Error Estimates for Calculated Glomerular Filtration Rates
Glomerular filtration rate (GFR) is a measure of
kidney function. It is usually estimated from serum concentrations of
cystatin C or creatinine although there has been considerable debate
in the literature about (i) the best equation to use and (ii) the
variability in the correlation between the concentrations of creatinine
and cystatin C. The equations for GFR can be written in a general
form and from these I calculate the error of the GFR estimates
associated with analyte measurement error. These show that the
error of the GFR estimates is such that it is not possible to distinguish
between the equations over much of the concentration range of either
analyte. The general forms of the equations are also used to derive
an expression for the concentration of cystatin C as a function of the
concentration of creatinine. This equation shows that these analyte
concentrations are not linearly related. Clinical reports of cystatin C
and creatinine concentration are consistent with the expression
derived.
[1] D. W. Cockcroft and M. H. Gault, "Prediction of creatinine clearance
from serum creatinine," Nephron, vol. 16, pp. 31-41, 1976.
[2] G. Filler and N. Lepage, "Should the Schwartz formula for estimation of
GFR be replaced by cystatin C formula?," Pediatric Nephrology, vol. 18,
pp. 981-985, 2003.
[3] F. J. Hoek, F. A. W. Kemperman, and R. T. K. Krediet, "A comparison
between cystatin C, plasma creatinine and the Cockcroft and Gault
formula for the estimation of glomerular filtration rate," Nephrology
Dialysis Transplantation, vol. 18, pp. 2024-2031, 2003.
[4] A. S. Levey, J. P. Bosch, J. B. Lewis, T. Greene, N. Rogers, and D.
Roth, "A more accurate method to estimate glomerular filtration rate
from serum creatinine: a new prediction equation.," Annals of Internal
Medicine, vol. 130, pp. 461-470, 1999.
[5] A. Larsson, J. Malm, A. Grubb, and L.-O. Hansson, "Calculation of
glomerular filtration rate expressed in mL/min from plasma cystatin C
values in mg/L," Scandinavian Journal of Clinical and Laboratory
Investigation, vol. 64, pp. 25-30, 2004.
[6] A. S. Levey, T. Greene, G. J. Beck, and M. S. Group, "A simplified
equation to predict glomerular filtration rate from serum creatinine,"
Journal of the American Society of Nephrology, vol. 11, pp. A0828,
2000.
[7] L. A. Stevens, J. Coresh, T. Greene, and A. S. Levey, "Assessing kidney
function - measured and estimated glomerular filtration rate," New
England Journal of Medicine, vol. 354, pp. 2473-2483, 2006.
[8] R. W. Jelliffe and S. M. Jelliffe, "A computer program for estimation of
creatinine clearance from unstable serum creatinine levels, age, sex, and
weight," Mathematical Biosciences, vol. 14, pp. 17-24, 1972.
[9] T. Le Bricon, E. Thervet, M. Froissart, M. Benlakehal, C. Legendre, and
D. Erlich, "Plasma cystatin C is superior to 24-h creatinine clearance and
plasma creatinine for estimation of glomerular filtration rate 3 months
after kidney transplantation," Clinical Chemistry, vol. 46, pp. 1206-
1207, 2000.
[10] D. DuBois and E. F. DuBois, "A formula to estimate the approximate
surface area if height and weight are known," Archives of Internal
Medicine, vol. 17, pp. 863-871, 1916.
[11] R. W. Jelliffe, "Creatinine clearance: bedside estimate," Annals of
Internal Medicine, vol. 79, pp. 604-605, 1973.
[12] A. D. Rule, E. J. Bergstralh, J. M. Slezak, J. Bergert, and T. S. Larson,
"Glomerular filtration rate estimated by cystatin C among different
clinical presentations," Kidney International, vol. 69, pp. 399-405, 2006.
[13] D. E. Salazar and G. B. Corcoran, "Predicting creatinine clearance and
renal drug clearance in obese patients from estimated fat-free body
mass," American Journal of Medicine, vol. 84, pp. 1053-1060, 1988.
[14] G. L. Barbour, C. K. Crumb, C. M. Boyd, R. D. Reeves, S. P. Rastogi,
and R. M. Patterson, "Comparison of inulin, iothalamate, and 99mTc-
DTPA for measurement of glomerular filtration rate," Journal of Nuclear
Medicine, vol. 17, pp. 317-320, 1976.
[15] C. Lempert, "The chemistry of glycoamidines," Chemical Reviews, vol.
59, pp. 667-736, 1959.
[16] M. Wyss and I. Kaddurah-Daouk, "Creatine and creatinine metabolism,"
Physiological Reviews, vol. 80, pp. 1107-1213, 2000.
[17] A. C. Baxmann, M. S. Ahmed, N. C. Marques, V. B. Menon, A. B.
Pereira, G. M. Kirsztajn, and I. P. Heilberg, "Influence of muscle mass
and physical activity on serum and urinary creatinine and serum cystatin
C," Clinical Journal of the American Society of Nephrology, vol. 3, pp.
348-354, 2008.
[18] M. H. Kroll, L. Nealon, M. A. Vogel, and R. J. Elin, "How certain drugs
interfere negatively with the Jaffé reaction for creatinine," Clinical
Chemistry, vol. 31, pp. 306-308, 1985.
[19] O. Shemesh, H. Golbetz, J. P. Kriss, and B. D. Myers, "Limitations of
creatinine as a filtration marker in glomerulopathic patients," Kidney
International, vol. 28, pp. 830-838, 1985.
[20] R. D. Perrone, N. E. Madias, and A. S. Levey, "Serum creatinine as an
index of renal function: new insights into old concepts," Clinical
Chemistry, vol. 38, pp. 1933-1953, 1992.
[21] R. Swaminathan, P. Major, H. Snieder, and T. Spector, "Serum
creatinine and fat-free mass (lean body mass)," Clinical Chemistry, vol.
46, pp. 1695-1696, 2000.
[22] B. G. Keevil, E. S. Kilpatrick, S. P. Nichols, and P. W. Maylor,
"Biological variation of cystatin C: implications for the assessment of
glomerular filtration rate," Clinical Chemistry, vol. 44, pp. 1535-1539,
1998.
[23] G. Filler, F. Priem, I. Vollmer, J. Gellermann, and K. Jung, "Diagnostic
sensitivity of serum cystatin for impaired glomerular filtration rate,"
Pediatric Nephrology, vol. 13, pp. 501-505, 1999.
[24] A. G. Christensson, A. O. Grubb, J.-Å. Nilsson, K. Norrgren, G. Sterner,
and G. Sundkvist, "Serum cystatin C advantageous compared with serum
creatinine in the detection of mild but not severe diabetic nephropathy,"
Journal of Internal Medicine, vol. 256, pp. 510-518, 2004.
[25] D. Groesbeck, A. Köttgen, R. Parekh, E. Selvin, G. J. Schwartz, J.
Coresh, and S. Furth, "Age, gender, and race effects on cystatin C levels
in US adolescents," Clinical Journal of the American Society of
Nephrology, vol. 3, pp. 1777-1785, 2008.
[26] M. Yashiro, T. Kamata, H. Segawa, Y. Kadoya, T. Murakami, and E.
Muso, "Comparisons of cystatin C with creatinine for evaluation of renal
function in chronic kidney disease," Clinical and Experimental
Nephrology, vol. 13, pp. 598-604, 2009.
[27] J. Stoves, E. J. Lindley, M. C. Barnfield, M. T. Burniston, and C. G.
Newstead, "MDRD equation estimates of glomerular filtration rate in
potential living kidney donors and renal transplant recipients with
impaired graft function," Nephrology Dialysis Transplantation, vol. 17,
pp. 2036-2037, 2002.
[28] J. Lin, E. L. Knight, M. L. Hogan, and A. K. Singh, "A comparison of
prediction equations for estimating glomerular filtration rate in adults
without kidney disease," Journal of the American Society of Nephrology,
vol. 14, pp. 2573-2580, 2003.
[29] C. White, A. Akbari, N. Hussain, L. Dinh, G. Filler, N. Lepage, and G.
A. Knoll, "Estimating glomerular filtration rate in kidney
transplantation: a comparison between serum creatinine and cystatin Cbased
methods," Journal of the American Society of Nephrology, vol. 16,
pp. 3763-3770, 2005.
[30] J. S. Al Wakeel, D. Hammad, A. Al Suwaida, N. Tarif, A. Chaudhary, A.
Isnani, W. A. Albedaiwi, A. H. Mitwalli, and S. S. Ahmad, "Validation
of predictive equations for glomerular filtration rate in the Saudi
population," Saudi Journal of Kidney Diseases and Transplantation, vol.
20, pp. 1030-1037, 2009.
[31] S. Savaj, T. Shoushtarizadeh, M. A. Abbai, S. H. Razavimanesh, and A.
J. Ghods, "Estimation of glomerular filtration rate with creatinine-based
versus cystatin C-based equations in kidney transplant recipients,"
Iranian Journal of Kidney Disease, vol. 3, pp. 234-238, 2009.
[32] A. S. Levey, L. A. Stevens, C. H. Schmid, Y. Zhang, A. F. Castro, III, H.
I. Feldman, J. W. Kusek, P. Eggers, F. Van Lente, T. Greene, and J.
Coresh, "A new equation to estimate glomerular filtration rate," Annals
of Internal Medicine, vol. 150, pp. 604-612, 2009.
[33] S. Brown, "Re: Estimation of glomerular filtration rate with creatininebased
versus cystatin C-based equations in kidney transplant recipients,"
Iranian Journal of Kidney Disease, vol. 4, pp. 169-170, 2010.
[34] J. R. Taylor, An introduction to error analysis. The study of
uncertainties in physical measurements, 2nd ed. Sausalito: University
Science Books, 1997.
[35] V. Menon, M. G. Shlipak, X. Wang, J. Coresh, T. Greene, L. Stevens, J.
W. Kusek, G. J. Beck, A. J. Collins, A. S. Levey, and M. J. Sarnak,
"Cystatin C as a risk factor for outcomes in chronic kidney disease,"
Annals of Internal Medicine, vol. 147, pp. 19-27, 2007.
[36] D. J. Newman, H. Thakkar, R. G. Edwards, M. Wilkie, T. White, A. O.
Grubb, and C. P. Price, "Serum cystatin C measured by automated
immunoassay: a more sensitive marker of changes in GFR than serum
creatinine," Kidney International, vol. 47, pp. 312-318, 1995.
[37] H. Li, G. Xu, X. Wang, X. Zhang, and J. Yanh, "Diagnostic accuracy of
various glomerular filtration rates estimating equations in patients with
chronic kidney disease and diabetes," Chinese Medical Journal, vol.
123, pp. 745-751, 2010.
[38] U. Pöge, B. Stoffel-Wagner, H. U. Klehr, T. Sauerbruch, and R. P.
Woitas, "Calculation of glomerular filtration rate based on cystatin C in
cirrhotic patients," Nephrology Dialysis Transplantation, vol. 21, pp.
660-664, 2006.
[39] L. K. van Rossum, R. Zietse, A. G. Vulto, and Y. B. de Rijke, "Renal
extraction of cystatin C vs 125I-iothalamate in hypertensive patients,"
Nephrology Dialysis Transplantation, vol. 21, pp. 1253-1256, 2006.
[40] H. Stowe, D. Lawrence, D. J. Newman, and E. J. Lamb, "Analytical
performance of a particle-enhanced nephelometric immunoassay for
serum cystatin C using rate analysis," Clinical Chemistry, vol. 47, pp.
1482-1485, 2001.
[41] R. H. Laessig, S. S. Ehrmeyer, and J. E. Leinweber, "Intralaboratory
performance requirements necessary to pass proficiency testing: CAP-
1990 vs CLIA-1867 (March 14, 1990) formats compared," Clinical
Chemistry, vol. 38, pp. 895-903, 1992.
[42] M. A. McDowell, C. D. Fryar, C. L. Ogden, and K. M. Flegal,
"Anthropometric reference data for children and adults: United States,
2003-2006," National Center for Health Statistics, Hyattsville 10, 2008.
[43] F. Ceriotti, J. C. Boyd, G. Klein, J. Henny, J. Queralt├│, V. Kairisto, and
M. Panteghini, "Reference intervals for serum creatinine concentrations:
assessment of available data for global application," Clinical Chemistry,
vol. 54, pp. 559-566, 2008.
[44] M. Peake and M. Whiting, "Measurement of serum creatinine - current
status and future goals," Clinical Biochemistry Reviews, vol. 27, pp. 173-
184, 2007.
[45] R. Botev, J.-P. Mallié, C. Couchoud, O. Sch├╝ck, J.-P. Fauvel, J. F. M.
Wetzels, N. Lee, N. G. De Santo, and M. Cirillo, "Estimating glomerular
filtration rate: Cockcroft-Gault and modification of diet in renal disease
formulas compared to renal inulin clearance," Clinical Journal of the
American Society of Nephrology, vol. 4, pp. 899-906, 2009.
[1] D. W. Cockcroft and M. H. Gault, "Prediction of creatinine clearance
from serum creatinine," Nephron, vol. 16, pp. 31-41, 1976.
[2] G. Filler and N. Lepage, "Should the Schwartz formula for estimation of
GFR be replaced by cystatin C formula?," Pediatric Nephrology, vol. 18,
pp. 981-985, 2003.
[3] F. J. Hoek, F. A. W. Kemperman, and R. T. K. Krediet, "A comparison
between cystatin C, plasma creatinine and the Cockcroft and Gault
formula for the estimation of glomerular filtration rate," Nephrology
Dialysis Transplantation, vol. 18, pp. 2024-2031, 2003.
[4] A. S. Levey, J. P. Bosch, J. B. Lewis, T. Greene, N. Rogers, and D.
Roth, "A more accurate method to estimate glomerular filtration rate
from serum creatinine: a new prediction equation.," Annals of Internal
Medicine, vol. 130, pp. 461-470, 1999.
[5] A. Larsson, J. Malm, A. Grubb, and L.-O. Hansson, "Calculation of
glomerular filtration rate expressed in mL/min from plasma cystatin C
values in mg/L," Scandinavian Journal of Clinical and Laboratory
Investigation, vol. 64, pp. 25-30, 2004.
[6] A. S. Levey, T. Greene, G. J. Beck, and M. S. Group, "A simplified
equation to predict glomerular filtration rate from serum creatinine,"
Journal of the American Society of Nephrology, vol. 11, pp. A0828,
2000.
[7] L. A. Stevens, J. Coresh, T. Greene, and A. S. Levey, "Assessing kidney
function - measured and estimated glomerular filtration rate," New
England Journal of Medicine, vol. 354, pp. 2473-2483, 2006.
[8] R. W. Jelliffe and S. M. Jelliffe, "A computer program for estimation of
creatinine clearance from unstable serum creatinine levels, age, sex, and
weight," Mathematical Biosciences, vol. 14, pp. 17-24, 1972.
[9] T. Le Bricon, E. Thervet, M. Froissart, M. Benlakehal, C. Legendre, and
D. Erlich, "Plasma cystatin C is superior to 24-h creatinine clearance and
plasma creatinine for estimation of glomerular filtration rate 3 months
after kidney transplantation," Clinical Chemistry, vol. 46, pp. 1206-
1207, 2000.
[10] D. DuBois and E. F. DuBois, "A formula to estimate the approximate
surface area if height and weight are known," Archives of Internal
Medicine, vol. 17, pp. 863-871, 1916.
[11] R. W. Jelliffe, "Creatinine clearance: bedside estimate," Annals of
Internal Medicine, vol. 79, pp. 604-605, 1973.
[12] A. D. Rule, E. J. Bergstralh, J. M. Slezak, J. Bergert, and T. S. Larson,
"Glomerular filtration rate estimated by cystatin C among different
clinical presentations," Kidney International, vol. 69, pp. 399-405, 2006.
[13] D. E. Salazar and G. B. Corcoran, "Predicting creatinine clearance and
renal drug clearance in obese patients from estimated fat-free body
mass," American Journal of Medicine, vol. 84, pp. 1053-1060, 1988.
[14] G. L. Barbour, C. K. Crumb, C. M. Boyd, R. D. Reeves, S. P. Rastogi,
and R. M. Patterson, "Comparison of inulin, iothalamate, and 99mTc-
DTPA for measurement of glomerular filtration rate," Journal of Nuclear
Medicine, vol. 17, pp. 317-320, 1976.
[15] C. Lempert, "The chemistry of glycoamidines," Chemical Reviews, vol.
59, pp. 667-736, 1959.
[16] M. Wyss and I. Kaddurah-Daouk, "Creatine and creatinine metabolism,"
Physiological Reviews, vol. 80, pp. 1107-1213, 2000.
[17] A. C. Baxmann, M. S. Ahmed, N. C. Marques, V. B. Menon, A. B.
Pereira, G. M. Kirsztajn, and I. P. Heilberg, "Influence of muscle mass
and physical activity on serum and urinary creatinine and serum cystatin
C," Clinical Journal of the American Society of Nephrology, vol. 3, pp.
348-354, 2008.
[18] M. H. Kroll, L. Nealon, M. A. Vogel, and R. J. Elin, "How certain drugs
interfere negatively with the Jaffé reaction for creatinine," Clinical
Chemistry, vol. 31, pp. 306-308, 1985.
[19] O. Shemesh, H. Golbetz, J. P. Kriss, and B. D. Myers, "Limitations of
creatinine as a filtration marker in glomerulopathic patients," Kidney
International, vol. 28, pp. 830-838, 1985.
[20] R. D. Perrone, N. E. Madias, and A. S. Levey, "Serum creatinine as an
index of renal function: new insights into old concepts," Clinical
Chemistry, vol. 38, pp. 1933-1953, 1992.
[21] R. Swaminathan, P. Major, H. Snieder, and T. Spector, "Serum
creatinine and fat-free mass (lean body mass)," Clinical Chemistry, vol.
46, pp. 1695-1696, 2000.
[22] B. G. Keevil, E. S. Kilpatrick, S. P. Nichols, and P. W. Maylor,
"Biological variation of cystatin C: implications for the assessment of
glomerular filtration rate," Clinical Chemistry, vol. 44, pp. 1535-1539,
1998.
[23] G. Filler, F. Priem, I. Vollmer, J. Gellermann, and K. Jung, "Diagnostic
sensitivity of serum cystatin for impaired glomerular filtration rate,"
Pediatric Nephrology, vol. 13, pp. 501-505, 1999.
[24] A. G. Christensson, A. O. Grubb, J.-Å. Nilsson, K. Norrgren, G. Sterner,
and G. Sundkvist, "Serum cystatin C advantageous compared with serum
creatinine in the detection of mild but not severe diabetic nephropathy,"
Journal of Internal Medicine, vol. 256, pp. 510-518, 2004.
[25] D. Groesbeck, A. Köttgen, R. Parekh, E. Selvin, G. J. Schwartz, J.
Coresh, and S. Furth, "Age, gender, and race effects on cystatin C levels
in US adolescents," Clinical Journal of the American Society of
Nephrology, vol. 3, pp. 1777-1785, 2008.
[26] M. Yashiro, T. Kamata, H. Segawa, Y. Kadoya, T. Murakami, and E.
Muso, "Comparisons of cystatin C with creatinine for evaluation of renal
function in chronic kidney disease," Clinical and Experimental
Nephrology, vol. 13, pp. 598-604, 2009.
[27] J. Stoves, E. J. Lindley, M. C. Barnfield, M. T. Burniston, and C. G.
Newstead, "MDRD equation estimates of glomerular filtration rate in
potential living kidney donors and renal transplant recipients with
impaired graft function," Nephrology Dialysis Transplantation, vol. 17,
pp. 2036-2037, 2002.
[28] J. Lin, E. L. Knight, M. L. Hogan, and A. K. Singh, "A comparison of
prediction equations for estimating glomerular filtration rate in adults
without kidney disease," Journal of the American Society of Nephrology,
vol. 14, pp. 2573-2580, 2003.
[29] C. White, A. Akbari, N. Hussain, L. Dinh, G. Filler, N. Lepage, and G.
A. Knoll, "Estimating glomerular filtration rate in kidney
transplantation: a comparison between serum creatinine and cystatin Cbased
methods," Journal of the American Society of Nephrology, vol. 16,
pp. 3763-3770, 2005.
[30] J. S. Al Wakeel, D. Hammad, A. Al Suwaida, N. Tarif, A. Chaudhary, A.
Isnani, W. A. Albedaiwi, A. H. Mitwalli, and S. S. Ahmad, "Validation
of predictive equations for glomerular filtration rate in the Saudi
population," Saudi Journal of Kidney Diseases and Transplantation, vol.
20, pp. 1030-1037, 2009.
[31] S. Savaj, T. Shoushtarizadeh, M. A. Abbai, S. H. Razavimanesh, and A.
J. Ghods, "Estimation of glomerular filtration rate with creatinine-based
versus cystatin C-based equations in kidney transplant recipients,"
Iranian Journal of Kidney Disease, vol. 3, pp. 234-238, 2009.
[32] A. S. Levey, L. A. Stevens, C. H. Schmid, Y. Zhang, A. F. Castro, III, H.
I. Feldman, J. W. Kusek, P. Eggers, F. Van Lente, T. Greene, and J.
Coresh, "A new equation to estimate glomerular filtration rate," Annals
of Internal Medicine, vol. 150, pp. 604-612, 2009.
[33] S. Brown, "Re: Estimation of glomerular filtration rate with creatininebased
versus cystatin C-based equations in kidney transplant recipients,"
Iranian Journal of Kidney Disease, vol. 4, pp. 169-170, 2010.
[34] J. R. Taylor, An introduction to error analysis. The study of
uncertainties in physical measurements, 2nd ed. Sausalito: University
Science Books, 1997.
[35] V. Menon, M. G. Shlipak, X. Wang, J. Coresh, T. Greene, L. Stevens, J.
W. Kusek, G. J. Beck, A. J. Collins, A. S. Levey, and M. J. Sarnak,
"Cystatin C as a risk factor for outcomes in chronic kidney disease,"
Annals of Internal Medicine, vol. 147, pp. 19-27, 2007.
[36] D. J. Newman, H. Thakkar, R. G. Edwards, M. Wilkie, T. White, A. O.
Grubb, and C. P. Price, "Serum cystatin C measured by automated
immunoassay: a more sensitive marker of changes in GFR than serum
creatinine," Kidney International, vol. 47, pp. 312-318, 1995.
[37] H. Li, G. Xu, X. Wang, X. Zhang, and J. Yanh, "Diagnostic accuracy of
various glomerular filtration rates estimating equations in patients with
chronic kidney disease and diabetes," Chinese Medical Journal, vol.
123, pp. 745-751, 2010.
[38] U. Pöge, B. Stoffel-Wagner, H. U. Klehr, T. Sauerbruch, and R. P.
Woitas, "Calculation of glomerular filtration rate based on cystatin C in
cirrhotic patients," Nephrology Dialysis Transplantation, vol. 21, pp.
660-664, 2006.
[39] L. K. van Rossum, R. Zietse, A. G. Vulto, and Y. B. de Rijke, "Renal
extraction of cystatin C vs 125I-iothalamate in hypertensive patients,"
Nephrology Dialysis Transplantation, vol. 21, pp. 1253-1256, 2006.
[40] H. Stowe, D. Lawrence, D. J. Newman, and E. J. Lamb, "Analytical
performance of a particle-enhanced nephelometric immunoassay for
serum cystatin C using rate analysis," Clinical Chemistry, vol. 47, pp.
1482-1485, 2001.
[41] R. H. Laessig, S. S. Ehrmeyer, and J. E. Leinweber, "Intralaboratory
performance requirements necessary to pass proficiency testing: CAP-
1990 vs CLIA-1867 (March 14, 1990) formats compared," Clinical
Chemistry, vol. 38, pp. 895-903, 1992.
[42] M. A. McDowell, C. D. Fryar, C. L. Ogden, and K. M. Flegal,
"Anthropometric reference data for children and adults: United States,
2003-2006," National Center for Health Statistics, Hyattsville 10, 2008.
[43] F. Ceriotti, J. C. Boyd, G. Klein, J. Henny, J. Queralt├│, V. Kairisto, and
M. Panteghini, "Reference intervals for serum creatinine concentrations:
assessment of available data for global application," Clinical Chemistry,
vol. 54, pp. 559-566, 2008.
[44] M. Peake and M. Whiting, "Measurement of serum creatinine - current
status and future goals," Clinical Biochemistry Reviews, vol. 27, pp. 173-
184, 2007.
[45] R. Botev, J.-P. Mallié, C. Couchoud, O. Sch├╝ck, J.-P. Fauvel, J. F. M.
Wetzels, N. Lee, N. G. De Santo, and M. Cirillo, "Estimating glomerular
filtration rate: Cockcroft-Gault and modification of diet in renal disease
formulas compared to renal inulin clearance," Clinical Journal of the
American Society of Nephrology, vol. 4, pp. 899-906, 2009.
@article{"International Journal of Medical, Medicine and Health Sciences:56510", author = "Simon Brown", title = "Error Estimates for Calculated Glomerular Filtration Rates", abstract = "Glomerular filtration rate (GFR) is a measure of
kidney function. It is usually estimated from serum concentrations of
cystatin C or creatinine although there has been considerable debate
in the literature about (i) the best equation to use and (ii) the
variability in the correlation between the concentrations of creatinine
and cystatin C. The equations for GFR can be written in a general
form and from these I calculate the error of the GFR estimates
associated with analyte measurement error. These show that the
error of the GFR estimates is such that it is not possible to distinguish
between the equations over much of the concentration range of either
analyte. The general forms of the equations are also used to derive
an expression for the concentration of cystatin C as a function of the
concentration of creatinine. This equation shows that these analyte
concentrations are not linearly related. Clinical reports of cystatin C
and creatinine concentration are consistent with the expression
derived.", keywords = "creatinine, cystatin C, error analysis, glomerularfiltration rate, measurement error.", volume = "5", number = "9", pages = "427-6", }
