Processing of spatially resolved, ion-spectrometric measurement signal data to determine molecular content scores in two-dimensional samples

1 . A method for processing ion-spectrometric measurement signal data which are recorded spatially resolved across a two-dimensional sample, comprising: providing the measurement signal data, which have a plurality of measurement signal histograms, where a measurement signal histogram is assigned, by means of two location coordinates (x, y), to a finite area (A fin,x,y ) of the two-dimensional sample, which is smaller than a total area (A total ) of the two-dimensional sample, and contains a measurement signal tuple having intensity dimension (J) or a quantity derived therefrom, mass dimension (m) or a quantity derived therefrom, and collision cross-section dimension (σ) or a quantity derived therefrom; specifying a first selection of ionic species and a second selection of ionic species for the two-dimensional sample, whose presence in measurement signal histograms is detectable and can be distinguished using the collision cross-section dimension (σ) or the quantity derived therefrom: determining the spatially resolved content of ionic species from the first selection and the spatially resolved content of ionic species from the second selection in measurement signal histograms of the finite areas (A fin,x,y ), and computing the various contents to form spatially resolved content scores (G x,y ); and labeling the two-dimensional sample with the spatially resolved content scores (G x,y ). 2 . The method according to claim 1 , wherein the two-dimensional sample was prepared with a matrix substance for matrix-assisted laser desorption. 3 . The method according to claim 1 , wherein the first selection of ionic species comprises those of high analytical interest, and the second selection of ionic species comprises those of low analytical interest. 4 . The method according to claim 1 , wherein the first selection of ionic species comprises biomolecules such as proteins, peptides, glycans, and/or lipids in the two-dimensional sample. 5 . The method according to claim 1 , wherein the second selection of ionic species comprises charged atoms or molecules and/or clusters thereof, which are generated by the method of sample preparation and/or the method of ionization. 6 . The method according to claim 1 , wherein after the labeling, a user is presented with an image of the two-dimensional sample in which individual finite areas (A fin,x,y ) are visibly coded with the assigned content scores (G x,y ). 7 . The method according to claim 1 , wherein predetermined value ranges of the content score are evaluated as ion-spectrometric measurement signals from outside the two-dimensional sample. 8 . The method according to claim 1 , wherein a subsequent evaluation (i) only takes into account measurement signal histograms from finite areas (A fin,x,y ), where the content scores (G x,y ) lie in a predetermined range of values, and/or (ii) uses the content scores (G x,y ) as weighting factors. 9 . The method according to claim 1 , wherein the first selection of ionic species is specified by summing several measurement signal histograms into an aggregated measurement signal histogram and determining an interesting portion of measurement signal tuple entries in the aggregated measurement signal histogram. 10 . The method according to claim 9 , wherein the interesting portion of the measurement signal tuple entries is used to distinguish the first selection of ionic species from the second selection in at least one dimension of the measurement signal histograms. 11 . The method according to claim 9 , wherein the interesting portion of measurement signal tuple entries is determined by means of regression analysis. 12 . The method according to claim 11 , wherein the regression analysis comprises a logarithmic regression or a logarithmic Radon transform. 13 . The method according to claim 11 , wherein the regression analysis searches for a correlation between collision cross-section (σ) and mass (m) of a molecule according to the equation σ(m)≈C m k , where C is a molecule-dependent proportionality factor and k is a molecule-dependent exponent. 14 . The method according to claim 9 , wherein the aggregated measurement signal histogram is calculated by a location-independent summation of several measurement signal histograms. 15 . The method according to claim 14 , wherein the location-independent summation takes into consideration only those measurement signal histograms where the measurement signal tuple entries of at least one dimension (i) exceed a predetermined threshold value, (ii) are below a predetermined threshold value, or (iii) are within a predetermined value range. 16 . The method according to claim 14 , wherein at least one measurement signal tuple entry of the individual measurement signal histograms is transformed before the summation such that measurement signal tuple entries of a first predetermined range are disproportionately weighted with respect to a second predetermined range. 17 . The method according to claim 1 , wherein the spatially resolved content score (G x,y ) is calculated using G x , y = Σ i ∈ S a ⁢ J i Σ i ∈ S a ⁢ J i + Σ iϵS b ⁢ J i ⁢ ⁢ or ⁢ ⁢ G x , y = Σ