Penélope D. Sánchez-González

An integrative view of the pathophysiological events leading to cisplatin nephrotoxicity.

Cisplatin is among the most effective chemotherapeutic agents against solid tumors. Nephrotoxicity is the most common side effect of cisplatin chemotherapy, which limits the clinical use of cisplatin and seriously worsens the quality of life of cancer patients resulting in dosage reduction and discontinuation of treatment. Cisplatin involves a complex multifactorial process, as it has direct toxic effect on cells of the renal tubules, vasculature and glomeruli, and causes alterations in renal blood flow and glomerular filtration rate. Indirectly, cisplatin also induces inflammation of the renal interstitium, which contributes to the acute damage and may lead to chronic interstitial fibrosis, indicative of irreversible renal damage. This review presents an integrative view of the pathophysiological effects of cisplatin on tubular, vascular, glomerular, and interstitial function and the interplay among these actions. Moreover, it reviewed human clinical trials of the last ten years in order to evaluate the incidence and severity of the renal injury induced by cisplatin at the doses and therapeutic guidelines used in the clinical practice.

Quercetin reduces cisplatin nephrotoxicity in rats without compromising its anti-tumour activity

BACKGROUND Nephrotoxicity is the major limitation for the clinical use of cisplatin as an anti-tumoural drug. Our aim was to investigate the protective effect of quercetin on cisplatin nephrotoxicity in a rat tumour model in vivo and to examine the mechanisms of renal protection. METHODS Breast adenocarcinoma (13762 Mat B-III) cells were inoculated subcutaneously in male Fischer rats and 7 days later, the rats were administered daily with quercetin [50 mg/kg/day, intraperitoneally (i.p.)] or vehicle. Four days after that, the rats were given a single dose of cisplatin (4 mg/kg, i.p.) or vehicle. Tumour growth and renal function were monitored throughout the experiment. Two or 6 days after cisplatin administration, the rats were killed and the kidneys and tumours were removed to examine renal function and toxicity markers in both tissues. RESULTS In the kidney, cisplatin treatment induced: (i) a decrease in renal blood flow and glomerular filtration rate, (ii) tubular necrosis/apoptosis, (iii) increased lipid peroxidation and decreased endogenous antioxidant systems, (iv) increased expression of inflammation markers and (v) increased activity of the apoptosis executioner caspase-3. Cisplatin effectively reduced tumour size and weight. CONCLUSIONS Co-treatment with quercetin partially prevented all the renal effects of cisplatin, whereas it did not impair its anti-tumour activity. In conclusion, in a model of tumour-bearing rats, quercetin prevents the nephrotoxic effect of cisplatin without affecting its anti-tumour activity.

Effect of the flavonoid quercetin on cadmium-induced hepatotoxicity.

The present study was designed to evaluate whether treatment with quercetin exerts any beneficial effect on cadmium (Cd)-induced hepatotoxicity in order to establish the possible protective mechanisms of quercetin. Wistar rats were distributed in four experimental groups: control, Cd, quercetin, and Cd+quercetin. Hepatic toxicity was evaluated by measuring plasma concentrations of markers of hepatic injury. The activity of antioxidant enzymes in liver was also measured. Hepatic expression of metallothioneins (MT), and endothelial nitric oxide synthase (eNOS) was assayed by Western and Northern blot. Our results demonstrated that Cd administration induced an increased marker enzyme activity in plasma. This effect was not inhibited by quercetin. However, the administration of quercetin softened Cd-induced oxidative damage. MT levels in liver were substantially increased when the animals received Cd and quercetin. Hepatic eNOS expression was significantly increased after treatment with Cd and quercetin, being this increase higher than in animals receiving Cd alone. In conclusion, in this experimental model, quercetin was not able to prevent the Cd-induced liver damage although the animals that received both, Cd and quercetin showed a marked improvement in oxidative stress and an increase in the MT and eNOS expression. These results suggest that other mechanisms different to oxidative stress could be involved in hepatic damage.

Cardiotrophin-1 Administration Prevents the Renal Toxicity of Iodinated Contrast Media in Rats

Although generally reversible, contrast media toxicity often induces contrast-induced nephropathy (CIN), which is associated with longer hospitalization time, the need for dialysis, and higher incidence of later cardiovascular events and higher mortality. Preventive cotreatments have been assayed at the preclinical and clinical levels, but recent meta-analysis has not demonstrated a beneficial effect, which supports the search for new nephroprotective strategies. We have assessed if the administration of cardiotrophin-1 (CT-1), an endogenous cytokine with protective properties on the heart and liver, might mitigate CIN in rats. We have developed a model of CIN induced by the administration of the contrast medium gastrographin iv (3.7mg/kg) in rats sensitized by previous administration of subnephrotoxic doses of gentamicin (50mg/kg/day, ip) for 6 days. The severity of CIN was assessed by the measurement of renal function; renal histological damage; urinary excretion of markers of tubular damage, including N-acetyl beta glucosaminidase (NAG), kidney injury molecule 1 (KIM-1), and plasminogen activator inhibitor 1; lipid peroxidation; and renal apoptosis. Treatment with CT-1 almost completely prevented the renal tissue damage, as evidenced by almost total prevention of tubular desepithelization and tubular obstruction, reduced caspase activation, and cell proliferation. Besides, CT-1 also prevented the increment in renal tissue levels of renal tissue injury markers NAG, KIM-1, and neutrophil gelatinase-associated lipocalin. Oxidative stress, a hallmark of CIN, was also prevented by CT-1. Administration of CT-1 also prevented the derangement in kidney function induced by CIN. Renal hemodynamics, also impaired by the contrast medium, was normal in rats cotreated with CT-1. CT-1 administration significantly prevents the alterations in renal function and structure observed in a rat model of CIN.

Effects of deferasirox on renal function and renal epithelial cell death.

Iron-chelating therapy results in a significant improvement in the life expectancy of patients with transfusional iron overload. However, alterations of renal function have been observed in some patients undergoing chelation therapy. In the present study we evaluated the effect of treatment with deferasirox iron chelator on the renal function in normal Wistar rats and in mouse and human cultured tubular cell lines. Results indicate that deferasirox given daily via intraperitoneal route for 7 days induced: (1) an increased urinary protein, albumin and glucose excretion, (2) tubular necrosis/apoptosis, (3) and increased tubular damage markers, in spite of normal glomerular function. Moreover, in vitro studies revealed that: (1) mouse MCT cultures resulted more susceptible to the antiproliferative/cytotoxic effect of deferasirox, mainly at 24h after treatment, than human HK-2 cultures, (2) MCT cell content of damage molecules increased after 24h of iron chelator treatment with slight changes in their excretion into the culture medium and (3) MCT cultures showed a significant evidence of apoptotic cell death through an increased expression and activation of caspase-3 and marked DNA fragmentation. In conclusion, this renal side effect of deferasirox-chelating therapy seems to be based on direct toxic effects of deferasirox on renal tubular cells.