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A sticky situation

19 Jan 2016

Examining the intermediate stages of antibody purification provides insight into the manufacture of safer biopharmaceuticals at lower cost

A*STAR researchers have discovered how to dramatically reduce the number of contaminants during antibody purification.

A*STAR researchers have discovered how to dramatically reduce the number of contaminants during antibody purification.

© markusblanke/ iStock / Thinkstock

Monoclonal antibodies are an important new class of drugs to treat cancer, heart disease and a range of other conditions. However, their production in mammalian cells introduces a large number of contaminants that are difficult to remove during purification. Now, by looking at how antibodies change chemically during purification, A*STAR scientists have identified a better way to eliminate contaminants.

Protein A affinity chromatography is a technique that has dominated the field of antibody purification for the past 20 years, thanks to its remarkable ability to selectively bind to Immunoglobulin G (IgG). However, the purified antibody always contains more contaminants than it should. Previous studies compared IgG characteristics before and after protein A, and did not reveal why these contaminants persisted, but the technique still worked so well that there seemed little need to dig deeper.

Pete Gagnon and his team from the A*STAR Bioprocessing Technology Institute thought there was more to the question and decided to look more closely at what was happening to the antibody during the purification process, especially during elution when IgG is separated from protein A. Their findings came as a surprise.

“The antibodies became chemically ‘sticky’ under these conditions”, says Gagnon, “worse than that — they stuck to contaminants, and carried them along with them.”

Nothing could be done about the chemical conditions that cause the IgG to become sticky. But the team found a clever way out of this sticky situation — they discovered a class of contaminants called chromatin heteroaggregates that adhere to protein A even more strongly than IgG. “Chromatin is the operative element in a covert system for smuggling contaminants through purification methods — remove the chromatin in advance and there is nothing for the IgG to stick to,” says Gagnon.

By removing chromatin in advance, the team was able to achieve better purification with just protein A than most licensed manufacturing procedures can achieve with protein A and two additional steps. Gagnon cautions that this does not mean that purification of therapeutic antibodies can done with just one step, but it does mean that higher purity IgG can be achieved faster with less work and fewer materials.

Gagnon concludes: “Big improvements in process economics often demand compromises in performance, but here we have a situation where both economics and purification performance are improved. It’s all upside.”

The A*STAR-affiliated researchers contributing to this research are from the Bioprocessing Technology Institute. For more information about the team’s research, please visit the Downstream Processing Group webpage.

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References

Gagnon, P., Nian, R., Yang, Y., Yang, Q., & Lim, C. L. Non-immunospecific association of immunoglobulin G with chromatin during elution from protein A inflates host contamination, aggregate content, and antibody loss. Journal of Chromatography A 1408, 151–160 (2015). | Article

This article was made for A*STAR Research by Nature Research Custom Media, part of Springer Nature