Osteoglycin As a Potential Biomarker of Mild Kidney Function Impairment in Type 2 Diabetes Patients

Overview

Journal J Clin Med

Specialty General Medicine

Date 2021 Jun 2

PMID 34065223

Citations 3

Authors

Sheila Gonzalez-Salvatierra

Cristina Garcia-Fontana

Francisco Andujar-Vera

Alejandro Borja Grau-Perales

Luis Martinez-Heredia

Maria Dolores Aviles-Perez

Maria Hayon-Ponce

Ivan Iglesias-Baena

Blanca Riquelme-Gallego

Manuel Munoz-Torres

Beatriz Garcia-Fontana

Affiliations

Soon will be listed here.

Abstract

Osteoglycin (OGN) could be a biomarker of mild kidney function impairment in type 2 diabetes (T2D). Our study aimed to determine the association between serum OGN and impaired kidney function risk in T2D patients and to analyze its potential role as an estimator of kidney disturbances in this population. This cross-sectional study included 147 T2D patients (65 ± 8 years, 58.5% males), and 75 healthy controls (63 ± 10 years, 36% males). Circulating OGN levels were determined by ELISA. Linear regression modeling was performed to determine the variables influencing circulating OGN, and an ROC curve was plotted to assess the usefulness of OGN as an estimator of diabetic kidney disease risk. Circulating OGN was significantly increased in T2D patients compared to controls (18.41 (14.45-23.27) ng/mL vs. 8.74 (7.03-12.35) ng/mL; < 0.001). We found a progressive increase in serum OGN according to the severity of kidney impairment in T2D patients (normal kidney function: 16.14 (12.13-20.48) ng/mL; mildly impaired kidney function: 19.15 (15.78-25.90) ng/mL; moderate impaired kidney function: 21.80 (15.06-29.22) ng/mL; = 0.006). Circulating OGN was an independent estimator of mildly impaired kidney function risk in T2D patients. We suggest that serum OGN could act as an albuminuria-independent biomarker of incipient kidney dysfunction in T2D patients.

Citing Articles

Serum osteoglycin is stable during various glycemic challenges in healthy men.

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Exploring the role of osteoglycin in type 2 diabetes: implications for insulin resistance and vascular pathophysiology.

Gonzalez-Salvatierra S, Garcia-Fontana B, Martinez-Heredia L, Lacal J, Andujar-Vera F, Sanabria-de la Torre R Am J Physiol Endocrinol Metab. 2023; 325(5):E649-E660.

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Lopez-Perez D, Redruello-Romero A, Garcia-Rubio J, Arana C, Garcia-Escudero L, Tamayo F Front Endocrinol (Lausanne). 2022; 13:818388.

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