Early urinary markers of target nephron segments as studied in cadmium toxicity.

A number of chemicals may adversely affect one or more of the anatomical structures of the kidney, such as the glomerulus, the tubular apparatus, the medullary, or interstitial cells. To recognize subclinical renal dysfunction, a battery of new, non-invasive tests was applied in comparison to established ones. The study on cadmium exposed subjects, performed within the framework of a collaborative European research project, exemplifies the concept of target selectivity within a nephron. One hundred seventy-two subjects were classified according to urinary cadmium excretion as controls (< 1.5 micrograms/g creatinine), or subjects with moderate or high cadmium body burden (1.5 to 5 micrograms/g creatinine, > 5 micrograms/g creatinine). Twenty-six urinary analytes (such as serum derived proteins, tubular enzymes, eicosanoids) and four plasma markers, related to the function or integrity of specific nephron segments, were investigated in a cross-sectional study. The group with the moderate cadmium body burden showed alterations of proximal tubular integrity, that is, increased excretion of tubular brush-border antigens. The group with higher cadmium body burden revealed an involvement of the whole nephron. The most prominent quantitative changes were found for the glomerular markers high molecular weight proteins, and thromboxane B2 and for the proximal tubular markers retinol binding protein, alpha 1-microglobulin, N-acetyl-beta-D-glucosaminidase, and the intestinal alkaline phosphatase. A diagnostic approach to screen for nephrotoxicity due to environmental hazards like cadmium should include proximal tubular markers (alpha 1-microglobulin and tubular enzymes, that is, intestinal alkaline phosphatase) but the measurement of glomerular markers is also advisable.

Markers of early renal changes induced by industrial pollutants. III. Application to workers exposed to cadmium.

Cadmium (Cd) was the third heavy metal investigated in the European collaborative research project on the development and validation of new markers of nephrotoxicity. Fifty workers exposed to Cd and 50 control workers were examined. After application of selection criteria 37 workers (mean age 43) exposed to Cd for an average of 11.3 years; and 43 age matched referents were retained for final analysis. The average concentrations of Cd in blood (Cd-B) and urine (Cd-U) of exposed workers were 5.5 micrograms Cd/l and 5.4 micrograms Cd/g creatinine respectively. By contrast with lead and mercury, Cd had a broad spectrum of effects on the kidney, producing significant alterations in amounts of almost all potential indicators of nephrotoxicity that were measured in urine--namely, low and high molecular weight proteins, kidney derived antigens or enzymes, prostanoids, and various other biochemical indices such as glycosaminoglycans and sialic acid. An increase in beta 2-microglobulin and a decrease of sialic acid concentration were found in serum. Dose-effect/response relations could be established between most of these markers and Cd-U or Cd-B. The thresholds of Cd-U associated with a significantly higher probability of change in these indicators were estimated by logistic regression analysis. Three main groups of thresholds could be identified: one around 2 micrograms Cd/g creatinine mainly associated with biochemical alterations, a second around 4 micrograms Cd/g creatinine for high molecular weight proteins and some tubular antigens or enzymes, and a third one around 10 micrograms Cd/g creatinine for low molecular weight proteins and other indicators. The recent recommendation by the American Conference of Governmental Industrial Hygienists (ACGIH) of 5 micrograms Cd/g creatinine in urine as the biological exposure limit for occupational exposure to Cd appears thus justified, although for most of the effects occurring around this threshold the link with the subsequent development of overt Cd nephropathy is not established. In that respect, the very early interference with production of some prostanoids (threshold 2 micrograms Cd/g creatinine) deserves further investigation; although this effect might contribute to protect the filtration capacity of the kidneys, it might also play a part in the toxicity of Cd on bone.

Glycation of serum albumin and its role in renal protein excretion and the development of diabetic nephropathy.

The present study was designed to investigate whether microalbuminuria at the onset of diabetic nephropathy might be partially due to the glycation of serum albumin. It is postulated elsewhere (Ghiggeri et al., Proc. Eur. Dial. Transplant. Assoc. 21 (1984) 633-636) that the glycation of serum albumin and the subsequent cationization may induce microalbuminuria. To investigate whether a relationship exists between the amount of glycated albumin in its cationized form and the development, and progression of diabetic nephropathy, the urinary excretion of glycated albumin was studied in diabetic patients. The diabetic patients (type I and II diabetes) were divided into groups according to their albumin excretion rates: group I diabetics had a normal albumin excretion (n = 30, x = 4.2 mg/12 h); group II diabetes displayed microalbuminuria (n = 17, x = 38.6 mg/12 h); group III diabetics displayed macroalbuminuria (n = 21, x = 582.5 mg/12 h). The fraction of glycated albumin in serum (Glyco Gel Test Kit) was 0.032 in group I, 0.042 in group II, and 0.038 in group III, all these values were significantly higher than the value for the controls (0.014%; n = 17, 2 alpha = 0.001) as measured with the Glyco Gel Test Kit. The concentration of glycated albumin in the urine of the controls and group I was below the detection limit. Urine in group II contained only a glycated albumin fraction of 0.0002 of total albumin, and the fraction for group III was 0.0008. Isoelectric focussing (IEF) and chromato-focussing revealed native albumin with an isoelectric point of 4.7-4.9, and anionic glycated albumin with a pI of 3.0-4.2.(ABSTRACT TRUNCATED AT 250 WORDS)