is as desired or is improved or optimised.

Patent Literature <NUM>: <CIT> (Paragraph [<NUM>]).

The present invention has been developed to solve the previously described problem. Its objective is to provide a method for liquid chromatographic mass spectrometry and a liquid chromatograph mass spectrometer in which the ionization efficiency in an atmospheric pressure ion source is improved for various compounds contained in a sample so that a higher detection sensitivity can be achieved as compared to conventional techniques.

According to a first aspect of the present invention there is provided a method for liquid chromatographic mass spectrometry as specified in claim <NUM>.

According to a second aspect of the present invention there is provided a liquid chromatograph mass spectrometer as specified in claim <NUM>.

In the liquid chromatograph mass spectrometer according to the present invention, each of the first and second additive supply sections may include: an additive container for holding an additive in a liquid form; a liquid supply pump for drawing the additive from the additive container and supplying the additive at a predetermined flow rate; and a passage for merging the additive supplied from the liquid supply pump into the eluate transported from the outlet of the column to the atmospheric pressure ion source. The plurality of additives supplied from the liquid supply pumps may be mixed together before being merged into the eluate, or each additive may be individually merged into the eluate. The additive supplier may further include another additive supply section in addition to the first and second additive supply sections. That is to say, the device may be configured to be capable of mixing three or more kinds of additives into the eluate.

In the liquid chromatograph mass spectrometer according to the present invention, the first additive supply section adds the first additive to the eluate at an appropriate flow rate, while the second additive supply section adds the second additive to the eluate at an appropriate flow rate, under the control of the controller. Accordingly, an eluate in which the first and second additives have been mixed reaches the atmospheric pressure ion source. In the atmospheric pressure ion source, the eluate is sprayed into an ambience of atmospheric pressure. Through this spraying process, the eluate is atomized into droplets, and the compounds (sample components) in those droplets are ionized.

The ionization mechanism itself depends on the technique used for the atmospheric pressure ionization, such as the ESI. In any case, the ionization efficiency mainly depends on the conditions concerning the electric charging, such as the ease of charging of the eluate introduced into the atmospheric pressure ion source, as well as the conditions concerning the ease of ejection of the compound (or ion) in a gasified form, such as the size of the droplets sprayed into the ambience of substantially atmospheric pressure and the ease of vaporization of the solvent in those droplets. Accordingly, in the method for liquid chromatographic mass spectrometry according to the present invention, a reagent which affects the charge state of the eluate is used as the first additive, while a reagent which affects the size of the droplets of the eluate or vaporization efficiency of the droplets when the eluate is sprayed into the ambience of atmospheric pressure in the atmospheric pressure ion source is used as the second additive. The flow rates at which the two kinds of additives, i.e. the first and second additives, are respectively mixed are appropriately adjusted according to the kind and characteristics of the compound contained in the sample, the kind of mobile phase and other factors. The appropriate amounts of addition of the two additives can be experimentally investigated.

By mixing the two or more kinds of additives with different characteristics into the eluate by the post-column method and introducing them into the atmospheric pressure ion source, the ionization efficiency in the atmospheric pressure ion source for various compounds can be improved to be higher than conventional levels. Accordingly, a larger quantity of ions can be subjected to mass spectrometry for any of the compounds, and the detection sensitivity can be thereby improved. Therefore, for example, it will be possible to detect a compound which cannot be detected by conventional techniques. Furthermore, a mass spectrum with a sufficient level of signal intensity can be obtained for a compound for which a sufficient signal intensity for qualitative determination or structural analysis has not been conventionally obtained, so that the qualitative determination or structural analysis can be accurately performed.

In the liquid chromatograph mass spectrometer according to the present invention, the controller may preferably be configured to control an operation of the first additive supply section and the second additive supply section according to a program in which the flow rate of the first additive and the flow rate of the second additive can be individually changed according to the passage of time.

According to this configuration, the program can be appropriately set beforehand so as to mix two or more kinds of additives into the eluate in such a manner that their respective amounts of addition continuously change with time. Consequently, each target compound can be assuredly detected with a high level of sensitivity.

In the method for liquid chromatographic mass spectrometry according to the present invention, typically, the first additive is a reagent for pH control and/or having a high level of proton affinity, and the second additive is a reagent having at least one nature selected from a lower boiling point, a lower surface tension and a lower viscosity than a mobile phase.

There are various kinds of reagents available as the first or second additive. Aqueous ammonia, triethylamine, acetic acid, formic acid, trifluoroacetic acid, ammonium acetate, and ammonium formate, which are all commonly used pH-control reagents, can be used as the first additive, i.e. the reagent which affects the charge state of the eluate. Dimethyl sulfoxide (DMSO), m-nitrobenzyl alcohol (m-NBA, where m is <NUM>, <NUM> or <NUM>) and glycerol may also be used as the first additive. These reagents affect the charge state distribution of the ions. It is known that DMSO has a charge-state-gathering effect, while m-NBA and glycerol have a charge-state--increasing effect (see Non Patent Literature <NUM>). On the other hand, acetonitrile, <NUM>-propanol, methanol, ethanol, <NUM>-propanol, acetone and other organic solvents can be used as the second additive, i.e. the reagent having a lower boiling point, lower surface tension or lower viscosity than the mobile phase.

A study by the present inventor suggested that it is preferable to use DMSO as the first additive and <NUM>-propanol as the second additive, both of which are easily available and highly effective. DMSO is a polar aprotic solvent. It produces the effect of gathering charge states and is therefore effective for ionizing a compound. However, DMSO has a high boiling point and is difficult to be vaporized. On the other hand, <NUM>-propanol has a low boiling point and is easy to be vaporized. It also has a low surface tension, which helps the formation of fine droplets. Thus, <NUM>-propanol can compensate for the shortcomings of DMSO in terms of the generation of gaseous ions in the atmospheric pressure ion source. The use of such additives can particularly improve the detection sensitivity for high-molecular compounds of biological origin, such as peptides or sugar chains.

In one possible mode of the method for liquid chromatographic mass spectrometry according to the present invention, the sample to be subjected to a measurement is a mixture of a peptide and a glycopeptide, the first additive is a pH-control reagent, and the flow rate of the first additive is changed with the passage of time in such a manner that the eluate exiting from the outlet of the column of the liquid chromatograph becomes acidic during a period of time in which the peptide is contained in the eluate, whereas the eluate exiting from the outlet of the column of the liquid chromatograph becomes basic during a period of time in which the glycopeptide is contained in the eluate.

In this case, the polarity of the ion to be detected may be switched so as to perform a positive ion measurement in the mass spectrometer during a period of time in which a peptide and a glycopeptide including a neutral sugar chain are eluted, and to perform a negative ion measurement in the mass spectrometer during a period of time in which a glycopeptide including an acidic sugar chain is eluted. By this operation, a high level of sensitivity can be achieved in detecting any of the three kinds of substances contained in the sample, i.e. a peptide, a glycopeptide including a neutral sugar chain, and a glycopeptide including an acidic sugar chain.

The present invention uses an electrospray ion source as the atmospheric pressure ion source.

An electrospray ion source sprays an eluate into an ambience of substantially atmospheric pressure while electrically charging the droplets by the effect of a high electric field. The compounds, such as peptides, are ionized through the atomization process which includes the splitting of the charged droplets into finer particles. DMSO and some other reagents have a lower surface tension than water and therefore more easily allows the atomization of the droplets. The atomization of the charged droplets facilitates the Coulomb repulsive force to act inside each droplet as well as promotes the ejection of gaseous ions, whereby the ionization efficiency is improved (see Non Patent Literature <NUM>). That is to say, when the method for liquid chromatographic mass spectrometry according to the present invention is applied in a liquid chromatograph mass spectrometer employing an electrospray ion source, the effect of gathering charge states and the effect of promoting the atomization of the droplets by the additives are combined together, so that the ionization efficiency can be more noticeably improved.

With the liquid chromatograph mass spectrometer and the method for liquid chromatographic mass spectrometry according to the present invention, the ionization efficiency in an atmospheric pressure ion source can be improved to the highest or nearly highest level for each of the various compounds contained in a sample. Therefore, a higher level of detection sensitivity can be achieved than in the case of a conventional analyzing method or device.

One embodiment of the LC-MS according to the present invention, and one embodiment of an analyzing method using the LC-MS, are hereinafter described with reference to the attached drawings.

<FIG> is an overall configuration diagram of the LC-MS in the present embodiment.

The LC-MS in the present embodiment includes a liquid chromatograph unit (LC unit) <NUM>, mass spectrometer unit (MS unit) <NUM>, control unit <NUM>, data-processing unit <NUM>, as well as an input unit <NUM> and display unit <NUM> which serve as user interfaces.

The LC unit <NUM> includes: liquid supply pumps 11a and 11b for drawing mobile phases a and b from two mobile phase containers 10a and 10b, respectively, and for supplying those mobile phases; a mixer <NUM> for mixing the two mobile phases a and b; an injector <NUM> for injecting a liquid sample into a mobile phase; a column <NUM> for separating compounds; a column oven <NUM> for controlling the temperature of the column <NUM>; and a post-column adding unit <NUM> provided in an eluate passage <NUM> on the outlet side of the column <NUM>. The post-column adding unit <NUM> includes: a first T-joint <NUM> located on the eluate passage <NUM>; a second T-joint <NUM> connected to the first T-joint <NUM>; two additive containers 163A and 163B which respectively contain different kinds of additives A and B; and two additive supply pumps 164A and 164B for drawing additives A and B from the additive containers 163A and 163B, respectively, and for supplying those additives.

The MS unit <NUM> has a chamber <NUM>, which is partitioned into an ionization chamber <NUM>, first intermediate vacuum chamber <NUM>, second intermediate vacuum chamber <NUM> and a high vacuum chamber <NUM>. The inside of the ionization chamber <NUM> is maintained at substantially atmospheric pressure, while the high vacuum chamber <NUM> is maintained in a high vacuum state by a high-performance vacuum pump (not shown). The first and second intermediate vacuum chambers <NUM> and <NUM> are individually evacuated by vacuum pumps so that the degree of vacuum increases in a stepwise manner from the ionization chamber <NUM> to the high vacuum chamber <NUM>. An ESI spray <NUM> for performing ionization by the ESI method is provided within the ionization chamber <NUM>. The ionization chamber <NUM> communicates with the first intermediate vacuum chamber <NUM> through a thin desolvation tube <NUM>. The first intermediate vacuum chamber <NUM> contains an ion guide <NUM> for transporting ions while converging them. The first intermediate vacuum chamber <NUM> communicates with the second intermediate vacuum chamber <NUM> through an orifice formed at the apex of a skimmer <NUM>. The second intermediate vacuum chamber <NUM> contains an ion guide <NUM> for transporting ions while converging them. The high vacuum chamber <NUM> contains a first quadrupole mass filter <NUM> and a second quadrupole mass filter <NUM> placed before and after a collision cell <NUM>, respectively, with a detector <NUM> located behind the second mass filter. Detection signals obtained with the detector <NUM> are fed to the data-processing unit <NUM>.

The control unit <NUM> includes an LC control section <NUM> for controlling the operation of each section of the LC unit <NUM>, and an MS control section <NUM> for controlling the operation of each section of the MS unit <NUM>. The LC control section <NUM> includes a timing controller <NUM>, mobile phase supply controller <NUM>, additive supply controller <NUM> and temperature controller <NUM>.

A typical operation of the LC-MS in the present embodiment is as follows:
The mobile phase supply controller <NUM> in the LC control section <NUM> controls the liquid supply pumps 11a and 11b to draw mobile phases a and b from the mobile phase containers 10a and 10b, respectively, and supply them at their respective flow rates, according to a previously determined program (time sequence) in which the relationship between the flow rate (or flow velocity) and the passage of time is specified. The two supplied mobile phases a and b are mixed together by the mixer <NUM> and sent through the injector <NUM> into the column <NUM>. According to an instruction from the timing controller <NUM>, a liquid sample is injected from the injector <NUM> into the mobile phase at a predetermined timing. The injected liquid sample is pushed by the mobile phase and sent into the column <NUM>. While passing through the column <NUM>, the various compounds in the liquid sample are separated from each other in the longitudinal direction of the column <NUM> (i.e. in the temporal direction), to be eluted from the outlet of the column <NUM> with different amounts of time lag. The temperature controller <NUM> regulates the temperature of the column oven <NUM> according to a previously determined temperature program, e.g. to maintain a constant temperature of <NUM>.

Additive A which has an appropriate nature is previously prepared in the additive container 163A. Another additive B, which is a different kind from additive A and has an appropriate nature, is also previously prepared in the additive container 163B. The additive supply controller <NUM> controls each of the additive supply pumps 164A and 164B to draw and supply additives A and B prepared in the additive containers 163A and 163B, respectively, according to a previously determined additive supply program (time sequence). Being mixed together through the two T-joints <NUM> and <NUM>, the two additives A and B are mixed into the eluate flowing through the eluate passage <NUM>. That is to say, while the eluate containing the compounds separated by the column <NUM> is flowing through the post-column adding unit <NUM>, the two additives A and B are mixed into the eluate in their respective appropriate quantities.

The eluate which has flown through the eluate passage <NUM> and reached the ESI spray <NUM> in the MS unit <NUM> is sprayed from the nozzle of the same spray <NUM> into an ambience of substantially atmospheric pressure while being ionized under the effect of a biased electric field created around the tip of the nozzle. Thus, fine charged droplets containing the compounds and solvent (including the mobile phase, solvent of the original liquid sample, and additives) are sprayed. Since a considerable amount of residual gas is present within the ionization chamber <NUM>, the charged droplets released from the ESI spray <NUM> come in contact with the molecules of the residual gas and are thereby gradually divided into smaller particles. Meanwhile, the ionization chamber <NUM> is heated with a heater (not shown), whereby the vaporization of the solvent in the charged droplets is prompted. The compounds in the droplets capture electric charges and are ejected from the droplets to turn into gaseous ions. The generated ions are drawn into the desolvation tube <NUM> by the stream of gas formed by the pressure difference between the two ends of the desolvation tube <NUM>, to be carried into the first intermediate vacuum chamber <NUM>. Under the effect of the electric fields created by the ion guides <NUM> and <NUM>, those ions are sequentially transported to the high vacuum chamber <NUM>, where only an ion having a predetermined mass-to-charge ratio is selected as the precursor ion in the first quadrupole mass filter <NUM>.

In the collision cell <NUM>, a predetermined kind of collision gas, such as argon, is introduced. The ion which has passed through the first quadrupole mass filter <NUM> enters the collision cell <NUM> and is fragmented due to the collision induced dissociation. The various kinds of product ions generated by the fragmentation are introduced into the second quadrupole mass filter <NUM>, where only a product ion having a specific mass-to-charge ratio is selected. Thus, the specific product ion which has originated from the specific precursor ion and passed through the second quadrupole mass filter <NUM> reaches the detector <NUM>. The detector <NUM> produces a detection signal corresponding to the amount of incident ion. This signal is digitized in the data-processing unit <NUM> and then subjected to a predetermined data-processing operation. For example, a mass chromatogram is created based on the data sequentially obtained with the passage of time. An area value of a peak corresponding to the target compound on that mass chromatogram is calculated, and a quantitative value is calculated based on the area value.

The gradient program which determines the mixture ratio of the two mobile phases a and b in the LC/MS analysis, the program which determines the flow rate for each of the two additives A and B, as well as the temperature program for controlling the temperature of the column <NUM>, should be previously set as part of the analysis conditions by an operator from the input unit <NUM>.

In the LC-MS according to the present embodiment, two kinds of additives (reagents) A and B can be added to the eluate in the post-column adding unit <NUM>. These additives do not affect separation characteristics in the LC unit <NUM>. Therefore, it is preferable to determine the kinds of additives and the flow-rate program according to the kind of sample (kinds of compounds) to be subjected to the measurement, kinds of mobile phases and other factors so that the highest possible level of ionization efficiency will be achieved in the ESI spray <NUM>, or the ESI ion source, in the MS unit <NUM>. The combination of the two additives may be appropriately determined. In the case of the ESI ion source, the major factors which affect the ionization efficiency are the charge state immediately before the formation of the charged droplets and the ease of ejection of the gaseous ions from the charged droplets. The latter factor is related to the size of the charged droplets and the ease of vaporization of the solvent in the droplets. The ejection of the gaseous ions becomes easier as the viscosity of the eluate becomes lower, the surface tension of the eluate becomes lower, or the boiling point of the solvent in the droplets becomes lower. Accordingly, these factors are considered in determining the combination of the additives.

A measurement example of the analyzing method using the LC-MS in the present embodiment is hereinafter described. In the following case, the compounds to be subjected to the measurement are peptides.

In this measurement example, dimethyl sulfoxide (DMSO) was selected as additive A, and <NUM>-propanol as additive B. DMSO is a polar aprotic solvent. It is a reagent which can produce the effect of gathering charge states. This effect of DMSO results from the fact that the high degree of proton affinity of DMSO causes progressive removal of protons from high charge states in which non-localized protons are present in lysine and arginine at the C-terminus of a trypsin-digested peptide or in the N-terminus of the peptide. On the other hand, <NUM>-propanol has the characteristics as shown in the table below. Although its coefficient of viscosity is higher than that of water or acetonitrile used as the mobile phase, it has a lower surface tension, which helps the formation of fine droplets in the spraying process. Its low boiling point also allows for easy vaporization.

The relationship between the flow rates of the two additives and the detection sensitivity was investigated by experiments as follows:.

The measurement conditions were as follows:.

<FIG> is the result of the measurement of the relationship between the flow rate of additive A and the peak area value on the mass chromatogram for peptide <NUM>-<NUM>. <FIG> is the result of the measurement of the relationship between the flow rate of additive A and the peak-area value on the mass chromatogram for peptide <NUM>-<NUM>. In the case of peptide <NUM>-<NUM>, as shown in <FIG>, the highest sensitivity (approximately <NUM>×<NUM><NUM>) was obtained when the flow rate of additive A (<NUM>% DMSO) was <NUM>µL/min (the final concentration of DMSO was <NUM> %). It can also be seen that the sensitivity did not increase with the further increase in the flow rate of additive A. In the case of peptide <NUM>-<NUM>, the highest level of sensitivity (approximately <NUM>×<NUM><NUM>) was obtained at a lower flow rate of additive A, i.e. <NUM>µL/min (the final concentration of DMSO was <NUM> %). In the latter case, the sensitivity noticeably decreased with the further increase in the flow rate of additive A. The detection was almost impossible when the flow rate was equal to or higher than <NUM>µL/min.

It seems that such a difference in the relationship between the flow rate of additive A and the peak area depending on the kind of peptide occurs due to the length of the amino acid sequence of the peptide, hydrophobicity of the peptide, contained amount of the acidic amino acid, and other factors.

<FIG> is the result of the measurement of the relationship between the flow rate of additive B and the peak area value on the mass chromatogram for peptide <NUM>-<NUM>. <FIG> is the result of the measurement of the relationship between the flow rate of additive B and the peak area value on the mass chromatogram for peptide <NUM>-<NUM>. As shown in <FIG>, for both peptides, the highest sensitivity (approximately <NUM>×<NUM><NUM> and <NUM>×<NUM><NUM>) was obtained when the flow rate of additive B (<NUM>-propanol) was <NUM>µL/min. The highest sensitivity increased to a level equal to or even higher than <NUM> times the level achieved in Experiment <NUM> in which additive B was not added. This result demonstrates that the combined use of additives A and B is effective for improving the detection sensitivity.

From the results of those experiments, it is possible to conclude that a nearly highest detection sensitivity can be obtained for peptide <NUM>-<NUM> and peptide <NUM>-<NUM> by supplying additive A (<NUM>% DMSO) at a flow rate of <NUM>µL/min and additive B (<NUM>-propanol) at a flow rate of <NUM>µL/min. In practice, it is possible that more appropriate conditions may be found by investigating the peak area with a changing flow rate of additive A.

If the target compounds to be detected are previously determined as in the experiments, it is possible to previously and experimentally investigate the combination of the flow rates of two additives A and B which yields the highest detection sensitivity for each target compound. Combinations of the kinds of additives which yield even higher levels of detection sensitivity can also be investigated beforehand. After the flow rates of the additives have been determined for each target compound based on the results of such experiments, the flow-rate program can be created so that the flow rates will be set at appropriate levels at the timing of the elution of each target compound, i.e. at the retention time for each target compound. With the created flow-rate program set as one of the analysis conditions, an LC/MS analysis is performed, whereby signals can be obtained with a nearly highest level of detection sensitivity for each target component.

In the previous embodiment, two additives are mixed in the eluate. It is possible to add one or more additive containers as well as additive supply pumps to mix a total of three or more additives in the eluate.

The combination of the additives is not limited to the one used in the previously described experiments. For example, in an analysis using an acidic mobile phase, a basic additive may be used in combination with an additive for promoting the atomization or vaporization of the droplets (e.g. <NUM>-propanol). This combination improves the detection performance for basic components while achieving an improvement in the overall detection sensitivity. Various other additives already mentioned as examples may also be used.

Claim 1:
A method for liquid chromatographic mass spectrometry in which a liquid chromatograph mass spectrometer employing a mass spectrometer (<NUM>) including an atmospheric pressure ion source (<NUM>) comprising an electrospray ion source is used as a detector for a liquid chromatograph (<NUM>),
the method including steps of:
preparing a sample to be subjected to a measurement,
introducing the sample into a column (<NUM>) of the liquid chromatograph (<NUM>),
mixing at least two kinds of additives as a first additive and a second additive into an eluate flowing in a passage (<NUM>) connecting an outlet of the column (<NUM>) and the atmospheric pressure ion source (<NUM>), where each of the two additives is mixed into the eluate at an arbitrary flow rate, the first additive is a reagent which affects a charge state of the eluate, and the second additive is a reagent which affects a size of droplets of the eluate when the eluate is atomized into droplets by the electrospray ion source as the eluate is sprayed into an ambience of atmospheric pressure in the atmospheric pressure ion source (<NUM>), and
calculating a quantitative value of a compound contained in the sample based on a result of detection of the compound by the mass spectrometer (<NUM>).