Reducing sugars can react nonenzymatically with free amino groups on proteins and form a variety of fluorescence-producing advanced glycosylation end products (AGEPs). These irreversible compounds have previously identified to accumulate on long-lived extracellular matrix proteins and probably also onDNA in tissues that develop diabetic complications. In this study, we examinedthe rates of variable carbohydrates including glucose, galactose, mannose, fructose, arabinose and xylose in stimulating AGEPs by incubating these sugarswith bovine serum albumin in vitro. The accumulations of AGEPs were be monitored by fluorescence detection at 410 nm. After 1 week incubation, arabinose and xylose stimulate 10 folds more AGEPs than other sugars. Further incubation,protein cross-linking were be found in these two sugars resulted in shift ofelectrophoretic motility. Fructose elicited 150% more AGEPs than glucose after2 or 3 week's incubation and the differences between fructose and glucosedramatically increased thereafter. In conventional glycemic control, pentoseand fructose have been preferentially employed due to their low absorption rateand greater clearance rate than those of glucose. However, long term usage ofarabinose, xylose and fructose as diet sugar substitutes may have adverse effectsbecause they stimulate more AGEPs accumulation. We also raised the polyclonalantibodies directed against protein-bound AGEPs and developed an immunohistochemical staining to screen the available tissue paraffin blocksfrom patients with or without diabetes. Our results demonstrate that AGEPs accumulate in many diabetics' tissues. We also used Enzyme Linked ImmunosorbentAssay (ELISA) to detect the amount of LDL- AGEPs in diabetes and elder.These results clearly show that high level of AGEPs products in the two groups than the healthy group. In conclusion, these antibodies can use to detect AGEPs in tissues and serve as a new marker of cardiac vascular complications in diabetes and aging individuals.