Frans G. M. Russel

Diuretic efficacy of high dose furosemide in severe heart failure: bolus injection versus continuous infusion.

OBJECTIVES The efficacy of high dose furosemide as a continuous infusion was compared with a bolus injection of equal dose in patients with severe heart failure. BACKGROUND The delivery rate of furosemide into the nephron has been proved to be a determinant of diuretic efficacy in healthy volunteers. METHODS In a randomized crossover study we compared the efficacy of a continuous infusion of high dose furosemide (mean daily dosage 690 mg, range 250 to 2,000) versus a single bolus injection of an equal dose in 20 patients with severe heart failure. The patients received an equal dosage, either as a single intravenous bolus injection or as an 8-h continuous infusion preceded by a loading dose (20% of total dosage). RESULTS Mean (+/- SEM) daily urinary volume (infusion 2,860 +/- 240 ml, bolus 2,260 +/- 150 ml, p = 0.0005) and sodium excretion (infusion 210 +/- 40 mmol, bolus 150 +/- 20 mmol, p = 0.0045) were significantly higher after treatment with continuous infusion than with bolus injection, despite significantly lower urinary furosemide excretion (infusion 310 +/- 60 mg every 24 h, bolus 330 +/- 60 mg every 24 h, p = 0.0195). The maximal plasma furosemide concentration was significantly higher after bolus injection than during continuous infusion (infusion 24 +/- 5 micrograms/ml, bolus 95 +/- 20 micrograms/ml, p < 0.0001). Short-term, completely reversible hearing loss was reported only after bolus injection in 5 patients. CONCLUSIONS We conclude that in patients with severe heart failure, high dose furosemide administered as a continuous infusion is more efficacious than bolus injection and causes less ototoxic side effects.

Multidrug resistance protein 4 (MRP4/ABCC4): a versatile efflux transporter for drugs and signalling molecules.

Multidrug resistance protein (MRP) 4 is a member of the MRP/ABCC subfamily of ATP-binding cassette transporters, which are capable of pumping a wide variety of endogenous and xenobiotic organic anionic compounds out of the cell. In addition to its role in the body distribution and renal excretion of a wide variety of antiviral, cytostatic, antibiotic and cardiovascular drugs, MRP4/ABCC4 has the remarkable ability to transport molecules involved in cellular signalling. These molecules include cyclic nucleotides, eicosanoids, urate and conjugated steroids. The unique structure, regulation and dual localisation of MRP4 in polarised cells could be connected with a key function in cellular protection and extracellular signalling pathways. This review focuses on recent insights into the versatile transport function of MRP4 and its potential as a new therapeutic target to modulate various pathophysiological signalling processes.

Interaction of Nonsteroidal Anti-Inflammatory Drugs with Multidrug Resistance Protein (MRP) 2/ABCC2- and MRP4/ABCC4-Mediated Methotrexate Transport

Methotrexate (MTX) has been used in combination with nonsteroidal anti-inflammatory drugs (NSAIDs) in the treatment of inflammatory diseases as well as malignancies. Especially at high MTX dosages, severe adverse effects with this combination may occur, usually resulting from an impaired renal elimination. It has been shown that the mechanism of this interaction cannot be fully attributed to inhibition of basolateral MTX uptake in renal proximal tubules. Here, we studied the effect of various NSAIDs on MTX transport in membrane vesicles isolated from cells overexpressing the proximal tubular apical efflux transporters human multidrug resistance protein (MRP) 2/ABCC2 and MRP4/ABCC4. MTX was transported by MRP2 and MRP4 with Km values of 480 ± 90 and 220 ± 70 μM, respectively. The inhibitory potency of the NSAIDs was generally higher against MRP4- than MRP2-mediated MTX transport, with therapeutically relevant IC50 values, ranging from approximately 2 μM to 1.8 mM. Salicylate, piroxicam, ibuprofen, naproxen, sulindac, tolmetin, and etodolac inhibited MRP2- and MRP4-mediated MTX transport according to a one-site competition model. In some cases, more complex interaction patterns were observed. Inhibition of MRP4 by diclofenac and MRP2 by indomethacin and ketoprofen followed a two-site competition model. Phenylbutazone stimulated MRP2 and celecoxib MRP4 transport at low concentrations and inhibited both transporters at high concentration. Our data suggest that the inhibition by NSAIDs of renal MTX efflux via MRP2 and MRP4 is a potential new site and mechanism contributing to the overall interaction between these drugs.

INTRAVENOUSLY ADMINISTERED SHORT INTERFERING RNA ACCUMULATES IN THE KIDNEY AND SELECTIVELY SUPPRESSES GENE FUNCTION IN RENAL PROXIMAL TUBULES

Different gene-silencing methods, like antisense and short interfering RNA (siRNA), are widely used as experimental tools to inhibit gene expression. In the present study, the in vivo behavior of siRNA in rats and siRNA-mediated silencing of genes in the renal proximal tubule were investigated. To study the biodistribution of siRNA, rats were injected i.v. with radiolabeled siRNA or radiolabel alone (control), and scintigraphic images were acquired at different time intervals postinjection. The siRNA preferentially accumulated in the kidneys and was excreted in the urine. One hour after injection, the amount of siRNA present in both kidneys (1.7 ± 0.3% of injected dose/g tissue) was on average 40 times higher than in other tissues (liver, brain, intestine, muscle, lung, spleen, and blood). Besides the biodistribution, the effect of siRNA on multidrug resistance protein isoform 2 (Mrp2/Abcc2, siRNAMrp2) in renal proximal tubules was investigated. Mrp2 function was assessed by measuring the excretion of its fluorescent substrate calcein in the isolated perfused rat kidney. Four days after administration, siRNAMrp2 reduced the urinary calcein excretion rate significantly (35% inhibition over the period 80–150 min of perfusion). This down-regulation was specific because another siRNA sequence directed against a different transporter in the proximal tubule, Mrp4 (Abcc4, siRNAMrp4), did not alter the Mrp2-mediated excretion of calcein. In conclusion, siRNA accumulates spontaneously in the kidney after i.v. injection, where it selectively suppresses gene function in the proximal tubules. Therefore, i.v. administered siRNA provides a novel experimental and potential therapeutic tool for gene silencing in the kidney.

The Role of ATP Binding Cassette Transporters in Tissue Defense and Organ Regeneration

ATP binding cassette (ABC) transporters are ATP-dependent membrane proteins predominantly expressed in excretory organs, such as the liver, intestine, blood-brain barrier, blood-testes barrier, placenta, and kidney. Here, they play an important role in the absorption, distribution, and excretion of drugs, xenobiotics, and endogenous compounds. In addition, the ABC transporters, P-glycoprotein (P-gp/ABCB1) and breast cancer resistance protein (BCRP/ABCG2), are highly expressed in a population of primitive stem cells: the side population (SP). SP cells were originally discovered in bone marrow by their capacity to exclude rhodamine 123 and Hoechst dye 33342; however, extensive research also revealed their presence in other nonhematopoietic tissues. The expression levels of BCRP and P-gp are tightly controlled and may determine the differentiation of SP cells toward other more specialized cell types. Although their exact function in these cells is still not clear, they may protect the cells by pumping out toxicants and harmful products of oxidative stress. Transplantation studies in animals revealed that bone marrow-derived SP cells contribute to organ repopulation and tissue repair after damage, e.g., in liver and heart. The role of SP cells in regeneration of damaged kidney segments is not yet clarified. This review focuses on the role of ABC transporters in tissue defense and regeneration, with specific attention to P-gp and BCRP in organ regeneration and repair.

Contribution of Multidrug Resistance Protein 2 (MRP2/ABCC2) to the Renal Excretion of p-aminohippurate (PAH) and Identification of MRP4 (ABCC4) as a Novel PAH Transporter

p-Aminohippurate (PAH) is the classical substrate used in the characterization of organic anion transport in renal proximal tubular cells. Although basolateral transporters for PAH uptake from blood into the cell have been well characterized, there is still little knowledge on the apical urinary efflux transporters. The multidrug resistance protein 2 (MRP2/ABCC2) is localized to the apical membrane and mediates ATP-dependent PAH transport, but its contribution to urinary PAH excretion is not known. In this report, we show that renal excretion of PAH in isolated perfused kidneys from wild-type and Mrp2-deficient (TR(-)) rats is not significantly different. Uptake of [(14)C]PAH in membrane vesicles expressing two different MRP2 clones isolated from Sf9 and MDCKII cells exhibited a low affinity for PAH (Sf9, 5 +/- 2 mM; MDCKII, 2.1 +/- 0.6 mM). Human MRP4 (ABCC4), which has recently been localized to the apical membrane, expressed in Sf9 cells had a much higher affinity for PAH (K(m) = 160 +/- 50 microM). Various inhibitors of MRP2-mediated PAH transport also inhibited MRP4. Probenecid stimulated MRP2 at low concentrations but had no effect on MRP4; but at high probenecid concentrations, both MRP2 and MRP4 were inhibited. Sulfinpyrazone only stimulated MRP2, but inhibited MRP4. Real-time PCR and Western blot analysis showed that renal cortical expression of MRP4 is approximately fivefold higher as compared with MRP2. MRP4 is a novel PAH transporter that has higher affinity for PAH and is expressed more highly in kidney than MRP2, and may therefore be more important in renal PAH excretion.

Thiazide-Induced Vasodilation in Humans Is Mediated by Potassium Channel Activation

-Hydrochlorothiazide and indapamide are thought to exert their hypotensive efficacy through a combined vasodilator and diuretic effect, but in vivo evidence for a direct vascular effect is lacking. The presence and mechanism of a direct vascular action of hydrochlorothiazide in vivo in humans were examined and compared with those of the thiazide-like drug indapamide. Forearm vasodilator responses to infusion of placebo and increasing doses of hydrochlorothiazide (8, 25, and 75 microg. min-1. dL-1) into the brachial artery were recorded by venous occlusion plethysmography. Dose-response curves were repeated after local tetraethylammonium (TEA) administration to determine the role of potassium channel activation and, in patients with the Gitelman syndrome, to determine the role of the thiazide-sensitive Na-Cl cotransporter in the vasodilator effect of hydrochlorothiazide. Vascular effects of hydrochlorothiazide were compared with those of indapamide in both normotensive (mean arterial pressure, 85+/-7 mm Hg) and hypertensive (mean arterial pressure, 124+/-16 mm Hg) subjects. At the highest infusion rate, local plasma concentrations of hydrochlorothiazide averaged 11.0+/-1.6 microg/mL, and those of indapamide averaged 7. 2+/-1.5 microg/mL. In contrast to indapamide, hydrochlorothiazide showed a direct vascular effect (maximal vasodilation, 55+/-14%; P=0. 013), which was inhibited by TEA (maximal vasodilation after TEA, 13+/-10%; P=0.02). The response was not dependent on blood pressure and was similar in patients with Gitelman syndrome, indicating that absence of the Na-Cl cotransporter does not alter the vasodilatory effect of hydrochlorothiazide. The vasodilator effect of hydrochlorothiazide in the human forearm is small and only occurs at high concentrations. The mechanism of action is not mediated by inhibition of vascular Na-Cl cotransport but involves vascular potassium channel activation. In contrast, indapamide does not exert any direct vasoactivity in the forearm vascular bed.

Direct vascular effects of furosemide in humans

BACKGROUND In humans, hemodynamic changes observed within minutes after systemic administration of furosemide are often referred to as direct vasoactivity. However, these immediate changes do not per se imply a direct vascular effect. We examined the genuine direct vascular effects of furosemide on the human forearm vascular bed and dorsal hand vein. METHODS AND RESULTS Forearm blood flow in response to infusion of increasing dosages of furosemide into the brachial artery was recorded by venous occlusion plethysmography. Local plasma concentrations of furosemide reached a maximum of 234+/-40 microg/mL during the highest infused dose but did not significantly affect the ratio of flow in the infused/noninfused arms. Venous distensibility of a dorsal hand vein was measured with a linear variable differential transformer. During precontraction with norepinephrine, five increasing dosages of furosemide (1 to 100 microg/min) were administered locally. Additional experiments using local administration of indomethacin or N(G)-monomethyl-L-arginine (L-NMMA) were carried out to determine whether effects were dependent on local prostaglandin or nitric oxide synthesis, respectively. Also, the effects of systemic administration of furosemide were examined. Local administration of furosemide led to a dose-dependent venorelaxation of 18+/-6% at the first to 72+/-16% at the last dose. Indomethacin almost completely abolished furosemide-induced venorelaxation, whereas L-NMMA had no effect. Systemic administration of furosemide resulted in a time-dependent increase of hand vein distensibility, reaching 45+/-11% after 8 minutes. CONCLUSIONS Furosemide does not exert any direct arterial vasoactivity in the human forearm, even at supratherapeutic concentrations. In contrast, at concentrations estimated to be in the therapeutic range, we observed a dose-dependent direct venodilator effect on the dorsal hand vein that appears to be mediated by local vascular prostaglandin synthesis.

Interaction of sulphonylurea derivatives with vascular ATP-sensitive potassium channels in humans

SummaryCardiovascular adenosine-5′-triphosphate-sensitive potassium (KATP) channels have been reported to play an important role in endogenous cardioprotective mechanisms. Sulphonylurea derivatives can inhibit these cardioprotective mechanisms in animal models. We investigated whether therapeutic concentrations of sulphonylurea derivatives can block vascular KATP channels in humans. The forearm vasodilator responses to administration of the specific KATP channel opener diazoxide into the brachial artery of healthy male volunteers were recorded by venous occlusion plethysmography. This procedure was repeated with concomitant intraarterial infusion of: 1) the sulphonylurea derivative glibenclamide (0.33 or 3.3 Μg · min−1 · dl−1, both n=12), 2) the new sulphonylurea derivative glimepiride (2.5 Μg · min−1 · dl−1, n=12) or 3) placebo (n=12). The effects of glibenclamide on the vasodilator responses to sodium nitroprusside were also studied (n=12). Glibenclamide significantly inhibited the diazoxide-induced increase in forearm blood flow ratio (ANOVA with repeated measures: p<0.01). During the highest diazoxide dose this ratio (mean ± SEM) was lowered from 892±165 to 449±105%, and from 1044±248 to 663±114% by low- and high-dose glibenclamide, respectively. In contrast, neither glimepiride nor placebo attenuate diazoxide-induced vasodilation. Furthermore, glibenclamide did not affect nitroprusside-induced vasodilation. We conclude that therapeutic concentrations of the classical sulphonylurea derivative glibenclamide result in significant blockade of vascular KATP channels in humans. The newly developed glimepiride seems to be devoid of these properties.

Mechanisms of renal anionic drug transport.

By utilizing filtration, active secretion and reabsorption processes, the kidney can conserve essential nutrients, and eliminate drugs and potentially toxic compounds. Active uptake of organic anions and cations across the basolateral membrane, and their extrusion into the urine across the brush border membrane mainly takes place in the renal proximal tubule cells, and is facilitated via a range of substrate-specific tubular transporters. Many drugs and their phase II conjugates are anionic compounds, and therefore renal organic anion transporters are important determinants of their distribution and elimination. Competition for renal excretory transporters may cause drugs to accumulate in the body leading to toxicity, which is a potential hazard of concomitant drug administration. Here, we present a brief update on the most prominent human proximal tubule organic anion transporters, which either belong to the ATP-binding cassette (ABC) or the solute carrier transporter (SLC) families. We focus on the participation of the individual transporters in renal anionic drug elimination, in an attempt to understand their overall biological and pharmacological significance, hoping to inspire further studies in the renal transporters field.