Method for matrix effect correction in quantitative mass spectrometric analysis of analytes in complex matrices

The invention claimed is: 1. A method for quantifying one or more analytes in a sample forming a sample matrix, by an analysis system comprising a separation unit, a means of adding a solution of post-column infused internal standards (PCI-ISs) post-column to an eluate, and a detection unit comprising a mass spectrometer coupled through an ionization source, the method comprising: a. inducing a matrix effect on the one or more analytes in the sample and on the post-column infused internal standards (PCI-ISs) by one of the following steps: i. adding one or more test matrices (matrices B) to the eluate, after separation in the separation unit and before introduction to the ionization source of the mass spectrometer (herein referred to as post-column); or ii. varying the composition of the sample matrix (matrix A) by mixing it with other test matrices (matrices C); or iii. varying the concentration of the sample matrix (matrix A); and b. matching one or more post-column infused internal standard(s) (PCI-IS) to each analyte that best matches the analyte's response to the matrix effect to obtain an analyte-matched PCI-IS identification and associated response data, and c. storing the analyte-matched PCI-IS identification and associated response data in a library; and d. applying the analyte-matched PCI-IS to the one or more analytes in other samples to correct observed analyte peak responses for the matrix effect during ionization. 2. The method according to claim 1 , wherein during step d the analyte-matched PCI-IS is additionally applied to obtain absolute quantitation of the analyte using the response data, wherein the one or more analytes may not have a structure assigned yet, or a compound with a known structure for which no reference material is available, or a compound for which the use of reference material is not practical due to costs or instability, or a compound with a known structure for which a reference material is available. 3. The method according to claim 1 , wherein the separation unit is configured and operable to produce a liquid flow, selected from the group consisting of a liquid chromatography unit, a supercritical fluid chromatography and an online solid phase extraction unit, wherein the ionization source is an electrospray ionization source. 4. The method according to claim 1 , wherein in step (a)(i) the one or more matrices comprises at least one compound, or plurality of compounds expected to induce a matrix effect on the analytes in the sample, wherein in step (a)(i), one or more salts and/or ionic compounds able to form adducts, a compound with surface activity and/or a compound with high proton affinity, and/or a biologically originating matrix, a fraction thereof, are employed. 5. The method according to claim 1 for determining for each analyte the PCI-IS that best matches the analyte's response to matrix effect, further comprising: (a) determining for each analyte in the sample a signal, reconstructed by each PCI-IS, with, and separately, without inducing the matrix effect according to step (a); and (b) assessing, which of the compounds employed as PCI-IS, or combination of compounds, matches best the analyte's response to the induced matrix effect. 6. The method according to claim 5 for determining for each analyte a reconstituted signal for each PCI-IS and internal standard reconstructed signal, both with and without inducing the matrix effect, further comprising one or more of a. subjecting the one or more analytes of the sample to the analysis system, while adding post-column a solution of one or more PCI-IS(s) to the eluate; b. repeating the subjection of the one or more analytes of the sample to the analysis system while inducing the matrix effect by applying one or more of the procedures specified in step (a) of claim 1 ; c. dividing in each sample the signal or intensity of a scan-by-scan by the PCI-IS signal or intensity in the same analysis run, giving a PCI-IS-reconstructed analyte signal or peak response; d. dividing the signal or intensity of each internal standard scan-by-scan by the signal or intensity of its matched PCI-IS in the same measurement run, giving the PCI-IS-corrected internal standard signal or peak response; and e. dividing the PCI-IS-reconstructed analyte signal or peak response by the applicable PCI-IS-corrected internal standard signal(s) or peak response(s) in the same measurement run, giving a PCI-IS and internal standard reconstructed peak response. 7. The method according to claim 6 , wherein the method comprises an additional step of adding one or more internal standards to the sample prior to analysis in step b, wherein the one or more internal standards added to the sample during sample preparation comprise a structural analogue of PCI-IS and/or a stable isotope labelled version of a PCI-IS. 8. The method according to claim 7 , wherein an assessment for each analyte which PCI-IS matches best the analyte's response to the induced matrix effect comprises basing the selection of PCI-IS on: (a) values for accuracy, comparing the PCI-IS and internal standard reconstructed peak response of each analyte in a sample with, and without the induced matrix effect as specified in claim 1 ; (b) values for precision of the PCI-IS reconstructed peak response of the analyte across matrices and/or samples; or (c) its ability to increase a linear dynamic range of an analyte and/or on values for accuracy and/or on values for precision. 9. The method according to claim 1 , wherein a variety of test matrices is used to induce a matrix effect on the one or more analytes in a sample, wherein the induced effect of the individual test matrices on the analyte is employed for: a. at least partial structural identification of the analyte; and/or b. optimization of the selection of PCI-IS or a combination of PCI-ISs that best matches the analyte's response to induced matrix effects. 10. The method according to claim 1 , wherein the one or more PCI-IS, or combination of PCI-ISs that matches best the one or more analyte's response to the induced matrix effect(s) is stored in a library unit, wherein the analyte-matched PCI-IS or combination of PCI-ISs in the library is applied to the one or more analytes, comprising the steps of: a. subjecting the one or more analytes of the sample to the analysis system; b. adding a post-column a solution of PCI-IS(s) to the eluate; c. matching the analyte signals found in the sample with analytes stored in the library unit; and d. reconstructing the mass spectrometric response of each analyte in the sample by dividing the signal or intensity of each internal standard scan-by-scan by the signal or intensity of its matched PCI-IS in the same measurement run, giving a PCI-IS-corrected internal standard signal or a peak response and dividing a PCI-IS-reconstructed analyte signal or peak response by the applicable PCI-IS-corrected internal standard signal(s) or peak response(s) in the same measurement run, using the matched PCI-IS in the library unit, to obtain a final PCI-IS and internal standard corrected peak response. 11. The method according to claim 1 , wherein the PCI-IS signal or a signal ratio between each analyte and PCI—IS is being used for quality control purposes. 12. A test matrix composition or combination of matrix compositions for determination of the structure and/or quantity of one or more analytes in a sample according to claim 1 , wherein the composition comprises one or more salts and/or ionic compounds able to form adducts, a compound with surface activity and/or a compound with proton affinity, and/or a biologically originating matrix, a fraction thereof in a pred