AI Article Synopsis
- Gout attacks can be seen as events where crystal formation occurs; crystallization inhibitors like carboxyl and hydroxyl groups can help prevent this.
- L-lactic acid (LA) has historically been thought to trigger gout by raising uric acid levels, but recent findings show it might actually suppress crystal formation at higher concentrations before promoting it.
- The study introduces a new mechanism called "tailored-made occupancy (TMO)" to better understand how LA influences the formation and growth of gout-related crystals.
Article Abstract
A gout attack could be viewed as a nucleation event. Many reports have shown that the typical molecular structure of crystallization inhibitors usually contains carboxyl and hydroxyl groups, which could interact with solute molecules through hydrogen bonding, thereby suppressing the nucleation and growth of crystals. Since 1923, l-lactic acid (LA), a molecule with structural features of inhibitors, has been speculated to be a trigger for acute gout because metabolized LA temporarily reduces uric acid excretion and leads to a slow increase in serum uric acid concentration. However, many cases of gout presumably triggered by elevated lactate in a very short period of 4 h are often inexplicable. Here, we present the unexpected result that LA has a significant "opposite effect" on the nucleation and growth of gouty pathological crystals, which is that as the concentration of the additive LA increases, the nucleation and growth of the crystals is suppressed and then facilitated. This approach may help our clarifying the long-standing "misunderstandings" and further understanding the association between metabolized LA and increased risk of gout attacks. Finally, a novel mechanism called "tailed-made occupancy (TMO)" was used to explain the nucleation and crystallization effects of LA on sodium urate monohydrate (MSUM).
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| http://dx.doi.org/10.1016/j.colsurfb.2024.113913 | DOI Listing |
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