At present, Earth is the only place that is known to harbour life in this Universe, and little is understood about the origin of life. Previous laboratory studies discovered that some of the organic molecules that reside in life on Earth also occur in the most primitive types of meteorites. As such, they may have contributed to building blocks of life through extraterrestrial delivery. In this thesis, we discuss our novel approach for studying the nature of meteoritic organics. Instead of the conventional image-by-image analysis, we used our NanoSIMS to map a large surface area of SaU 290 and studied the statistical behaviour of over 5,000 organic inclusions, which were automatically extracted by image analysis software (SourceExtractor). We extensively tested all parts of our analysis and performed data filtering, to maximise the accuracy of the obtained data on SaU290. The data was compared with the previously recorded maps of three other meteorites: Murchison, GRA 95229 and QUE 99177. As a result, we acquired a large set of new information on the nature of meteoritic organics, including correlations among the morphological, elemental and isotopic parameters of each meteorite, tendencies for certain types of organic inclusions to cluster, and trends among the four meteorites. Given the complex evolution of the Solar System and the diversity of meteoritic organics, we conclude that the correlations and the trends that were found within and among the meteorites in this study offer new insights to the current understanding of the origin of life.