Kidney stone pathophysiology
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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief:
Overview
Pathophysiology
Pathogenesis
- It is understood that nephrolithiasis is the result of / is mediated by / is produced by / is caused by either [hypothesis 1], [hypothesis 2], or [hypothesis 3].
- [Pathogen name] is usually transmitted via the [transmission route] route to the human host.
- Following transmission/ingestion, the [pathogen] uses the [entry site] to invade the [cell name] cell.
- [Disease or malignancy name] arises from [cell name]s, which are [cell type] cells that are normally involved in [function of cells].
- The progression to [disease name] usually involves the [molecular pathway].
- The following table summarizes major mechanism of stone formation:[1][2][3][4]
Type of stone/Mechanism | Cause | Pathophysiology | Stone composition | Labs | |
---|---|---|---|---|---|
All stones | Low urine volume
(raises production of solutes) |
Reduced intake or increased loss of water | Renal water conservation | All stones |
|
Calcium stones | Hypercalciuria
(raises saturation of calcium salts) |
Absorptive hypercalciuria | Increased absorption in gut | Calcium oxalate or phosphate | Urine calcium concentrations >6 mmol/L (240 mg) per day |
Hyperparathyroidism | Increased absorption in gut and bone release | High concentrations of parathyroid hormone | |||
Immobilization | Bone resorption | High concentrations of vitamin D | |||
Excess of sodium in the diet | Sodium-induced physiological renal calcium leak. Possible component of gut hyperabsorption | Urine sodium concentrations >200 mmol/L per day | |||
Excess of protein or acid in diet | Protein-induced bone loss and renal leak. | ||||
Range of monogenic disorders | Bone loss, gut hyperabsorption, and renal leak in various combinations | ||||
Hypocitraturia
(raises levels of ionised calcium and reduces inhibitor activity against calcium salts) |
Renal tubular acidosis (distal type) | Renal defense of acid-base balance | Calcium phosphate |
| |
High acid load (absence of detectable acidemia) | Physiological hypocitraturia | Calcium oxalate or phosphate |
| ||
Hyperoxaluria
(raises saturation of calcium oxalate) |
Excess of oxalate in diet | Increased delivery of luminal oxalate | Calcium oxalate | Urine oxalate concentrations >70·7 mmol/L per day | |
Bowel pathology | Reduced formation of luminal calcium and calcium-oxalate complex | ||||
Increased production of endogenous oxalate | Primary hyperoxaluria (type 1 and type 2) | ||||
Hyperuricosuria
(sodium urate precipitation causes crystallization of calcium salts) |
High purine intake | Raised production and urinary excretion of sodium and urate |
| ||
Myeloproliferative diseases | |||||
Enzymatic defects | Urine uric acid concentrations >600 mg per day | ||||
Uricosuric drugs | Hypouricaemia | ||||
Genetic primary renal leak | Increased excretion of uric acid | ||||
Uric acid stones | Low urine pH or hyperuricosuria |
|
Titrates urate to poorly soluble uric acid | Uric acid | Urine pH <5·5 |
Cystine stones | Cystinuria | Congenital mutations of dibasic aminoacid transporter subunits rBAT and b0+AT | Renal leak of basic aminoacids | Cystine | Urine concentrations of cystine high (>150 μmol/mmol creatinine) |
Infection stones | Urinary tract infection | Urea-splitting organisms | Production of ammonium and bicarbonate from urea |
|
Genetics
- Nephrolithiasis can be passed on to following generations due to rare causes of hypercalciuria:
- Hereditary distal renal tubular acidosis
- Dent disease
- Bartter syndrome types III and IV
- Autosomal dominant hypocalcemic hypercalciuria
- Familial hypomagnesemia
Associated Conditions
Gross Pathology
- On gross pathology, the characteristic findings of nephrolithiasis are:
- Location = 80% unilateral, usually in calyces, pelvis or bladder
- Size=variable, 2-3 mm usually
- All stones contain an organic matrix of mucoprotein
- Shape:
- Struvite stone= staghorn calculus
-
Nephrolithiasis, Source: Wikimedia commons[5]
-
Staghorn shape of struvite stones, Source: Wikimedia commons[6]
-
Renal calculi, different shapes and sizes, Source: Wikimedia commons[7]
-
Kidney stone with a maximum dimension of 5mm, Source: Wikimedia commons[8]
Microscopic Pathology
- On microscopic histopathological analysis, the characteristic findings of nephrolithiasis are:
- Shapes of different stones/crystals are different:
- Cysteine= hexagonal
- Struvite= coffin lid shape
- Calcium oxalate= pyramid shape
- Calcium oxalate= dumbbell shape
- Uric acid= rectangular/rhomboidal
- Oxalate crystals are highlighted by polarized light
- Foreign body giant cells and macrophages are seen with the stones
- Shapes of different stones/crystals are different:
-
Type of stones. Light microscopy of urine crystals. (A) Hexagonal cystine crystal (200X); (B) coffin-lid shaped struvite crystals (200X); (C) pyramid-shaped calcium oxalate dehydrate crystals (200X); (D) dumbbell-shaped calcium oxalate monohydrate crystal (400X); (E) rectangular uric acid crystals (400X); and (F) rhomboidal uric acid crystals (400X).[9]
-
Deposits of oxalate with variable size and form; they occupy mainly distal tubules. The asterisks indicate proximal tubules, which usually do not contain these crystals, H&E seen with polarized light, X200[10]
-
Medullary interstitial urate crystal deposits in chronic nephropathy by urates as seen after Masson's trichome stain X400[11]
-
Calcium oxalate dihydrate crystals under Scanning Electron Micrograph (SEM) taken at 30 KV. Source: Wikimedia commons[12]
-
Density-dependent color scanning electron micrograph of kidney stone, Source: Wikimedia commons[13]
References
- ↑ Moe, Orson W (2006). "Kidney stones: pathophysiology and medical management". The Lancet. 367 (9507): 333–344. doi:10.1016/S0140-6736(06)68071-9. ISSN 0140-6736.
- ↑ Freitag, Jeffrey; Hruska, Keith (1983). "Pathophysiology of Nephrolithiasis": 523–553. doi:10.1007/978-1-4613-3524-5_16.
- ↑ Gambaro G, Fabris A, Abaterusso C, Cosaro A, Ceol M, Mezzabotta F, Torregrossa R, Tiralongo E, Del Prete D, D'Angelo A, Anglani F (May 2008). "Pathogenesis of nephrolithiasis: recent insight from cell biology and renal pathology". Clin Cases Miner Bone Metab. 5 (2): 107–9. PMID 22460990.
- ↑ Sakhaee, Khashayar (2009). "Recent advances in the pathophysiology of nephrolithiasis". Kidney International. 75 (6): 585–595. doi:10.1038/ki.2008.626. ISSN 0085-2538.
- ↑ By Amadalvarez - Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=46706235
- ↑ By H. Zell [GFDL (http://www.gnu.org/copyleft/fdl.html) or CC BY-SA 3.0 (https://creativecommons.org/licenses/by-sa/3.0)], from Wikimedia Commons
- ↑ By Jakupica - Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=45324355
- ↑ By RJHall - Own work, Public Domain, https://commons.wikimedia.org/w/index.php?curid=4070842
- ↑ Han H, Segal AM, Seifter JL, Dwyer JT (July 2015). "Nutritional Management of Kidney Stones (Nephrolithiasis)". Clin Nutr Res. 4 (3): 137–52. doi:10.7762/cnr.2015.4.3.137. PMC 4525130. PMID 26251832.
- ↑ http://kidneypathology.com/Imagenes/Diabetes/Oxalato.4.w.jpg
- ↑ http://www.kidneypathology.com/English_version/Diabetes_and_others.html
- ↑ By Kempf EK - Own work, CC BY-SA 3.0, https://commons.wikimedia.org/w/index.php?curid=18036112
- ↑ By Sergio Bertazzo - Own work, CC BY-SA 4.0, https://commons.wikimedia.org/w/index.php?curid=45316797