Bypass high-performance liquid chromatography for purification of trace analytes

Measurement of N7-(2'-hydroxyethyl)guanine in human DNA by gas chromatography electron capture mass spectrometry

An improved method is presented, based on gas chromatography-electron capture mass spectrometry (GC-EC-MS), for measuring N7-(2'-hydroxyethyl)guanine (N7-HEG) in DNA from an in vivo sample. The method was used to detect this adduct in amounts of human DNA ranging from 0.07 to 11.5 microg isolated from granulocytes. In this method, the DNA is spiked with a stable isotope internal standard (N7-HEG-d4) and heated in water to release the adduct in a nucleobase form. After the adduct is extracted into 1-butanol, it is purified by reverse phase HPLC and derivatized with HONO, pentafluorobenzyl bromide, and pivalic anhydride. Further purification by silica solid phase extraction and reverse phase HPLC is done prior to injection into a GC-EC-MS. Relatively clean GC-EC-MS chromatograms result, contributing to the high sensitivity that is observed. In the samples tested, from 1.6 to 240 N7-HEG adducts in 10(7) nucleotides were observed, a 150-fold range.

Trace detection of glycolic acid by electrophore labeling gas chromatography-electron capture mass spectrometry

As little as 10 pg of standard glycolic acid (glycolate) was detected in a method comprising the following sequence of steps: (1) add glycolate-2,2-d(2) as an internal standard and exchange the carboxylate oxygens in hot HCl/[(18)O]water; (2) form an amide derivative with a water-soluble carbodiimide and the electrophoric amine, AMACE1; (3) purify by bypass HPLC; (4) derivatize the residual hydroxy with butyric anhydride; (5) partition with acetonitrile/2 M NaCl; and (6) detect by GC-ECMS. At an intermediate stage in method development, 1 pg of glycolate-2,2,-d(2) could be detected by subjecting it to the above steps 2-6, forming product in an overall, absolute yield of 76%. Step 1 was added after an effort to fully overcome background contamination by glycolate was unsuccessful. For example, background contamination by glycolate could increase rather than decrease when the methanol reagent in the procedure was "carefully purified." The work extends the sensitivity for glycolate detection by approximately 100-fold and provides high-performance conditions for the analytical steps employed.