Abstract: In a device (4) for assisting in analytical operations for correctly arranging samples in a plurality of sample-placement portions and implementing multiple protocols in the correct order, a storage section (41) holds sample information and analysis parameters for each protocol as well as the order of implementation. A protocol-selection-input receiver (42) receives an input of the selection of a protocol. A sample-position displayer (43) displays, on a display unit (6), sample information in the selected protocol along with the positions of the sample-placement portions. A protocol-implementation-information collector (45) collects information concerning the state of implementation of the protocols. A determiner (46) determines whether a protocol which must be implemented earlier was already implemented, based on the state of implementation and order of implementation of the protocols.

Abstract: In a device for processing imaging-analysis data, two kinds of imaging-analysis data are stored in a storage section 21: (a) first imaging-analysis data, in which measurement data of a target substance, acquired by performing a first predetermined analysis at each of a plurality of measurement points within an analysis target area of a sample S, is associated with spatial position information of the measurement point, and (b) second imaging-analysis data, in which measurement data of a reference substance, acquired by performing a second predetermined analysis at each of the measurement points, is associated with spatial position information of the measurement point. A normalization executer 28 normalizes the measurement data of the target substance at each measurement point, based on the measurement data of the reference substance acquired at the same measurement point.

Abstract: One mode of the present invention provides a laser power adjustment method for ionization in a laser desorption/ionization mass spectrometer, the laser power adjustment method including: a measurement step (S1) in which intensity information on ions derived from a specific component in a specimen are acquired while changing laser power in n stages (n is 3 or more) for the identical specimen; and a processing step (S2, S6, and S7) in which a slope of a straight line connecting two adjacent plot points on a laser power axis is calculated in a two-axis graph in which a relationship between n ionic intensities obtained by the measurement step or a signal value, which is an SN ratio obtained from the ionic intensities, and laser power is plotted; an index value reflecting a ratio between a forward slope value, which is a slope of a straight line on a front side of the plot point, and a backward slope value, which is a slope of a straight line on a rear side, is obtained for each plot point; and appropriate laser p

Abstract: In a device (4) for assisting in analytical operations for correctly arranging samples in a plurality of sample-placement portions and implementing multiple protocols in the correct order, a storage section (41) holds sample information and analysis parameters for each protocol as well as the order of implementation. A protocol-selection-input receiver (42) receives an input of the selection of a protocol. A sample-position displayer (43) displays, on a display unit (6), sample information in the selected protocol along with the positions of the sample-placement portions. A protocol-implementation-information collector (45) collects information concerning the state of implementation of the protocols. A determiner (46) determines whether a protocol which must be implemented earlier was already implemented, based on the state of implementation and order of implementation of the protocols.

Abstract: After collecting mass spectrometry data for each of a large number of measurement points in the two-dimensional region on the sample with the imaging mass spectrometry unit, the user inputs the target compound whose two-dimensional distribution is desired to be observed from the input unit. The image display instruction reception unit obtains the m/z range for data integration from the precise m/z value and the allowable width of m/z for each target compound. The mass-to-charge ratio range overlap determination unit determines the presence or absence of overlap between the m/z ranges of a plurality of compounds, and if there is an overlap, the overlap determination result processing unit creates and displays on the screen of the display unit a list of compounds whose m/z ranges overlap, for example. This urges the user to review the compounds and allowable values.

Abstract: In a device for processing imaging-analysis data, two kinds of imaging-analysis data are stored in a storage section 21: (a) first imaging-analysis data, in which measurement data of a target substance, acquired by performing a first predetermined analysis at each of a plurality of measurement points within an analysis target area of a sample S, is associated with spatial position information of the measurement point, and (b) second imaging-analysis data, in which measurement data of a reference substance, acquired by performing a second predetermined analysis at each of the measurement points, is associated with spatial position information of the measurement point. A normalization executer 28 normalizes the measurement data of the target substance at each measurement point, based on the measurement data of the reference substance acquired at the same measurement point.

Abstract: A mass spectrometry device includes: an image generation unit that generates an image indicating a mass spectrometry sample arranged on each sample mounting portion in which each position of a plurality of sample mounting portions in a sample plate for laser desorption/ionization corresponds to each position of the plurality of sample mounting portions in an image, wherein: in the image, a display element indicating a direction is displayed at a position corresponding to the sample mounting portion.