Purification Techniques | Unveiling the MaXtar® Butyl HR High-Resolution Hydrophobic Interaction Chromatography Resin

Hydrophobic interaction chromatography (HIC) resins play a critical role in downstream purification processes for biopharmaceuticals. HIC leverages differences in surface hydrophobicity of proteins or biomolecules, utilizing reversible binding between hydrophobic groups and the stationary phase’s hydrophobic ligands under high-salt conditions. It serves an irreplaceable function in key steps such as aggregate removal and impurity protein purification. Among these, the MaXtar® Butyl HR HIC resin stands out for its high resolution, moderate hydrophobicity, and low cost, playing a key role in the purification of antibodies and recombinant proteins. Below is a detailed introduction to this high-performance HIC product.

I. Core Product Performance Advantages

MaXtar® Butyl HR is a butyl-based hydrophobic interaction chromatography (HIC) resin. Its core advantages include:

Excellent Separation Performance, Impurities Nowhere to Hide

The superior separation performance of MaXtar® Butyl HR depends largely on its particle size distribution. With an average particle size of 40 μm, the overall particle size is relatively small. Based on the principles of hydrophobic interaction chromatography, it efficiently separates structurally similar impurities, playing an important role in antibodies (including bispecific antibodies), recombinant proteins, and vaccines.

Application Case 1

- Sample Information: Bispecific antibody (pI 8-9) Column volume: 4.7 mL (H=10 cm)

- Equilibration Buffer: 100 mM PB, 1 M (NH₄)₂SO₄, pH 7.0

- Elution Buffer: 100 mM PB, pH 7.0

- Loading: 20 mg/mL

Figure 1: Bispecific antibody purification chromatogram 1

Sample Name	SEC_HPLC
Sample Name	HMW(%)	Monomer(%)	LMW(%)
Loading Sample	2.3	94.2	3.5
Elution Peak 1	ND	99.8	0.2

Table 1: SEC purity before and after bispecific antibody purification

Summary: MaXtar® Butyl HR demonstrates excellent separation performance in the purification of this bispecific antibody, with particularly strong removal of high-molecular-weight impurities. High-molecular-weight impurities are essentially eliminated, achieving a final SEC purity of 99.8%.

Application Case 2

- Sample Information: Bispecific antibody

- Column Volume: 4.7 mL (H=10 cm)

- Equilibration Buffer: 20 mM PB, 1 M (NH₄)₂SO₄, pH 7.0

- Elution Buffer: 20 mM PB, pH 7.0

- Loading: 20 g/L

Figure 2: Bispecific antibody purification chromatogram 2

Sample Name	SEC_Main Peak(%)	CE_NR_Main Peak(%)
Loading Sample	76.6	75.1
Elution Peak	98.8	96.3

Table 2: Purification performance after bispecific antibody purification

Summary: After purification with MaXtar® Butyl HR, SEC and CE‑NR purity are significantly improved. Bispecific antibody SEC purity increased from 76.6% to 98.8%, and CE‑NR purity increased from 75.1% to 96.3%.

Controllable Batch-to-Batch Variability, Reliable Quality

Figure 3: Hydrophobicity characterization of three batches of MaXtar® Butyl HR resin

Summary: Using a monoclonal antibody to characterize the hydrophobicity of three batches of MaXtar® Butyl HR, the peak shapes and elution positions are essentially identical across batches, showing no significant differences in hydrophobicity.

High Flow Rate and Low Backpressure, Supporting Industrial Production

1. Pressure-Flow Rate Curve

Figure 4: Pressure-flow rate curve of MaXtar® Butyl HR

2. Packing for Production

Column Specification	D=300mm H=20cm
Column Efficiency HETP	5066.56
Symmetry AS	1.48

Table 3 & Figure 5: Packing of 200/500 column

Summary: MaXtar® Butyl HR is based on the MaXtar high-flow modified agarose matrix. Under conditions of D=300 cm, H=15 cm, at a pressure of 3 bar, the maximum flow rate reaches 330 cm/h, and it has been successfully applied in industrial production.

II. Application Tips

1. Selection of Loading Salt Solution

In early process development, the loading salt solution should be selected. For MaXtar® Butyl HR HIC resin, it is recommended to initially perform a linear elution using (NH₄)₂SO₄. If the target protein elutes with difficulty or cannot be effectively eluted under these conditions, switch to a NaCl system to continue optimizing elution conditions.

2. Elution Process Optimization

During linear elution on HIC resins, if the sample shows clear separation trends, the method can be further developed into step elution and finally optimized to a one-step elution. If protein separation is poor, consider reducing the loading capacity or increasing the column volume of the linear elution to improve resolution of the target protein.

3. Control of Influencing Factors

Many factors affect HIC, including temperature, loading capacity, pH and salt concentration of the loading solution. These factors can significantly impact the hydrophobicity of the resin. Therefore, during method development, attention should be paid to their influence on separation selectivity and resolution, thereby laying the foundation for subsequent process scale-up and robustness validation.

III. Product Ordering Information

Product Name	Cat. No.	Pack Size
MaXtar® Butyl HR	1041-1811	25mL
	1041-1812	100mL
	1041-1813	500mL
	1041-1814	1L
	1041-1815	5L
	1041-1816	10L
	1041-1817	20L
Chrom-Trap® MaXtar® Butyl HR 1mL	2041-1811	1×1mL
Chrom-Trap® MaXtar® Butyl 4.7mL	2041-1812	1×4.7mL
Chrom-Trap® MaXtar® Butyl 5mL	2041-1813	1×5mL

Table 4: Product catalog numbers

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Purification Techniques | Unveiling the MaXtar® Butyl HR High-Resolution Hydrophobic Interaction Chromatography Resin

08 Jun 2026