Ion Exchange Chromatography

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  • Ion exchange chromatography (IEX) is a separation method using the difference of charge states between the mobile phase and analytes from the stationary phase in the column. It is mainly used for the analysis of ionic compounds. There are two types of IEX; anion exchange chromatography and cation exchange chromatography, and the type used depends on the ionic strength of theTable 1. Typical Ion Exchange Functional Groups Used In the Stationary Phase ion exchange group. Table 1 shows typical functional groups per IEX stationary phase type. Strong ion-exchange functional groups can always be ionized, while ionization conditions of weak ion-exchange groups can vary depending on the pH of the mobile phase. The appropriate stationary phase is selected according to the charge and properties of the analyte.
    Note that when ion exchange chromatography is applied, cations and anions cannot be separated within a single analysis.
  • Table 1. Typical Ion Exchange Functional Groups Used In the Stationary Phase

      Ionic Strength Typical Functional Groups
    Cation Exchange Chromatography Strong (SCX) Sulfonic acid
    Weak (WCX) Carboxylic acid
    Anion Exchange Chromatography Strong (SAX) Quaternary ammonium
    Weak (WAX) Tertiary amine

 

 

Fig.1 shows the workings of anion exchange chromatography.

In the stationary phase of anion exchange chromatography, packing materials modified with positively charged ion-exchange groups are used. When the mobile phase (eluent) enters the column, it absorbs onto the ion exchange groups of the stationary phase due to electrostatic attraction. The mobile phase continuously introduces anions into the column, resulting in a repeated adsorption and desorption of anions between the stationary and mobile phases, i.e. a state of equilibrium. When a sample containing anions is introduced into the column during this state, the anions in the sample are adsorbed through electrostatic interactions with the functional groups of the stationary phase. At the same time, the anions from the mobile phase that were previously adsorbed on the stationary phase are desorbed. The sample anions adsorbed on the stationary phase are then desorbed and adsorbed onto the next ion exchange group. This phenomenon is repeated until the sample anions completely move through the column and are eluted.
 

Fig.1 Mechanism of IEX

Fig. 1 The Workings of Anion Exchange Chromatography

 

 

Different types of ions in the sample interact differently with the ion exchange groups, resulting in differences in the speed at which they move through the column. This difference is used to separate the ions in the sample. Ions with a smaller valence interact less with the ion exchange groups and therefore elute from the column faster. However, ions with the same valence or homologous elements will still elute faster if they have smaller ionic radiuses.

 

Fig.2 shows the chromatogram of the standard solutions for seven anions. An anion exchange chromatography column (Shim-pack IC-SA3)  was used in this analysis case. It was shown that F, Cl, and Br in the anion mixing standard solution were halogen elements, and that they eluted in order from small to large ionic radius, though their ionic values were the same.
Fig.3 shows the chromatogram of a five-sequence oligonucleotide mixture. An anion exchange chromatography column (Shim-pack BIO IEX Q-NP) was used in this oligonucleotide analysis case. The separation of oligonucleotides is based on the number of phosphate groups in the oligonucleotide, i.e., the difference in negative charges. Therefore, each oligonucleotide was separated by their length.

In ion-exchange chromatography, if a sample contains compounds whose ionic state changes with pH, changing the pH of the mobile phase as well as the salt concentration of the mobile phase can change the elution order.

 

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