HPLC analysis of oligosaccharides in urine from oligosaccharidosis patients.

Analysis of urinary oligosaccharides by thin-layer chromatography (TLC) is used as screening procedure for 10 different lysosomal diseases. We tested the usefulness of HPLC in screening, using a CarboPac PA1 column (Dionex), pulsed amperometric detection (PAD), and post-column derivatization (PCD). Patterns from six types of oligosaccharidoses were compared with normal urinary patterns and with the TLC patterns. PAD appeared to be nonspecific and therefore is applicable only to desalted urine samples. PCD was more specific and applicable to nondesalted urine samples, albeit with a lower resolving power. Peaks in urines from oligosaccharidoses patients were identified on the basis of retention times of commercially available oligosaccharides or TLC bands after isolation and HPLC of the corresponding oligosaccharides. Abnormal oligosaccharide peaks were seen in urines from patients with alpha-mannosidosis, GM1-gangliosidosis (juvenile), GM2-gangliosidosis (Sandhoff disease), Pompe disease, and beta-mannosidosis. HPLC detected no abnormal oligosaccharides in urine from patients with fucosidosis. Although TLC is a simple and reliable screening procedure for detecting classical lysosomal diseases with oligosaccharide excretion, HPLC, by its higher resolution and possibility of quantification, can more generally be used for recognition of abnormal oligosaccharides or detection of increased excretion or content for known oligosaccharides in urine, other body fluids, and cells.

High-performance liquid chromatography of monosaccharides and oligosaccharides in a complex biological matrix.

Analysis of oligosaccharides in complex biological matrices is hampered by the fact that oligosaccharides, closely related in structure, are difficult to separate from each other and that conventional detection procedures (refraction index and uv detection) are not specific enough for carbohydrates. Prepurification of samples by procedures like desalting or gel filtration is often used but can lead to the loss of specific oligosaccharides. We have used pellicular anion chromatography in combination with a postcolumn reaction for reducing carbohydrates based on 4-aminobenzoylhydrazide. This procedure not only detected normal mono- and oligosaccharides but N-acetylhexosamines and reducing N-acetylhexosamine containing oligosaccharides as well. A sensitivity of about 20-25 pmol for non-GlcNAc containing mono- or oligosaccharides and between 30-50 pmol for GlcNAc or oligosaccharides with GlcNAc at the reducing side was reached. The postcolumn detection was compared with pulsed amperometric detection and appeared to be more specific for mono- and oligosaccharides. Except for deproteination to protect the column, no further sample preparation was needed with this system for our application (urines). In this way pellicular anion chromatography in combination with this postcolumn reaction reaction to be a sensitive and specific HPLC procedure for analysis of monosaccharides and oligosaccharides in complex biological matrices.