# Cystine Renal Calculi: New Aspects Related to Their Formation and Development

**Authors:** Felix Grases, Francisca Tomàs Nadal, Francesca Julià Florit, Antonia Costa-Bauza

PMC · DOI: 10.3390/jcm13102837 · 2024-05-11

## TL;DR

This paper explores how cystine kidney stones form and how certain agents can prevent their crystallization, offering insights into prevention strategies.

## Contribution

The study identifies N-acetylcysteine as the most effective cystine-binding thiol agent in preventing cystine crystallization.

## Key findings

- N-acetylcysteine delays cystine crystallization and modifies crystal morphology.
- Cystine stones start from a few crystals forming a compact radial structure.
- High supersaturation is a key factor in cystine stone formation.

## Abstract

Background: Crystallization experiments of renal-calculi-forming compounds (calcium oxalate, calcium phosphates, uric acid) are normally performed by monitoring these processes during periods of time similar to the residence of urine inside the kidney. Nevertheless, cystine requires high supersaturation for its crystallization, and most experiments last for longer periods. It must be considered that at high supersaturation, the inhibitors of crystalline development have poor effects. Methods: The induction time of crystallization (ti) of cystine in experimental conditions similar to those of the formation of cystine renal calculi and the effect of different cystine-binding thiol agents was determined through turbidimetric measurements. We also studied the macro- and microstructure of 30 cystine kidney stones through stereoscopic microscopy and scanning electron microscopy. Results: Under the studied conditions, the ti in absence of crystallization inhibitors was 15 min, and the presence of 9 mM of penicillamine, tiopronin, or N-acetylcysteine totally inhibited crystallization, as their effects relate to the formation of complexes with cystine, although N-acetylcysteine also delayed cystine crystalline development and modified cystine crystal morphology. Cystine stones have traditionally been classified as smooth and rough. The study of their structure shows that all of them begin their formation from a few crystals that generate a compact radial structure. Their subsequent growth, depending on the renal cavity where they are located, gives rise to the rough structure in the form of large blocks of cystine crystals or the smooth structure with small crystals. Conclusions: To prevent the development of cystine renal stones, the formation of small crystals must be avoided by reducing urinary cystine supersaturation, with N-acetylcysteine being the most effective among the studied cystine-binding thiol agents. Also, the removal of cystine crystals through increased water intake and physical activity can be a very important preventive measure.

## Linked entities

- **Chemicals:** cystine (PubChem CID 67678), penicillamine (PubChem CID 4727), tiopronin (PubChem CID 5483), N-acetylcysteine (PubChem CID 12035)

## Full-text entities

- **Diseases:** Cystine stones (MESH:D003554), Cystine Renal Calculi (MESH:D007669)
- **Chemicals:** calcium oxalate (MESH:D002129), tiopronin (MESH:D008625), N-acetylcysteine (MESH:D000111), cystine (MESH:D003553), penicillamine (MESH:D010396), thiol (MESH:D013438), uric acid (MESH:D014527), calcium phosphates (MESH:D002130)

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC11122214/full.md

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Source: https://tomesphere.com/paper/PMC11122214