Derek Grant

Effects of Gadolinium Contrast Agents in Naïve and Nephrectomized Rats: Relevance to Nephrogenic Systemic Fibrosis

Background: Human nephrogenic systemic fibrosis (NSF) is a rare condition reported in patients with severe renal insufficiency exposed to a gadolinium (Gd)-based contrast agent. An animal model of NSF could help to investigate its mechanisms and lead to prevention and treatment. Purpose: To evaluate a possible animal model of NSF using naïve and partially nephrectomized rats to induce conditions similar to those in patients at risk of NSF. Material and Methods: Naïve rats received intravenous doses of 5 or 10 mmol/kg Omniscan; 5 mmol/kg Magnevist; 1 mmol/kg caldiamide; 1, 2.5, or 5 mmol/kg gadodiamide; 25 µmol/kg GdCl3; or 25 µmol/kg Gd citrate. Partially nephrectomized rats received 5 mmol/kg Omniscan; 5 mmol/kg Magnevist; 1 mmol/kg caldiamide; 1 mmol/kg gadodiamide; 25 µmol/kg GdCl3; or 25 µmol/kg Gd citrate. There were three or four animals per group. Clinical signs were recorded during treatment. At termination, clinical biochemistry, histopathology, and tissue Gd and Zn concentrations were investigated. Results: Similar responses to treatment were seen in naïve and nephrectomized rats. High doses of gadodiamide were toxic, necessitating early termination of the affected animals. Skin lesions appeared in naïve and nephrectomized groups treated with gadodiamide or Omniscan, coinciding with the onset of signs of pruritus, i.e., intensive scratching. The histomorphological features of the skin lesions were also consistent with superficial physical trauma. Dermal fibrosis was not a feature of these skin lesions in any of the groups, i.e., no increased collagen density, CD34+ cells, or increased fibroblasts. This was supported by skinfold measurements that demonstrated no increased skin thickness. Treatment with the gadolinium-based contrast agents and Gd salts resulted in increased Gd content of several tissues. The Gd salts were mainly taken up by the liver and spleen, possibly reflecting formation of insoluble particles and macrophage uptake. Zn tissue concentrations were normal or increased. Other major treatment-related changes included increased serum rat C-reactive protein and histamine; mineralization affecting the dermis, stomach, and blood vessels; and renal proximal tubule vacuolation. Conclusion: The visible skin lesions seen in this study appeared to be caused by excessive scratching in response to pruritus. As there was no evidence of dermal fibrosis, the cardinal feature of human NSF, this did not appear to be a model of human NSF.

Cardiac Metal Contents After Infusions of Manganese: An Experimental Evaluation in the Isolated Rat Heart

RATIONALE AND OBJECTIVES Manganese dipyridoxyl diphosphate (MnDPDP), a contrast agent for liver MRI, releases free Mn2+ in a graded manner. The aim of the study was to compare the effects of brief versus prolonged infusions of MnDPDP and manganese chloride (MnCl2) on cardiac function, metabolism, Mn accumulation, and tissue metal content. METHODS Isolated perfused rat hearts received 1-minute or 10-minute infusions of MnDPDP (100 microM, 1000 microM) or of MnCl2 (10 microM, 100 microM). Physiologic indices were measured intermittently, and tissue high-energy phosphate compounds and Ca/Fe/Mg/Mn/Zn contents were measured after a standardized Mn washout. RESULTS One-minute and 10-minute infusions induced, respectively, minor and marked depressions of contractile function and corresponding elevations in myocardial Mn content. MnCl2 was markedly more potent than MnDPDP. Ten-minute infusions of the highest concentration of MnDPDP and MnCl2 lowered tissue Mg and elevated tissue Ca (MnCl2), whereas high-energy phosphates were unaffected. CONCLUSIONS Mn uptake after Mn infusion is strongly related to the duration, concentration, and dose of free Mn ions. Differences in Mn accumulation between MnDPDP and MnCl2 were more pronounced after the 10-minute infusion.

Iodixanol 320 results in better renal tolerance and radiodensity than do gadolinium-based contrast media: arteriography in ischemic porcine kidneys.

PURPOSE To prospectively compare nephrotoxicity and radiodensity of plasma hyperosmotic gadolinium chelates (attenuation-osmotic ratio of 1:1) with those of plasma iso-osmotic iodine-based contrast media (attenuation-osmotic ratio of 3:1 or 6:1) after renal arteriography in ischemic porcine kidneys. MATERIALS AND METHODS The local animal care committee approved this study. The following contrast media were used: (a) iodixanol (150 mg of iodine per milliliter and 320 mg I/mL, 0.29 osm/kg H(2)O), (b) iopromide (150 mg I/mL, 0.34 osm/kg), (c) 0.5 mol/L gadodiamide (0.78 osm/kg), and (d) 1.0 mol/L gadobutrol (1.6 osm/kg). After left-sided nephrectomy, contrast media (3 mL per kilogram of body weight) were injected (20 mL/min) in a noncrossover design into the right renal artery of pigs during a 10-minute ischemic period. There were eight pigs in each group and one group for each contrast medium. We compared histomorphology, radiographic contrast medium excretion, subjective radiodensity of nephrograms (70 kVp) at the end of injection, and contrast medium plasma half-life elimination times 1-3 hours after injection. Longer elimination times resulted in lower glomerular filtration rates. RESULTS Gadobutrol caused extensive tubular necrosis and moderate glomerular necrosis; gadodiamide and iopromide, minimal to mild tubular necrosis; and iodixanol, no necrosis. Gadobutrol was the only contrast medium to show no sign of excretion, and its plasma half-life elimination time (median, 1103 minutes; P < .001) was significantly longer than that of other contrast agents. Gadodiamide had a significantly longer plasma half-life elimination time (median, 209 minutes; P = .01) than did iodine-based contrast media (median, 136-142 minutes). The 320 mg I/mL dose of iodixanol had the highest radiodensity, whereas gadodiamide had the lowest radiodensity. The radiodensity of the 320 mg I/mL dose of iodixanol was greater than that of the 150 mg I/mL dose of iodixanol, which was equal to the radiodensities of the 150 mg I/mL dose of iopromide and 1.0 mol/L gadobutrol, which in turn were greater than that of 0.5 mol/L gadodiamide. CONCLUSION Plasma iso-osmotic iodine-based contrast media used at commercially available concentrations have superior attenuation and nephrotoxic profiles compared with equal volumes of hyperosmotic nonionic 0.5-1.0 mol/L gadolinium-based contrast media when performing renal arteriographic procedures.

GE-145, a new low-osmolar dimeric radiographic contrast medium

Background: Contrast-induced nephrotoxicity is a significant risk when using radiographic contrast media clinically, especially in high risk patients. Consequently, there is a need for a new contrast agent with improved clinical safety with regards to nephrotoxicity. Purpose: To evaluate the physicochemical properties as well as the preclinical safety and biodistribution parameters of the newly developed radiographic contrast medium GE-145. Material and Methods: Standard methods for radiographic contrast media were used for evaluation of physicochemical properties. The acute toxicity in rats was studied at 8, 10, and 12.5 gI/kg, the clinical chemistry parameters were determined, and histology of the kidneys was performed. Biodistribution was studied in rats using 123I-labeled GE-145. Results: GE-145 is more hydrophilic than iodixanol and has a considerably lower osmolality. The viscosity is similar to that of iodixanol and the protein binding is low. The acute toxicity is similar to that of iodixanol and the biodistribution is similar to that of other radiographic contrast media, showing mainly renal excretion. Kidney histology showed a moderate reversible vacuolization, similar to that of iodixanol. Conclusion: GE-145 exhibits similar preclinical properties to other dimeric radiographic contrast media. In addition, the low osmolality enables an iso-osmolar formulation containing a significantly higher concentration of electrolytes than Visipaque.

Histomorphological Changes after Renal X-Ray Arteriography Using Iodine and Gadolinium Contrast Media in an Ischemic Porcine Model.

Background: Gadolinium contrast media (Gd-CM) are regarded as non-nephrotoxic or considerably less nephrotoxic than iodine contrast media (I-CM), and have therefore come to be used as a substitute for I-CM in patients with renal insufficiency in a variety of radiographic examinations. Purpose: To investigate renal histomorphological changes caused by Gd-CM in comparison with I-CM after renal X-ray arteriography in an ischemic porcine model, and to evaluate these changes in relation to the nephrotoxicity of the CM used. Material and Methods: Test solutions: gadopentetate, gadodiamide, iohexol, gadobutrol, iopromide, iodixanol, mannitol, and saline. The experiments were performed on 152 animals. Each pig was randomized to receive one test solution injected into the balloon-occluded (10 min) right renal artery. The kidneys were evaluated histomorphologically. The severity of histomorphological changes was graded subjectively: 1 = minimal, 2 = mild, 3 = moderate, and 4 = marked. Results: The main histological changes were 1) proximal tubular and glomerular necrosis, 2) hemorrhage/congestion of the cortex, medulla, and glomeruli, 3) proximal tubular vacuolation, and 4) protein-filled tubules in the cortex and medulla. Necrosis and hemorrhage/congestion were more frequent after injections with gadopentetate, mannitol solution iso-osmotic to gadopentetate, and gadobutrol compared to all other groups (P<0.001). The degree of necrosis and hemorrhage/congestion was related to the degree of impairment of renal function, but inversely related to vacuolation and tubular protein filling. Conclusion: In ischemic porcine kidneys, the histomorphological changes caused by Gd-CM are similar to those caused by I-CM. Vacuolation appears to be independent of the osmolality and viscosity of the CM, and does not seem to be an indicator of renal impairment. “High-osmolal” Gd-CM are more nephrotoxic than “low- and iso-osmolal” I-CM when compared in equal volumes of concentrations, resulting in equal X-ray attenuation.

A modified model of gentamicin induced renal failure in rats: Toxicological effects of the iodinated X-ray contrast media ioversol and potential usefulness for toxicological evaluation of iodinated X-ray contrast media

Contrast-induced nephropathy (CIN) remains a serious complication in patients exposed to iodinated X-ray contrast media (ICM). Animal models of CIN are useful to further understand the mechanisms involved, identify novel biomarkers and evaluate potential differences between ICM. The current investigation was undertaken to modify the rat-gentamicin model for potential usefulness for toxicological evaluation of ICM. A dose-range finding study (50, 60 and 70 mg/kg body weight (bw)) of gentamicin was conducted over 4 consecutive days. Based on the kidney histopathology findings, a gentamicin dose of 70 mg/kg bw was chosen to investigate whether ICM would cause further renal damage. Following gentamicin treatment, this group was given a single administration of ioversol (6 gI/kg bw). Blood and urine samples were taken from all animals 3 days before the start of the study and at the end of treatment. Serum and urinary creatinine, urinary N-acetyl-β-D-glucosaminidase (NAG), γ-glutamyl transferase (GGT), total protein, and urine cytology were evaluated as biomarkers of renal damage. Histopathological examination of kidneys was performed. Histopathological examination of the kidneys revealed vacuolation, dilatation, and necrosis of the proximal tubules in the gentamicin-ioversol treatment group. These changes were not seen in the gentamicin-only treatment groups. Data on GGT and urinary epithelial cells show clear differences between rats treated with gentamicin alone versus gentamicin plus ioversol. These findings show that the modified rat-gentamicin model was able to demonstrate the nephrotoxic effect of ioversol.

The Effects of the Iodinated X-Ray Contrast Media Iodixanol, Iohexol, Iopromide, and Ioversol on the Rat Kidney Epithelial Cell Line NRK 52-E

Nephrotoxicity, associated with the administration of iodinated X-ray contrast media (ICM), continues to be a major side effect in a significant number of vulnerable patients undergoing diagnostic X-ray imaging procedures. The molecular mechanisms underlying these adverse effects on the kidneys are unclear despite several decades of investigation. Side effects are more common after exposure to high-osmolar compared with low-osmolar ICM, suggesting that osmolality may be an important physical–chemical property related to nephrotoxicity. This investigation in cultured NRK 52-E cells, a cell line of renal origin, compares the in vitro toxicity of the iso-osmolal ICM iodixanol with the low-osmolal ICM iohexol, iopromide, and ioversol. The cellular toxicity was evaluated with the trypan blue exclusion assay, the MTT assay, and incidences of cell death. A qualitative assessment of vacuolation of the cultured NRK 52-E cells was taken as a measure of intracellular uptake of ICM. A difference in cell death incidence was observed between the iso-osmolal iodixanol and the low-osmolal iohexol, iopromide, and ioversol contrast media, with the iso-osmolal iodixanol having the least effect in each of the in vitro systems tested. The osmolality of the contrast media appeared to be the major cause for the observed in vitro toxicity.