Abstract
The evaluation of estimated GFR (eGFR) is a pivotal staging step in patients with chronic kidney disease (CKD), and renal ultrasound plays an important role in diagnosis, prognosis and progression of CKD. The interaction between histopathological diagnosis and ultrasound parameters in eGFR determination has not been fully investigated yet. The study examined the results of native kidney biopsies performed in 48 Italian centers between 2012 and 2020. The primary goal was if and how the histopathological diagnosis influences the relationship between ultrasound parameters and eGFR. After exclusion of children, patients with acute kidney injury and patients without measure of kidney length or parenchymal thickness, 2795 patients have been selected for analysis. The median values were 52 years for patient age, 11 cm for bipolar kidney diameter, 16 mm for parenchymal thickness, 2.5 g/day for proteinuria and 70 ml/min/1.73 m2 for eGFR. The bipolar kidney diameter and the parenchymal thickness were directly related with eGFR values (R square 0.064). Diabetes and proteinuria were associated with a consistent reduction of eGFR, improving the adjusted R square up to 0.100. Addition of histopathological diagnosis in the model increased the adjusted R square to 0.216. There is a significant interaction between histopathological diagnosis and longitudinal kidney diameter (P 0.006). Renal bipolar length and parenchymal thickness are directly related with eGFR. The magnitude of proteinuria and histopathological kidney diagnosis are associated with eGFR. The relationship between kidney length and the level of eGFR depends on the nature of the kidney disease.
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Introduction
Renal Ultrasound (US) plays an important role in the diagnosis and progression of chronic kidney disease (CKD) [1]. The evaluation of CKD is classified based on the glomerular filtration rate (GFR) estimate, urinary abnormalities, and ultrasound structural kidney abnormalities. When CKD is suspected or diagnosed, longitudinal kidney diameter, parenchymal thickness and echogenicity grading are the first measures to be gathered, through renal US, as first imaging tool [2]. CKD can be associated with different values of longitudinal kidney diameters. It increases in polycystic kidney disease, in myeloma cast nephropathy, in amyloidosis, and in the beginning of the diabetic Kimmestiel-Wilson nephropathy. Contrarily, it decreases in many other nephropathies, such as chronic glomerulonephritis, nephroangiosclerosis and chronic ischemic nephropathy.
The estimated GFR (eGFR) in place of its measure [3, 4] is a pivotal step in the CKD staging and can be performed by using various approaches, like the Cockroft-Gault [5] and the Modification of Diet in Renal Disease (MDRD) equations [6]. In the clinical practice context, the Cockroft-Gault equation has been progressively abandoned, partially because it requires the knowledge of the patient weight, often unavailable at the laboratory level and, in addition, it overestimates the true GFR at high values of body mass index [7]. On the other side, the first MDRD eGFR equation [8] has been improved to take into account three subsequent needs: a standardized measurement of creatinine [9], a simplified equation (four variables in place of the first six) [9], and a higher accuracy at GFR values higher than 60 ml/min/1.73 m2 [6]. In 2012 [10], 2014 [4] and 2021 [11], other equations developed in different populations were published, and the Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) equations have been used more frequently for general clinical purpose. The 2021 CKD-EPI equation offered the opportunity to take out the race information from the eGFR estimation [11]. Unfortunately, this race-free equation may result in substantial change in eGFR estimation, in CKD reclassification, in kidney and cardiovascular prognosis [12,13,14], and in substantial error in comparison with the measured GFR, also among kidney transplant recipients [15].
Future research should focus on the lack of a more precise eGFR equations at the individual level [16], and the risk of a misleading indexing of glomerular filtration rate for body surface area in obese patients [17].
The aim of this study, instead, is to define the relationship between the kidney diameters measured in vivo with ultrasound and the estimated GFR according to the CKD-EPI 2009 equation [6], taking into account the role of the histopathological diagnosis available with native kidney biopsy.
Materials and methods
Patient selection
The invited Italian study centers and the patients enrolled in this study are described in detail in our previous work [18]. Briefly, as this was a cross-sectional observational multi-center study, the enrollment criteria were not questioned. Consequently, all of the consecutive patients undergoing a native kidney biopsy during the active recruitment period were considered eligible and there were no a priori exclusion criteria. In relation with the aim of this study, secondary exclusion criteria were pediatric patients (age at kidney biopsy less than 18 years), unstable patients for acute kidney injury (AKI) or AKI in patients on chronic kidney disease (CKD), unavailability of eGFR or its estimated value higher than 200 ml/min, unavailability of kidney length or of parenchymal thickness of biopsied kidney.
Data collection was centralized and made use of an ad hoc web-based database linked to the Italian Renal Biopsy Registry (http://www.irrb.net/).
All of the patients gave their written informed consent; the study protocol was approved by the Ethics Committee of Bari University and implemented in accordance with the principles of the Declaration of Helsinki. It was not appropriate to involve patients or the public in the design, or conduct, or reporting, or dissemination plans of our research. This independent study without any sponsorship was registered with ClinicalTrials.gov (No. NCT04948593).
Outcomes
The primary goal of this study was to define the relation between the renal length and parenchymal thickness measured with ultrasounds and the eGFR, taking into account the role of the histopathological diagnosis made by native kidney biopsy.
Variables
Relevant patient-related covariates and factors recorded included age, gender, diabetes, the clinical presentation of their renal disease, the presence of renal failure, the eGFR according to CKD-EPI equations [9], the bipolar longitudinal diameter and the parenchymal thickness of the biopsied kidney, the magnitude of proteinuria and the histopathologic kidney diagnosis. The histopathologic kidney diagnosis, defined according to our previous work [18], was treated in the statistical analysis as a categorical variable.
Ultrasound parameters were measured in the biopsied kidney, thus more frequently on the left side (95% of patients), on the midaxillary line with the patient in lateral decubitus. Parenchymal thickness was measured and reported where it was minimum in value, avoiding Bertin's columns.
To avoid bias, proteinuria, eGFR and ultrasound parameters were measured before the native kidney biopsy.
The diabetic variables were considered at three levels. The clinical diabetes status (yes/no) was defined according to the clinical diagnosis of diabetes without the knowledge of the histopathologic kidney diagnosis. In addition, the type [19] and the severity [20] of diabetic nephropathy according to Mazzucco G et al. [19] and to Tervaert TW et al. [20], respectively, were also considered.
Statistical analysis
For descriptive purposes, quantitative variables were analysed using their median values and the 10th and 90th percentiles, as indexes of central tendency and variability, respectively. Categorical variables were analysed as absolute numbers and percentages.
For inferential purposes, multivariate analysis of variance was performed, using the eGFR as dependent variable, according to CKD-EPI equation [9] expressed in ml/min/1.73 m2. To investigate the role of the various covariates, a step-by-step approach was used starting from the ultrasound parameters, such as the kidney bipolar diameter and parenchymal thickness. According to the suggestion of Lucisano et al. [21], we have considered also the role of the kidney length indexed for body height compared with the kidney length alone. The next step was adding two covariates easily available before kidney biopsy, such as the clinical diabetes status (yes/no) and proteinuria (g/day) values. To investigate the slope between US parameters and eGFR in patients with clinical diabetes compared with patients without clinical diabetes, we tested the interaction term clinical diabetes status by kidney length. Thus, we tested the histopathologic kidney diagnosis, as categorical variable, and its interaction with the US biopsied kidney length. Finally, we added in the model the type [19] and severity [20] of diabetic nephropathy. The amount of explained variance, through the adjusted R square, was used as goodness of fit. The partial Eta square of each covariate was used to test the relative net impact of each one compared to the others.
All the analyses were performed using the Statistical Package for Social Sciences (SPSS for Windows, version 23.0).
Results
This study involved 48 Italian centers (see Appendix) and 5312 patients, enrolled from the 3rd of January 2012 to the 4th of August 2020. After exclusion of children (333 patients, 6%), the patients with acute kidney injury (AKI) or AKI on CKD (1390 patients, 26%) and patients without measure of kidney length or parenchymal thickness (894 patients, 17%), the final sample of 2795 patients (53%) was selected for analysis from the pool of 5312 biopsied patients (Fig. 1). Thus 2795 patients, with one kidney biopsy for each patient, constituted the study group for this report. The main characteristics of the analysed patients were shown in Table 1. The median values were 52 years for patient age, 11 cm for bipolar kidney diameter, 16 mm for parenchymal thickness, 2.5 g/day for proteinuria and 70 ml/min/1.73 m2 for eGFR. Male were prevalent (60.5%), with a clinical diagnosis of diabetes status in 14.9% of the cases. Urinary abnormalities (49.2%) and nephrotic syndrome (39.4%) were the more common clinical presentations of studied patients.
Multivariate analysis
The Table 3, Panel A shows how the ultrasound kidney parameters, such as the bipolar kidney diameter and the parenchymal thickness, are associated with eGFR values. As expected, the B coefficients of both ultrasound parameters were positive, indicating a direct association with the eGFR values. From a clinical perspective, for each incremental centimeter in renal length, we can expect an increase of 6.89 ml/min/1.73 m2 of eGFR. The adjusted model R square value is 0.064, showing that the ultrasound parameters, together with the gender variable, explain only 6.4% of the eGFR variability. This percentage is not improved by using kidney length and parenchymal thickness indexed for body height in place of the kidney length alone (data not shown).
Adding other two covariates easily available before and without kidney biopsy, such as the clinical diabetes status and proteinuria values (Table 3, Panel B), the adjusted model R square value increased from 0.064 to 0.100, with the persistent major contribution of the bipolar kidney diameter (Eta square of 0.048). Interestingly, male gender, diabetes status and proteinuria were associated with a significant and a consistent reduction of eGFR value (see B coefficients in Panel B of Table 3). The interaction of clinical diabetes with ultrasound kidney parameters (bipolar length and parenchymal thickness) was not statistically significant (P value 0.389 and 0.819, respectively), meaning that the slope between the ultrasound kidney parameters and eGFR is not different between patients with and without clinical diabetes. Thus, for each incremental centimeter in renal length, we can expect the same increase of eGFR in both patients with and without clinical diabetes.
The histopathological diagnosis added a lot of information on the eGFR/ultrasound parameters relationship (Table 4, Panel A). Indeed, the adjusted model R square value increased consistently from 0.100 to 0.216, with the major contribution made now by the histopathological diagnosis (P < 0.001, Eta square of 0.022). Moreover, as expected, there was a significant interaction of histopathological diagnosis with longitudinal kidney diameter (P = 0.006, Eta square of 0.017) suggesting that the association of kidney length with the level of eGFR was dependent on the nature of kidney disease. The histopathological diagnosis, at the time of kidney biopsy, influenced also the distribution of mean eGFR values (Fig. 2): some histopathological diagnoses were associated with a nearly normal eGFR value, as in case of normal kidney, of minimal chance disease (MCD) or of hereditary glomerulopathies. On the other side, small vessel vasculitis and myeloma cast nephropathy were more frequently associated with low eGFR values.
Finally, the global model can be only slightly ameliorated, from 0.216 to 0.219, with the addition of renal pathology score, according to the pathologic classification of diabetic nephropathy [20] (Table 4, Panel B): as expected, a high value of renal pathology score was associated with a decrease of eGFR (Fig. 3).
Discussion
The main findings of this study are (i) that is confirmed a direct relationship between eGFR and kidney mass, estimated with the kidney bipolar length and the parenchymal thickness, (ii) that diabetes status and proteinuria levels are associated inversely with the eGFR values, and finally (iii) that the association of kidney length with the level of eGFR is dependent on the nature of kidney disease.
Regarding the first finding, renal length and parenchymal thickness are clinically relevant parameters, often used for making clinical decisions [22]. In our study, both renal length and parenchymal thickness were associated directly with eGFR, with a major contribution of renal length (Eta square 0.037) compared with the parenchymal thickness (Eta square 0.006). As renal function loss occurs during the course of CKD, the measurement of kidney bipolar length using ultrasound can become a very useful tool and should be performed and reported in any clinical ultrasound kidney evaluation. Several studies have demonstrated the relationship between kidney size and eGFR in kidney donors [23], in renal transplant patients [24] and in older patients [25]. Since it is well-known that progressive loss of nephrons is associated with a reduction of kidney mass [26], correlations were performed between renal function in the elderlies and renal US parameters [27]. Apart from some specific kidney diseases such as polycystic kidney [28], longitudinal renal diameter is considered a pivotal marker of CKD, since it progressively declines together with GFR, thus with a direct relationship. Accordingly, polycystic kidney disease was absent in our sample, and also patients with acute kidney injury or acute kidney injury on chronic kidney disease, other confounding factors on the kidney diameter/eGFR relationship, were excluded from our analysis. Moreover, in most of the patients with acute kidney injury, renal US imaging shows normal or larger renal diameters [29]. For this reason, in our study, also patients with acute kidney injury were excluded.
In course of CKD, it is well known that there is a progressive loss of renal mass and a reduction of kidney length associated with a decline of GFR [4]. With age, this evolution pattern happens also in healthy subjects, in a less impressive manner, and can manifest differently in men and women [30]. Anyways, the relationship eGFR/kidney diameter length remained very weak in our study (adjusted R square value of 0.064) and this can be due to at least two limiting factors: the diameter length was measured only on one kidney, the biopsied one, and the lack of longitudinal observations. In fact, no information was collected on the contralateral kidney diameter. Regarding the latter limiting factor, the cross-sectional design of the study did not permit to take into account the progressive aging kidney atrophy, and the related kidney compensatory hypertrophy common in the CKD course [26, 31]. Kidney atrophy and subsequent opposite compensatory hypertrophy act in opposite directions on kidney length, with the final result of a reduced correlation between the kidney length and the eGFR.
The second relevant finding of our study was related to other two parameters easily available before biopsy, that can be used to improve the estimation of kidney damage: the clinical diabetes status and highest levels of proteinuria, that were associated with a significant and a consistent reduction of eGFR value, indeed the adjusted model R square value increased from 0.064 to 0.100. If the reduction of eGFR in diabetic patients at a late stage is an expected finding, the interaction of diabetes with ultrasound kidney parameters (bipolar length and parenchymal thickness) was not statistically significant (P value 0.389 and 0.819, respectively), meaning that the slope between the ultrasound kidney parameters and eGFR is not different between patients with and without clinical diabetes. Thus, for each incremental centimeter in renal length, we can expect the same increase of eGFR in both patients with and without clinical diabetes. This is another interesting finding of this study. Also, the association of high proteinuria with low eGFR levels, controlling for histopathological diagnosis, is another novel and interesting one. Thus, proteinuria has many roles, not only in various types of glomerulonephritis [32] and in Kidney Disease Screening Programs [33], but also in CKD staging, influencing directly the value of eGFR.
The third main finding of our study derived from the histopathological diagnosis of the biopsied kidney. In our study the association between histopathological diagnosis and the eGFR was confirmed. Indeed, including this variable in the multivariate analysis, the adjusted R square value increased consistently from 0.100 to 0.216. Moreover, there is a significant interaction of histopathological diagnosis with longitudinal kidney diameter (P = 0.006) suggesting that the association of kidney length with the level of eGFR is dependent on the nature of kidney disease.
Finally, this study had some strong points that are worth to be underlined. The opportunity to investigate the association between ultrasound parameters and eGFR, controlling, in a multivariate context, for the histopathological diagnosis is a very powerful and adequate study design. The ultrasound parameters were determined before kidney biopsy, and thus not dependent by bleeding risks of kidney biopsy [18] and/or by subsequent therapies suggested by the histopathological diagnosis. The large sample size and the combined availability of ultrasound kidney parameters with the histopathologic kidney diagnosis, validated and controlled by qualified histopathologists, are unique in the scientific literature, although its results are partially confirmatory.
Conclusions
Renal bipolar length and cortical thickness are related directly with eGFR. Magnitude of proteinuria and histopathological kidney diagnosis are associated with eGFR values. The relationship between kidney length and the level of eGFR is dependent on the nature of kidney disease.
Data availability
Data may be shared upon reasonable request to the corresponding author.
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Acknowledgements
The authors would like to thank the Società Italiana di Nefrologia (SIN) and the Fondazione Italiana del Rene (FIR) for their support in developing the website database.
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Open access funding provided by Università degli Studi di Bari Aldo Moro within the CRUI-CARE Agreement. This was an independent study without any direct sponsorship, and so there was no financial conditioning that may have affected the analyses.
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Simeone Andrulli and Antonietta Gigante designed the study and wrote the first draft of the paper. Simeone Andrulli analysed the data. Umberto Venere and Domenico Roselli participated in data collection. Umberto Venere, Domenico Roselli, Giovanni Valsecchi and Simeone Andrulli participated in data quality control. Giovanni Andrulli provided the linguistic revision of the manuscript. All of the authors assisted in the preparation of the final manuscript.
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Appendix
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Andrulli, S., Gigante, A., Rossini, M. et al. How histopathological diagnosis interacts with kidney ultrasound parameters and glomerular filtration rate. Intern Emerg Med (2024). https://doi.org/10.1007/s11739-024-03711-7
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DOI: https://doi.org/10.1007/s11739-024-03711-7