Chromatographic monoliths exhibit several properties like flow‐unaffected resolution and dynamic binding capacity, low pressure drop and high capacity for extremely large molecules, which are advantageous to the purification of large biomolecules such as proteins, DNA or even viruses. Recently, large‐volume monolithic columns were introduced enabling the monoliths to be incorporated into industrial downstream processes. Due to the monolithic structure, however, conventional methods for resin characterization cannot be applied to monoliths, which limit their usage under cGMP conditions. In this article, a methodology of how to overcome this problem and to determine the most important parameters is presented. Several fast and noninvasive methods for monolith characterization are introduced. Their usage enables accurate determination of monolith pore size distribution and specific surface area, uniformity of the monolith as well as type and density of the active groups before or during monolith usage. Chromatographic monoliths nowadays are used in all chromatographic fields, also for industrial applications. Monitoring and control of the monolith properties require the development of new, noninvasive techniques. The methods presented enable the accurate determination of monolith pore size distribution and specific surface area, uniformity of the monolith as well as type and density of the active groups before or during monolith usage.