Many preparative separations undertaken within the laboratory begin life with a separation carried out at analytical scale. One must develop an analytical method in which the selectivity of the target analytes is maximized. In this way, the amount of analyte that can be loaded onto the column (and hence recovered from the column) per injection is optimized. Elution of analytes in more highly organic fractions is preferred from a sample recovery perspective as these fractions are more quickly and cost effectively processed.

When the sample of interest has good solubility in the mobile phase, concentration overload is the technique of choice and sample concentration is increased while the injected sample volume remains constant. Column efficiency (as dictated by particle size) has little effect on concentration overloading, and the selectivity of the separation tends to be the dominant factor. When increasing the sample concentration, it may be necessary to use cosolvents within the diluent (dimethyl sulfoxide and dimethylformamide are popular) to improve sample solubility. If the diluent is more highly eluotropic than the eluent, however, problems can arise with peak shape and with precipitation during post-injection mixing with the eluent (which limits loadability).

When the sample of interest has limited solubility in the mobile phase, then volume overload is the technique of choice and sample volume is increased while the sample concentration remains constant. Volume overloading is heavily influenced by stationary-phase particle size and column diameter. Most preparative chromatography methods use a mixture of concentration and volume overloading to obtain the maximum amount of analyte on column per injection.

After the analytical-scale method has been developed and the loading factor has been estimated, the method can be scaled up using various simple calculations and estimation methods. Scalable factors include eluent flow rate, column internal diameter, gradient profile, sample volume loaded, solvent consumption, total fraction volume, and yield. A detailed treatment of various approaches to method scale-up can be found in the accompanying CHROMacademy Essential Guide on-line article.

Preparative HPLC equipment differs from analytical scale only in the capability to deliver very high flow rates (100 mL/min is not unusual in a laboratory-scale semipreparative separation), and typically the inclusion of a fraction-collection device for automated sample recovery. Preparative fractions are typically collected by means of a diverter valve that can be triggered either by time settings or detector signal. If the fraction collection is time based, then one must take care to avoid analyte retention time drift. Where the collection is triggered by mass (using mass spectrometry detection), a response threshold, or a rate of change in detector response, the delay volume (time) between the detector and the fraction collector nozzle must be carefully calibrated to ensure precious sample is not lost.