Agilent and Waters give HPLC a Makeover

WATERS' ACQUITY UPLC SYSTEMCourtesy of WatersLong the method of choice for fast, accurate protein purification, HPLC has been revamped in recent months. Two companies, Agilent Technologies in Palo Alto, Calif., and Waters in Milford, Mass., released new high-performance liquid chromatography systems designed specifically for the microscale sample requirements of mass spectrometry-based proteomics. Though they adopt different approaches, both systems have been hailed by developers and users alike

Aileen Constans
Aug 29, 2004
<p>WATERS' ACQUITY UPLC SYSTEM</p>

Courtesy of Waters

Long the method of choice for fast, accurate protein purification, HPLC has been revamped in recent months. Two companies, Agilent Technologies in Palo Alto, Calif., and Waters in Milford, Mass., released new high-performance liquid chromatography systems designed specifically for the microscale sample requirements of mass spectrometry-based proteomics. Though they adopt different approaches, both systems have been hailed by developers and users alike as harbingers of liquid chromatography's next wave.

SMALLER PARTICLES, HIGHER EFFICIENCY

Water's http://www.waters.com new Acquity UPLC (ultra-performance liquid chromatography) system exploits the basic principles of chromatography to deliver a high-throughput, high-resolution instrument designed for use with or without mass spectrometers. "The end result is speed, sensitivity, and resolution that is above and beyond anything that people see today with HPLC," says John Morawski, UPLC program manager for Waters.

Central to UPLC is the 1.7 μm, ethane-bridged, hybrid silica-polymer particle used as...

HPLC-ON-A-CHIP

Proteomics researchers working with small sample sizes have largely turned to capillary nano-LC technologies, which are based on fused silica capilary tubes linked by fittings and connections. These fittings have relatively high dead volumes and can get clogged easily. Enter Agilent's http://www.agilent.com new HPLC-Chip, a microfluidics device containing integrated enrichment and separation columns and an electrospray tip that interfaces with Agilent's Tof MS system to ensure that the tip is in the correct position for mass analysis. "The advantage of going to microfluidics here is that you can eliminate all these connection and get rid of all those dead volumes, and [you] are able to handle the small amounts of fluids on the microfluidic chip," says Tom van de Goor, R&D project manager for LC-MS solution at Agilent.

<p>AGILENT'S HPLC-CHIP</p>

Courtesy of Agilent

Eliminating LC components also aids troubleshooting. "Doing nanoflow can be very tricky because of how you have to put things together. And you're going at a very low flow rate, so it's very hard to detect leaks. It's hard to troubleshoot if anything goes wrong," says beta-user Karen Jonscher, University of Colorado, Boulder. Like other nanoflow systems, the HPLC-Chip can be tricky to use, Jonscher cautions. "You have to have everything working right all at the same time for it to work. Things that you could fudge in a normal slow source and that would still work, you can't fudge in this," she says, noting that her version is a pre-production system and that Agilent has since redesigned the chip. "I think it'll be the easiest system for somebody who's not familiar with nanoflow to get up and going with," she adds.

Pierre Thibault of the University of Montreal, who has used the system for the past four months, says the system's compatibility with other MS systems is another concern. It is currently configured only for Agilent's MS instruments, but Christina Maehr, Agilent press-relations manager, says the company has long-term plans to make the chip platform more broadly compatible.

- Aileen Constans

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