Purpose: To establish whether advanced glycation is the major mechanism for yellowing of lens proteins.
Methods: Synchronous fluorescence (SF) and immunochemical assays were used to study glycation in vitro and in vivo. In the in vitro study, advanced glycation end products (AGEs) were prepared and used as antigens to induce antibodies to AGEs. The in vitro AGEs and classified nuclear cataracts were analyzed by SF and immunochemical assays.
Results: In vitro AGEs generated from various glycating agents and carrier proteins displayed strong SF above 350 nm; the spectra were well resolved with major bands at 380 nm and 420 nm. Samples from human lenses manifested a band at 395 nm in addition to the two bands shown by in vitro AGEs. SF intensity is greater for the water-insoluble (WI) than water-soluble (WS) fraction, but both increased with increasing nuclear color. The immunoreactivity data also showed that the WI fraction contained more AGEs than the WS fraction and that the amount of AGEs increased with increasing nuclear color.
Conclusions: Fluorescence and immunoassays indicated that pigmented AGEs contributed to yellowing of the crystalline lens nucleus.