Prediction of renal function (GFR) from cystatin C and creatinine in children: Body cell mass increases accuracy of the estimate

Trine Borup Andersen; Lars Jødal; Martin Bøgsted; Erland J. Erlandsen; Anni Eskild-Jensen; Jørgen Frøkiær; Jens Brøchner-Mortensen

Prediction of renal function (GFR) from cystatin C and creatinine in children: Body cell mass increases accuracy of the estimate

Trine Borup Andersen, Lars Jødal, Martin Bøgsted, Erland J. Erlandsen, Anni Eskild-Jensen, Jørgen Frøkiær, Jens Brøchner-Mortensen

Research output: Contribution to conference without publisher/journal › Poster › Research

Abstract

AIM: To derive an accurate prediction model for estimating glomerular filtration rate (GFR) in children based primarily on the endogenous renal function marker cystatin C (CysC) and body cell mass (BCM).

THEORY: Cystatin C is produced at a constant rate in all cells of the body and is excreted by glomerular filtration followed by catabolization in the tubular cells. We hypothesized that production rate is proportional to body cell mass (BCM) and inferred GFR (mL/min) to be proportional to BCM/CysC.

MATERIAL AND METHODS: GFR was determined with ⁵¹Cr-EDTA-clearance in 131 children (52 girls, 79 boys) aged 2-14 years. GFR was 14-147 mL/min/1.73m². BCM was estimated using bioimpedance spectroscopy. Log-transformed data on BCM/CysC, serum creatinine (SCr), body-surface-area (BSA), height×BSA/SCr, CysC, weight, sex, age, height, serum urea and albumin were considered possible explanatory variables using robust regression in a forward, stepwise procedure. GFR (mL/min) was the dependent variable. The accuracy and precision of the prediction model were compared to other prediction models from the literature, using k-fold cross-validation. Local constants and coefficients were calculated for all models.

RESULTS: New prediction equation GFR (mL/min) = (BCM/CysC)^0.39×(heightxBSA/SCr)^0.65×10.2 could predict 99% within ±30% of reference GFR, and 66% within ±10%. This was higher than all other equations. The present equation also had the highest R²and the narrowest 95% limits of agreement.

CONCLUSION: The new equation predicts GFR with higher accuracy than other equations. Endogenous methods are, however, still not accurate enough to replace exogenous markers when GFR must be determined with high accuracy.

Original language	English
Publication date	2010
Publication status	Published - 2010
Externally published	Yes
Event	Forskningens Dag 2010 - Aalborg, Denmark Duration: 28 Oct 2010 → 28 Oct 2010

Conference

Conference	Forskningens Dag 2010
Country/Territory	Denmark
City	Aalborg
Period	28/10/2010 → 28/10/2010

Keywords

Cystatin C
Glomerular Filtration Rate
Bioelectric impedance spectroscopy

AUB Link

Search for the material in Aalborg University Library's search engine

Cite this

@conference{05c8454be4c44bc388ab40b70a63ad7b,

title = "Prediction of renal function (GFR) from cystatin C and creatinine in children: Body cell mass increases accuracy of the estimate",

abstract = "AIM: To derive an accurate prediction model for estimating glomerular filtration rate (GFR) in children based primarily on the endogenous renal function marker cystatin C (CysC) and body cell mass (BCM).THEORY: Cystatin C is produced at a constant rate in all cells of the body and is excreted by glomerular filtration followed by catabolization in the tubular cells. We hypothesized that production rate is proportional to body cell mass (BCM) and inferred GFR (mL/min) to be proportional to BCM/CysC.MATERIAL AND METHODS: GFR was determined with 51Cr-EDTA-clearance in 131 children (52 girls, 79 boys) aged 2-14 years. GFR was 14-147 mL/min/1.73m2. BCM was estimated using bioimpedance spectroscopy. Log-transformed data on BCM/CysC, serum creatinine (SCr), body-surface-area (BSA), height×BSA/SCr, CysC, weight, sex, age, height, serum urea and albumin were considered possible explanatory variables using robust regression in a forward, stepwise procedure. GFR (mL/min) was the dependent variable. The accuracy and precision of the prediction model were compared to other prediction models from the literature, using k-fold cross-validation. Local constants and coefficients were calculated for all models. RESULTS: New prediction equation GFR (mL/min) = (BCM/CysC)^0.39×(heightxBSA/SCr)^0.65×10.2 could predict 99% within ±30% of reference GFR, and 66% within ±10%. This was higher than all other equations. The present equation also had the highest R2 and the narrowest 95% limits of agreement.CONCLUSION: The new equation predicts GFR with higher accuracy than other equations. Endogenous methods are, however, still not accurate enough to replace exogenous markers when GFR must be determined with high accuracy.",

keywords = "Cystatin C, Glomerular filtrationsrate, Bioelectric impedance spectroscopy, Cystatin C, Glomerular Filtration Rate, Bioelectric impedance spectroscopy",

author = "Andersen, {Trine Borup} and Lars J{\o}dal and Martin B{\o}gsted and {J. Erlandsen}, Erland and Anni Eskild-Jensen and J{\o}rgen Fr{\o}ki{\ae}r and Jens Br{\o}chner-Mortensen",

year = "2010",

language = "English",

note = "Forskningens Dag 2010 ; Conference date: 28-10-2010 Through 28-10-2010",

}

TY - CONF

T1 - Prediction of renal function (GFR) from cystatin C and creatinine in children: Body cell mass increases accuracy of the estimate

AU - Andersen, Trine Borup

AU - Jødal, Lars

AU - Bøgsted, Martin

AU - J. Erlandsen, Erland

AU - Eskild-Jensen, Anni

AU - Frøkiær, Jørgen

AU - Brøchner-Mortensen, Jens

PY - 2010

Y1 - 2010

N2 - AIM: To derive an accurate prediction model for estimating glomerular filtration rate (GFR) in children based primarily on the endogenous renal function marker cystatin C (CysC) and body cell mass (BCM).THEORY: Cystatin C is produced at a constant rate in all cells of the body and is excreted by glomerular filtration followed by catabolization in the tubular cells. We hypothesized that production rate is proportional to body cell mass (BCM) and inferred GFR (mL/min) to be proportional to BCM/CysC.MATERIAL AND METHODS: GFR was determined with 51Cr-EDTA-clearance in 131 children (52 girls, 79 boys) aged 2-14 years. GFR was 14-147 mL/min/1.73m2. BCM was estimated using bioimpedance spectroscopy. Log-transformed data on BCM/CysC, serum creatinine (SCr), body-surface-area (BSA), height×BSA/SCr, CysC, weight, sex, age, height, serum urea and albumin were considered possible explanatory variables using robust regression in a forward, stepwise procedure. GFR (mL/min) was the dependent variable. The accuracy and precision of the prediction model were compared to other prediction models from the literature, using k-fold cross-validation. Local constants and coefficients were calculated for all models. RESULTS: New prediction equation GFR (mL/min) = (BCM/CysC)^0.39×(heightxBSA/SCr)^0.65×10.2 could predict 99% within ±30% of reference GFR, and 66% within ±10%. This was higher than all other equations. The present equation also had the highest R2 and the narrowest 95% limits of agreement.CONCLUSION: The new equation predicts GFR with higher accuracy than other equations. Endogenous methods are, however, still not accurate enough to replace exogenous markers when GFR must be determined with high accuracy.

AB - AIM: To derive an accurate prediction model for estimating glomerular filtration rate (GFR) in children based primarily on the endogenous renal function marker cystatin C (CysC) and body cell mass (BCM).THEORY: Cystatin C is produced at a constant rate in all cells of the body and is excreted by glomerular filtration followed by catabolization in the tubular cells. We hypothesized that production rate is proportional to body cell mass (BCM) and inferred GFR (mL/min) to be proportional to BCM/CysC.MATERIAL AND METHODS: GFR was determined with 51Cr-EDTA-clearance in 131 children (52 girls, 79 boys) aged 2-14 years. GFR was 14-147 mL/min/1.73m2. BCM was estimated using bioimpedance spectroscopy. Log-transformed data on BCM/CysC, serum creatinine (SCr), body-surface-area (BSA), height×BSA/SCr, CysC, weight, sex, age, height, serum urea and albumin were considered possible explanatory variables using robust regression in a forward, stepwise procedure. GFR (mL/min) was the dependent variable. The accuracy and precision of the prediction model were compared to other prediction models from the literature, using k-fold cross-validation. Local constants and coefficients were calculated for all models. RESULTS: New prediction equation GFR (mL/min) = (BCM/CysC)^0.39×(heightxBSA/SCr)^0.65×10.2 could predict 99% within ±30% of reference GFR, and 66% within ±10%. This was higher than all other equations. The present equation also had the highest R2 and the narrowest 95% limits of agreement.CONCLUSION: The new equation predicts GFR with higher accuracy than other equations. Endogenous methods are, however, still not accurate enough to replace exogenous markers when GFR must be determined with high accuracy.

KW - Cystatin C

KW - Glomerular filtrationsrate

KW - Bioelectric impedance spectroscopy

KW - Cystatin C

KW - Glomerular Filtration Rate

KW - Bioelectric impedance spectroscopy

M3 - Poster

T2 - Forskningens Dag 2010

Y2 - 28 October 2010 through 28 October 2010

ER -

Prediction of renal function (GFR) from cystatin C and creatinine in children: Body cell mass increases accuracy of the estimate

Abstract

Conference

Keywords

AUB Link

Fingerprint

Cite this