(. Most
silanol groups (red) are converted to hydrophobic alkylsiloxy groups. The history and evolution of reversed phase stationary phases in described in detail in an article by Majors, Dolan, Carr and Snyder. In the 1970s, most
liquid chromatography runs were performed using solid particles as the stationary phases, made of unmodified
silica gel or
alumina. This type of technique is now referred to as
normal-phase chromatography. Since the stationary phase is
hydrophilic in this technique, and the mobile phase is non-polar (consisting of organic solvents such as hexane and heptane), biomolecules with hydrophilic properties in the sample
adsorb to the stationary phase strongly. Moreover, they were not dissolved easily in the mobile phase solvents. At the same time
hydrophobic molecules experience less affinity to the polar stationary phase, and elute through it early with not enough retention. This was the reasons why during the 1970s the silica based particles were treated with hydrocarbons, immobilized or bonded on their surface, and the mobile phases were switched to aqueous and polar in nature, to accommodate biomedical substances. The use of a hydrophobic stationary phase and polar mobile phases is essentially the reverse of normal phase chromatography, since the polarity of the mobile and stationary phases have been inverted – hence the term reversed-phase chromatography. As a result, hydrophobic molecules in the polar mobile phase tend to adsorb to the hydrophobic stationary phase, and hydro
philic molecules in the sample pass through the column and are eluted first. Hydrophobic molecules can be eluted from the column by decreasing the polarity of the mobile phase using an organic (non-polar) solvent, which reduces hydrophobic interactions. The more hydrophobic the molecule, the more strongly it will bind to the stationary phase, and the higher the concentration of organic solvent that will be required to elute the molecule. Many of the mathematical parameters of the theory of chromatography and experimental considerations used in other chromatographic methods apply to RP-LC as well (for example, the selectivity factor, chromatographic resolution, plate count, etc.). It can be used for the separation of a wide variety of molecules. It is typically used for separation of proteins, because the organic solvents used in normal-phase chromatography can denature many proteins. Today, RP-LC is a frequently used analytical technique. There are a huge variety of stationary phases available for use in RP-LC, allowing great flexibility in the development of the separation methods.
Silica-based stationary phases Silica gel particles are commonly used as a stationary phase in high-performance liquid chromatography (HPLC) for several reasons, including: •
High surface area: Silica gel particles have a high surface area, allowing direct interactions with solutes or after bonding of variety of ligands for versatile interactions with the sample molecules, leading to better separations. •
Chemical and thermal stability and inertness: Silica gel is chemically stable, as it usually does not react with either the solvents of the mobile phase nor the compounds being separated, resulting in accurate, repeatable and reliable analyses. •
Wide applicability: Silica gel is versatile and can be modified with various functional groups, making it suitable for a wide range of analytes and applications. •
Efficient separation: The unique properties of silica gel particles, combined with their high surface area and controlled average particle diameter pore size, facilitate efficient and precise separation of compounds in HPLC. •
Reproducibility: Silica gel particles can offer high batch-to-batch reproducibility, which is crucial for consistent and reliable HPLC analyses throughout decades. •
Particle diameter and pore size control: Silica gel can be engineered to have specific pore sizes, enabling precise control over separation based on molecular size. •
Cost-effectiveness: Silica is one of the most abundant minerals on earth, hence its gel is a cost-effective choice for HPLC applications, making it widely adopted in laboratories. The
United States Pharmacopoeia (USP) has classified HPLC columns by L# types. The most popular column in this classification is an octadecyl carbon chain (C18)-bonded silica (USP classification L1). This is followed by C8-bonded silica (L7), pure silica (L3), cyano-bonded silica (CN) (L10) and phenyl-bonded silica (L11). Note that C18, C8 and phenyl are dedicated reversed-phase stationary phases, while CN columns can be used in a reversed-phase mode depending on analyte and mobile phase conditions. Not all C18 columns have identical retention properties. Surface functionalization of silica can be performed in a monomeric or a polymeric reaction with different short-chain organosilanes used in a second step to cover remaining silanol groups (
end-capping). While the overall retention mechanism remains the same, subtle differences in the surface chemistries of different stationary phases will lead to changes in selectivity. Modern columns have different polarity depending on the ligand bonded to the stationary phase. PFP is pentafluorophenyl. CN is cyano. NH2 is amino. ODS is octadecyl or C18. ODCN is a mixed mode column consisting of C18 and nitrile. Recent developments in chromatographic supports and instrumentation for liquid chromatography (LC) facilitate rapid and highly efficient separations, using various stationary phases geometries. Various analytical strategies have been proposed, such as the use of silica-based
monolithic supports, elevated mobile phase temperatures, and columns packed with sub-3 μm superficially porous particles (fused or solid core) or with sub-2 μm fully porous particles for use in ultra-high-pressure LC systems (UHPLC). ==Mobile phases==