Skip to main content
Key Specialties
Cardiology Diabetology Endocrinology Gastroenterology Geriatrics and Gerontology Gynecology and Obstetrics Hematology Infectious Disease Internal Medicine Nephrology Neurology Oncology Pediatrics Respiratory Medicine Rheumatology Surgery
Congress Coverage
2024 ACC Congress 2023 ESMO Congress 2023 EASD Congress 2023 ERS Congress 2023 ESC Congress
Clinical Collections
Advances in Alzheimer’s

At a glance: The STEP trials

A round-up of the STEP phase 3 clinical trials evaluating semaglutide for weight loss in people with overweight or obesity.
ADVANCED SEARCH
Log in
Top
Urolithiasis
Published in: Urolithiasis 3/2020

01-06-2020 | Urinalysis | Original Paper

Predicting the risk of kidney stone formation in the nephron by ‘reverse engineering’

Authors: Michael G. Hill, Erich Königsberger, Peter M. May

Published in: Urolithiasis | Issue 3/2020

Login to get access

Abstract

Although most kidney stones are found in the calyx, they are usually initiated upstream in the nephron by precipitation there of certain incipient mineral phases. The risk of kidney stone formation can thus be indicated by changes in the degree of saturation of these minerals in the nephron fluid. To this end, relevant concentration profiles in the fluid along the nephron have been calculated by starting with specified urine compositions and imposing constraints from the corresponding, much less variable, blood compositions. A model for supersaturation within ten sections of both long and short nephrons has accordingly been developed based on this ‘reverse engineering’ of the necessary substance concentrations coupled with chemical speciation distributions calculated by our Joint Expert Speciation System (JESS). This allows the likelihood of precipitation to be assessed based on Ostwald’s ‘Rule of Stages’. Differences between normal and stone-former profiles have been used to identify sections in the nephron where conditions seem most likely to induce heterogeneous nucleation.
Appendix
Available only for authorised users
Literature
1.
Grases F, Costa-Bauzá A, Garcia-Ferragut L (1998) Biopathological crystallization: a general view about the mechanisms of renal stone formation. Adv Colloid Interface Sci 74:169–194CrossRef
2.
Kallidonis P, Liourdi D, Liatsikos E (2011) Medical treatment for renal colic and stone expulsion. Eur Urol Suppl 10:415–422CrossRef
3.
4.
Hill MG, Königsberger E, May PM (2017) Mineral precipitation and dissolution in the kidney. Am Mineral 102:701–710CrossRef
5.
Tiselius HG (1982) An improved method for the routine biochemical evaluation of patients with recurrent calcium oxalate stone disease. Clin Chim Acta 122:409–418CrossRef
6.
Milosevic D, Batinic D, Konjevoda NBP, Stambuk N, Votava- Raic A, Fumic VBK, Rumenjak V, Stavljenic-Rukavina A, Nizic L, Vrljicak K (1998) Determination of urine supersaturation with computer program Equil 2 as a method for estimation of the risk of urolithiasis. J Chem Inf Comput Sci 38:646–650CrossRef
7.
Laube N, Schneider A, Hesse A (2000) A new approach to calculate the risk of calcium oxalate crystallization from unprepared native urine. Urol Res 28:274–280CrossRef
8.
Hill MG (2019) A chemical model to investigate the risk of kidney stone formation in humans in terms of urinary supersaturation. PhD thesis, Murdoch University
9.
Rodgers AL, Allie-Hamdulay S, Jackson G, Tiselius HG (2011) Simulating calcium salt precipitation in the nephron using chemical speciation. Urol Res 39:245–251CrossRef
10.
Robertson WG (2015) Potential role of fluctuations in the composition of renal tubular fluid through the nephron in the initiation of Randall’s plugs and calcium oxalate crystalluria in a computer model of renal function. Urolithiasis 43(Supplement 1):S93–S107CrossRef
11.
Tiselius H, Lindbäck B, Fornander AM, Nilsson MA (2009) Studies on the role of calcium phosphate in the process of calcium oxalate crystal formation. Urol Res 37:181–192CrossRef
12.
Højgaard I, Tiselius HG (1999) Crystallization in the nephron. Urol Res 27:397–403CrossRef
13.
Tiselius HG (1997) Estimated levels of supersaturation with calcium phosphate and calcium oxalate in the distal tubule. Urol Res 25:153–159CrossRef
14.
Kok DJ (1997) Intratubular crystallization events. World J Urol 15:219–228CrossRef
15.
Söhnel O, Grases F (1995) Calcium oxalate monohydrate renal calculi. Formation and development mechanism. Adv Colloid Interface Sci 59:1–17CrossRef
16.
Grases F, Costa-Bauzá A, Gomila I, Ramis M, García-Raja A, Prieto RM (2012) Urinary pH and renal lithiasis. Urol Res 40:41–46CrossRef
17.
Robertson WG, Scurr DS, Bridge CM (1981) Factors influencing the crystallisation of calcium oxalate in urine–critique. J Cryst Growth 53:182–194CrossRef
18.
Tiselius HG (2011) A hypothesis of calcium stone formation: an interpretation of stone research during the past decades. Urol Res 39:231–243CrossRef
19.
Rodgers A, Webber D, Hibberd B (2015) Experimental determination of multiple thermodynamic and kinetic factors for nephrolithiasis in the urine of healthy controls and calcium oxalate stone formers: does a universal discriminator exist? Urolithiasis 43:479–487CrossRef
20.
Coe FL, Evan A, Worcester E (2011) Pathophysiology-based treatment of idiopathic calcium kidney stones. Clin J Am Soc Nephrol 6:2083–2092CrossRef
21.
Baumann JN, Affolter B (2014) From crystaluria to kidney stones, some physicochemical aspects of calcium nephrolithiasis. World J Nephrol 3:256–267CrossRef
22.
Söhnel O, Grases F (2011) Supersaturation of body fluids, plasma and urine, with respect to biological hydroxyapatite. Urol Res 39:429–436CrossRef
23.
Asplin JR, Mandel NS, Coe FL (1996) Evidence for calcium phosphate supersaturation in the loop of Henle. Am J Physiol 270:F604–F613PubMed
24.
Luptak J, Bek-Jensen H, Fornander AM, Højgaard I, Nilsson MA, Tiselius H (1994) Crystallization of calcium oxalate and calcium phosphate at superstauration levels corresponding to those in different parts of the nephron. Scan Microsc 8:47–62
25.
Grases F, Villacampa AI, Söhnel O, Königsberger E, May PM (1997) Phosphate composition of precipitates from urine-like liquors. Cryst Res Technol 32:707–715CrossRef
26.
Johnsson MSA, Nancollas GH (1992) The role of brushite and octacalcium phosphate in apatite formation. Crit Rev Oral Biol Med 3:61–82CrossRef
27.
Pak CYC (1969) Physicochemical basis for formation of renal stones of calcium phosphate origin: calculation of the degree of saturation of urine with respect to brushite. J Clin Investig 48:1914–1922CrossRef
28.
Pak CYC (1981) Potential etiologic role of brushite in the formation of calcium (renal) stones. J Cryst Growth 53:202–208CrossRef
29.
Pak CYC, Rodgers K, Poindexter JR, Sakhaee K (2008) New methods of assessing crystal growth and saturation of brushite in whole urine: effect of pH, calcium and citrate. J Urol 180:1532–1537CrossRef
30.
Coe FL, Parks JH, Nakagawa Y (1992) Inhibitors and promoters of calcium oxalate crystallization. their relationship to the pathogenesis and treatment of nephrolithiasis. In: Coe FL, Favus MJ (eds) Disorders of bone and mineral metabolism, vol 35. Raven Press Ltd, New York, pp 757–799
31.
Rabadjieva D, Tepavitcharova S, Sezanova K, Gergulova R (2016) Chemical equilibria modeling of calcium phosphate precipitation and transformation in simulated physiological solutions. J Solut Chem 45:1620–1633CrossRef
32.
Sawada K (1997) The mechanisms of crystallization and transformation of calcium carbonates. Pure Appl Chem 69:921–928CrossRef
33.
Zhang J, Wang L, Putnis C (2019) Underlying role of brushite in pathological mineralization of hydroxyapatite. J Phys Chem B 123:2874–2881CrossRef
34.
Atherton JC (2006) Function of the nephron and the formation of urine. Anaesth Intensive Care Med 7:221–226CrossRef
35.
Good DW, Knepper MA (1985) Ammonia transport in the mammalian kidney. Am J Physiol 248:F459–F471PubMed
36.
May PM, Murray K (1991) JESS, a Joint Expert Speciation System—I. Raison d’être. Talanta 38:1409–1417CrossRef
37.
May PM, Murray K (1991) JESS, a Joint Expert Speciation System—II. The thermodynamic database. Talanta 38:1419–1426CrossRef
38.
May PM (2015) JESS at thirty: strengths, weaknesses and future needs in the modelling of chemical speciation. Appl Geochem 55:3–16CrossRef
39.
May PM, Rowland D (2018) JESS, a Joint Expert Speciation System—VI: thermodynamically-consistent standard Gibbs energies of reaction for aqueous solutions. N J Chem 42:7617–7629CrossRef
40.
Cavan D, Hovorka R, Hejlesen O, Andreassen S, Sonksen P (1996) Use of the DIAS model to predict unrecognised hypoglycaemia in patients with insulin dependent diabetes. Comput Methods Prog Biomed 50:241–246CrossRef
41.
Metadata
Title
Predicting the risk of kidney stone formation in the nephron by ‘reverse engineering’
Authors
Michael G. Hill
Erich Königsberger
Peter M. May
Publication date
01-06-2020
Publisher
Springer Berlin Heidelberg
Keyword
Urinalysis
Published in
Urolithiasis / Issue 3/2020
Print ISSN: 2194-7228
Electronic ISSN: 2194-7236
DOI
https://doi.org/10.1007/s00240-019-01172-8

Other articles of this Issue 3/2020

Urolithiasis 3/2020 Go to the issue

Original Paper

The impact of urinary stone disease and their treatment on patients’ quality of life: a qualitative study

Original Paper

Evaluation of day-care versus inpatient mini-percutaneous nephrolithotomy: a propensity score-matching study

Original Paper

Kidney volume loss following percutaneous nephrolithotomy utilizing 3D planimetry

Editorial

Effective and quick discharge of residual fragments after minimal invasive stone procedures with “EPVL” modality: a new and promising approach

Original Paper

Ultrasound-guided low thoracic paravertebral block versus peritubal infiltration for percutaneous nephrolithotomy: a prospective randomized study

Original Paper

Role of pelvicalyceal anatomy in the outcomes of retrograde intrarenal surgery (RIRS) for lower pole stones: outcomes with a systematic review of literature