Role of Plasma Protein Binding on Renal Metabolism and Dynamics of Furosemide in the Rabbit

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Vol. 27, Issue 1, 81-85, January 1999

Role of Plasma Protein Binding on Renal Metabolism and Dynamics of Furosemide in the Rabbit

Vincent Pichette, David Geadah, and Patrick du Souich

Service de néphrologie, Hopital Maisonneuve-Rosemont and Département de Pharmacologie, Faculté de Médecine, Université de Montréal

	Abstract

Top Abstract Introduction Materials and methods Results Discussion References

To investigate the influence of furosemide plasma protein binding on its kinetics and dynamics, the kinetics of furosemidewas studied in the presence of a protein binding displacer, warfarin,and in hypoalbuminemic rabbits. Compared with controls, in anesthetizedrabbits pretreated with warfarin, the unbound fraction of furosemideincreased from 1.8 ± 0.4% to 7.0 ± 0.4% (p < .001), and its metabolicclearance increased by 30%, whereas furosemide urinary excretiondecreased by 48% (p < .05). Experiments in nephrectomized rabbitsshowed that the increase in metabolic clearance was secondaryto an increase in its renal metabolic clearance (p < .05). Comparedwith controls, in warfarin pretreated rabbits, sodium excretionand diuresis were decreased by 30% (p < .05). However, when furosemidewas injected mixed with albumin, warfarin-induced kinetic anddynamic alterations of furosemide were reversed. Compared withcontrol rabbits, in conscious hypoalbuminemic rabbits, furosemideunbound fraction was enhanced from 1.2 ± 0.1% to 5.5 ± 0.5% (p< .001), and its urinary excretion, diuresis, and sodium excretionwere reduced by 22% (p < .05). The administration of warfarinto hypoalbuminemic rabbits further increased the fraction of unboundfurosemide, and diminished its urinary excretion and diureticeffect. In conclusion, 1) binding of furosemide to plasma proteins,and not albumin per se, facilitates its renal secretion and pharmacologicalresponse; 2) the decrease in furosemide binding, secondary todrug displacement and/or hypoalbuminemia, can be a cause of resistanceto the diuretic; and 3) when furosemide binding is decreased,the administration of furosemide mixed with albumin enhances itsrenal secretion and diureticeffect.

	Introduction

Top Abstract Introduction Materials and methods Results Discussion References

In mutant analbuminemic rats, the renal secretion of mercapturic acid, phenolsulfophthaleic acid, and furosemide is diminished,whereas their volume of distribution is increased (Okajima etal., 1985; Inoue et al., 1985, 1987), suggesting that albuminserves as a vector for the transport of drugs to the kidney (Inoueet al., 1987). On the other hand, according to results obtainedwith isolated perfused kidneys or proximal tubules, it has beenproposed that albumin directly facilitates the cellular uptakeand secretion of organic anions (Depner et al., 1984; Besseghiret al., 1989), promotion that appears unrelated to the extentof organic anion binding to albumin (Besseghir et al., 1989).

Furosemide is eliminated by renal excretion, proximal tubular secretion, and biotransformation to approximately the same extent(Hammarlund-Udenaes and Benet, 1989; Ponto and Schoenwald, 1990a,b).In the rabbit, the major site for the biotransformation of furosemideis the kidney (Pichette and du Souich, 1996). Moderate hypoalbuminemiais associated with a decrease in the renal proximal tubular secretionof furosemide and an increase in its renal metabolic clearance,suggesting that in vivo albumin or the binding to albumin facilitatesthe renal secretion of furosemide but limits its renal metabolism(Pichette et al., 1996).

The modifications in the pharmacokinetics of furosemide induced by hypoalbuminemia or analbuminemia are associated with significantalterations in the pharmacodynamics of furosemide, i.e., a reductionin the excretion of sodium and in the urinary volume (Inoue etal., 1987; Pichette et al., 1996). In analbuminemic rats, thedecrease in the renal secretion of furosemide and in its natriureticand diuretic effects is prevented when furosemide is administeredmixed with albumin (Inoue et al., 1987), suggesting that the bindingof furosemide to plasma proteins is the limiting factor and notalbumin plasma levels as proposed by others (Depner et al., 1984;Besseghir et al., 1989).

To determine whether the changes in the pharmacokinetics and pharmacodynamics of furosemide induced by hypoalbuminemic conditionsare associated to the binding of furosemide to albumin or to theconcentration of albumin itself, the disposition and dynamicsof furosemide have been studied in 1) control rabbits and rabbitspretreated with warfarin, a known displacer of furosemide fromits binding sites to albumin; 2) functionally nephrectomized rabbitswith and without pretreatment with warfarin; 3) rabbits pretreatedwith warfarin but receiving furosemide mixed with albumin; and4) rabbits with moderate hypoalbuminemia with and without warfarinpretreatment.

	Materials and Methods

Top Abstract Introduction Materials and methods Results Discussion References

Experimental Model. Male New Zealand rabbits (Ferme Cunicole, Mirabel, Canada) weighing 2.2 to 2.8 kg were individually housed in ventilated metaboliccages and maintained on Purina pellets and water ad libitum. Anacclimatization of at least 7 days was allowed for the animalsbefore any experimental work was undertaken. The rabbits weresegregated into eight groups. The rabbits in five groups wereanesthetized, and in the remaining three groups, the rabbits wereconscious. All the experiments were conducted according to theCanadian Council on Animal Care guidelines for care and use oflaboratoryanimals.

Effect of Warfarin on Furosemide Disposition and Dynamics in Anesthetized Rabbits. Rabbits were fasted for at least 12 h before surgery. A lateral vein of an ear was cannulated with a Butterfly-25 (Venisystem;Abbot Ireland, Sligo, Ireland) for the infusion of 0.9% NaCl atthe rate of 30 ml/h to compensate for the loss of water and allowfor blood sampling. Urinary losses secondary to the injectionof furosemide were replaced with a solution of 0.9% NaCl. Anesthesiawas induced by injecting 30 mg/kg sodium pentobarbital througha cannula (Butterfly-25) inserted into the lateral vein of theopposite ear; the trachea was exposed, and an endotracheal tube(CDMV; ST-Hyacinthe, Québec, Canada) was inserted between thefourth and fifth tracheal rings, caudally to the thyroid cartilage,for artificial ventilation (21 ml/cycle, 48 cycles/min) (HarvardApparatus, Boston, MA). The right femoral artery was dissected,and a polyethylene tube (P-60; Intramedic, Becton Dickinson, Parsippany,NJ) was inserted into the abdominal aorta, above the renal arteries,for blood sampling and arterial blood pressure measurement. Finally,a vesical catheter (Bardex Foley 8 Ch/Fr; Mississauga, Ontario,Canada) was installed to collecturine.

Once anesthetized, in sham and in rabbits with functional nephrectomy, the abdomen was opened by a midline incision to haveaccess to the kidneys by clearing the surrounding tissues. Functionalnephrectomy was produced by ligating both renal pedicles as describedelsewhere (Pichette and du Souich, 1996

). The surgical procedurewas completed in less than 20 min. Throughout the experiment,pH, PaO, and PaCO₂ were measured in arterial blood samples withan automated, computerized 1312 pH and oxygen analyzer (InstrumentationLaboratory, Lexington, MA), and arterial blood pressure was monitoredvia a three-way stopcock (Seamless, Division of Professional MedicalProducts, Inc., Ocala, FL) connected to a pressure transducer(E & M Instruments, Houston, TX) and a physiograph (E & MInstruments).

Five groups of anesthetized rabbits were used. The first three groups (n = 6/group) were sham animals. Rabbits of the firstgroup (control animals) received an i.v. dose of 2.5 mg/kg offurosemide. Rabbits of the second group received an i.v. doseof 50 mg/kg warfarin 3 min before the injection of furosemide(2.5 mg/kg). The rabbits of the third group received warfarin(50 mg/kg) 3 min before the injection of furosemide (2.5 mg/kg)mixed with human albumin (25%), which was prepared 10 min beforethe experiment. Preliminary experiments showed that human albuminbinds furosemide as well as rabbit albumin, and single, acuteadministration of human albumin to rabbits is well tolerated.A total of 187.5 mg/kg of albumin was injected into each rabbit.In all rabbits, the glomerular filtration rate (GFR)¹ was assessed by measuring the clearance of inulin. The rabbitsreceived an i.v. dose of 20 mg/kg of inulin, followed by an infusionat the rate of 1 mg/min; blood (0.75 ml) was withdrawn at 60,80, 90, 100, and 110 min, and inulin was assayed in plasma byspectrophotometry (Schreiner, 1950

). The anesthetized rabbitsof the last two groups (n = 4/group) underwent a functional nephrectomy.The rabbits of one group were pretreated with warfarin (50 mg/kg),whereas the rabbits of both groups received furosemide (2.5 mg/kg).The dose of furosemide used was selected according to the factthat the kinetics of furosemide injected i.v. are first orderup to doses of 10 mg/kg (Homsy et al., 1995

In all rabbits, immediately after the sham laparotomy or functional nephrectomy, furosemide was injected within 1 min. Ingroups 1 to 3, blood samples (1.0 ml) were withdrawn at 0, 6,10, 15, 20, 25, 30, 40, 50, and 60 min. In groups 4 and 5 (functionalnephrectomy), blood samples were withdrawn at 0, 6, 10, 15, 20,25, 30, 45, 60, 90, 120, and 150 min. In addition, 4 ml of bloodwas withdrawn from each rabbit at 3 min to assess furosemide proteinbinding and warfarin concentration. Urine was collected for 60min. Plasma and urine were stored at $-$ 20°C in tubes protectedfrom light until furosemide was assayed. Furosemide in plasmaand urine was assayed by high-performance liquid chromatographyas described elsewhere (Lambert et al., 1982

). Because warfarinis a weak acid with pK_a of 4.8, the high-performance liquid chromatographyprocedure described for the assay of furosemide was adapted toassay warfarin, i.e., the mobile phase contained water and methanolat a ratio of 48:52 (v/v).

Binding of furosemide to plasma proteins was assessed by ultrafiltration. The 3-min blood sample was selected a) to assessthe binding of furosemide at peak plasma concentrations, whichrange between 20 and 30 µg/ml; b) because preliminary in vitrostudies demonstrated that furosemide binding to plasma proteinswas independent of furosemide concentrations included in the rangeof 10 to 25 µg/ml; and c) because even if lower furosemide concentrationsmay slightly increase furosemide binding, a change that shouldnot distort the interpretation of the results, the accuracy offurosemide assay is greater at high concentrations. In previousstudies, it was confirmed that the experimental procedures (anesthesiaand surgery) do not modify furosemide plasma protein binding (Pichetteand du Souich, 1996

). Plasma (1.0 ml) was centrifuged at 3500rpm in Centrifree System devices (Amicon; W.R. Grace & Co., Beverly,MA) for 30 min at 25°C. The concentration of unbound furosemidewas assayed in 250 µl of the resultingultrafiltrate.

Sodium, urea, creatinine, and albumin in plasma and creatinine in urine were determined with a Hitachi 717 analyzer (BoehringerMannheim Canada, Laval, Québec, Canada). Urinary sodium was assayedwith an automatic flame photometer (model 11943; InstrumentationLaboratory Inc., Lexington, MA). Urinary pH was measured in eachurine collection with an Acumet model 230 pH/ion meter (FisherScientific, Fairlawn,NJ).

Effect of Hypoalbuminemia and Warfarin on Furosemide Dynamics in Conscious Rabbits. To determine whether a smaller dose of warfarin could displace furosemide from its binding sites to albumin in conscious hypoalbuminemicrabbits, the dynamics of furosemide (2.5 mg/kg) were studied in12 conscious rabbits, 4 controls, 4 with moderate hypoalbuminemia,and 4 with moderate hypoalbuminemia who were pretreated with warfarin(5 mg/kg). Hypoalbuminemia was induced by repeated plasmapheresisof 10 ml/kg at a rate of five exchanges daily for 2 days, a techniquethat does not induce changes in blood pressure or GFR (Pichetteet al., 1996). Furosemide was injected through a cannula (Butterfly-25)inserted into a lateral vein of an ear and warfarin through anothercannula inserted into the lateral vein of the opposite ear. Avesical catheter (Bardex Foley 8 Ch/Fr, Mississauga, Ontario,Canada) was installed to collect urine. Urinary losses inducedby furosemide were replaced with 0.9% NaCl. At 3 min, 4 ml ofblood was withdrawn to assess furosemide binding to plasma proteinsand warfarin concentrations. Urine was collected for 60 min. GFRwas assessed by measuring the clearance of creatinine. Furosemide,warfarin, sodium, urea, creatinine, and albumin were assayed inthe 3-min plasma sample, and furosemide and creatinine were measuredin the 60-min urine collection as describedabove.

Drugs Used. Furosemide was purchased from Sabex (Montréal, Québec, Canada). Methyl ester of furosemide was donated by Hoechst-Marion-RousselCanada (Montreal, Quebec, Canada). Inulin and warfarin were obtainedfrom Sigma Chemical Company (St. Louis, MO). Human albumin wasobtained from Bayer Corporation Inc. (Etobicoke, Ontario,Canada).

Data Analysis. Furosemide terminal half-life (T_1/2), area under its plasma concentration-time curve (AUC_0-60 or AUC_0-150), systemicclearance, and predicted apparent volume of distribution at steadystate were estimated according to noncompartmental analysis basedon statistical moment theory (Gibaldi and Perrier, 1982) withthe computer program Pharmacokinetic Data Analysis Program includedin Lotus 1,2,3, Version 2.2 (Lotus Development Corporation, Cambridge,MD). The urinary clearance of furosemide (Cl_u) was calculatedwith the following equation: Cl_u = Xu_0-t/AUC_0-t; whereXu_0-t is the amount of furosemide excreted unchanged inthe urine during the experiment. Furosemide metabolic clearancewas estimated by subtracting Cl_u from systemic clearance. In anesthetizedrabbits, GFR was assumed to be equal to the clearance of inulin,which was calculated as follows: Cl = inulin infusion rate andsteady-state plasma concentration. On the other hand, in consciousrabbits, GFR was estimated by dividing the urinary excretion rateof creatinine by creatinine plasma concentration. Fractional excretionof sodium (FeNa) was estimated by the ratio of the sodium excretedover the sodium filtered (GFR × sodium plasmaconcentration).

The results are expressed as mean ± S.E. Differences between groups were assessed with an unpaired Student's t test or ananalysis of variance test with Fisher's correction for multiplecomparisons. The threshold of significance was p < .05.

	Results

Top Abstract Introduction Materials and methods Results Discussion References

Anesthetized Rabbits. Hemodynamic and biochemical parameters. After anesthesia and surgical manipulations, mean arterial pressure was not affected by the administration of warfarin oralbumin, i.e., 64 ± 2, 62 ± 4, and 66 ± 3 mm Hg in the control,warfarin, and albumin groups, respectively. After the injectionof furosemide, there was a small drop in blood pressure (5 mmHg) in each group, although thereafter blood pressure remainedconstant during the experiment. Functional nephrectomy did notmodify arterial blood pressure in either control or warfarin pretreatedrabbits.

Compared with baseline values of the rabbits, the coadministration of furosemide with human albumin (187.5 mg/kg) raised plasmaalbumin concentration from 33.7 ± 0.9 to 36.2 ± 1.0 g/liter (p< .05). However, the biochemical parameters (including albumin)and GFR did not differ between the groups (Table 1).

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TABLE 1
Biochemical and renal function parameters in anesthetized rabbits, control rabbits, and rabbits receiving warfarin (50 mg/kg) alone or with albumin (187.5 mg/kg)

Furosemide kinetics in control and warfarin-pretreated rabbits with or without albumin coadministration. In rabbits pretreated with warfarin, mean plasma concentrations of furosemide administered alone or with albumin were essentiallyidentical with those estimated in control rabbits (Fig. 1). However,peak plasma concentrations of furosemide were lower in the grouptreated with warfarin than in the other two groups (Table 2).In plasma of control rabbits, the unbound fraction of furosemidewas 1.8%, and pretreatment with warfarin increased the unboundfraction of furosemide to 7% (p < .05). The administration offurosemide mixed with albumin restored the unbound fraction tocontrol values (Table 2). The furosemide apparent volume of distributiontended to increase (p > .05) in rabbits being pretreated withwarfarin.

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Fig. 1. Mean plasma concentrations of furosemide (2.5 mg/kg) as a function of time following i.v. injection into anesthetized rabbits, control rabbits without ( $open circle$ ) or with ( $triangle$ ) a functional nephrectomy, rabbits pretreated with warfarin (50 mg/kg) without ( $bullet$ ) and with ( $black-triangle$ ) a functional nephrectomy, and rabbits in which furosemide was mixed with 187.5 mg/kg albumin and injected after the pretreatment with warfarin ( $black-square$ ).

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TABLE 2
Kinetic parameters of furosemide injected (2.5 mg/kg) to anesthetized rabbits, control rabbits, and rabbits receiving warfarin (50 mg/kg) alone or with albumin (187.5 mg/kg)

In the control group, systemic clearance of furosemide was 11.2 ± 0.8 ml·min¹·kg¹, of which 54% corresponded to urinary and 46% to metabolic clearance(Table 2). Compared with control rabbits, pretreatment with warfarindid not modify the value of the systemic clearance of furosemide;however, furosemide metabolic clearance increased by 31% (p <.05), and furosemide urinary clearance decreased by 54% (p < .05).The changes in furosemide metabolic and urinary clearances werealmost totally precluded when the rabbits received the diureticmixed with albumin (Table 2). Compared with control rabbits,warfarin reduced the urinary recovery of furosemide by 46%. Whenthe diuretic was injected mixed with albumin, furosemide urinaryrecovery increased to reach baseline control values (Table 2).The urinary excretion of furosemide was negatively correlatedwith its unbound fraction in all groups (r = 0.65, p < .05).

Furosemide kinetics in rabbits with functional nephrectomy. In control nephrectomized rabbits, plasma concentrations of albumin, creatinine, and urea did not differed from normal values.Functional nephrectomy reduced the slope of the decline of furosemideplasma concentrations in both control and warfarin pretreatedrabbits to a similar extent (Fig. 1). Compared with control rabbits(Table 2), functional nephrectomy decreased furosemide volumeof distribution by about 30% and systemic clearance of furosemideby 85% (p < .05), secondary to the abolition of its renal excretionand the reduction in its metabolic clearance (p < .05) (Table3). In rabbits with functional nephrectomy, warfarin did notmodify furosemide pharmacokinetic parameters, i.e., mean valuesof systemic clearance and volume of distribution were identicalwith those estimated in rabbits with functional nephrectomy withoutwarfarin pretreatment (Table 3). These results suggest that theincrease in furosemide metabolic clearance induced by warfarinin rabbits without functional nephrectomy is secondary to an increasein the renal metabolic clearance of furosemide.

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TABLE 3
Kinetic parameters of furosemide injected (2.5 mg/kg) to anesthetized rabbits subjected to a functional nephrectomy in absence or in presence of warfarin (50 mg/kg)

Furosemide dynamics in control and warfarin pretreated rabbits. Compared with control rabbits, in rabbits pretreated with warfarin, the urinary excretion rate of furosemide, decreased byalmost 50% (from 2784 ± 214 to 1451 ± 111 µg/h; p < .05). Consequently,the rate of sodium excretion as well as the diuresis were diminishedby the same proportion (Fig. 2). In control animals, fractionalexcretion of sodium was 15.7 ± 1.8%, and decreased to 10.9 ± 1.0%(p < .05) in rabbits pretreated with warfarin. When furosemidewas injected mixed with albumin to rabbits pretreated with warfarin,furosemide excretion rate and fractional excretion of sodium increasedto values similar to those observed in control rabbits, i.e.,2682 ± 283 µg/h and 15.4 ± 1.1%, respectively. Moreover, sodiumexcretion and diuresis attained control values (Fig. 2). Natriuresisand diuresis were positively correlated with furosemide excretion(r = 0.77, p < .001; r = 0.73, p < .001).

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Fig. 2. Diuresis (open columns) and sodium excretion rate (solid columns) following the i.v. injection of furosemide (2.5 mg/kg) to anesthetized rabbits, control rabbits, rabbits pretreated with warfarin (50 mg/kg), and rabbits pretreated with warfarin but which received furosemide mixed with albumin (187.5 mg/kg).

Vertical columns are S.E. *p < .05 compared with control and warfarin plus albumin rabbits.

Conscious Rabbits. Furosemide dynamics in conscious rabbits with hypoalbuminemia and warfarin. Compared with control rabbits, hypoalbuminemia increased the fraction of unbound furosemide in plasma (p < .05) and decreasedthe urinary recovery of furosemide, but the GFR remained unchanged(Table 4). As a consequence, in hypoalbuminemic rabbits, furosemideresponse, as assessed by the sodium excretion rate and the urinaryvolume, was decreased by 21%. Pretreatment of hypoalbuminemicrabbits with 5 mg/kg warfarin further enhanced the fraction ofunbound furosemide and reduced its urinary recovery (Table 4).Consequently, sodium excretion rate and urinary volume were decreasedby 33% and 19%, respectively (p < .05), compared with hypoalbuminemicrabbits not pretreated with warfarin. Natriuresis and diuresiswere positively correlated with furosemide excretion (r = 0.78,p < .001; r = 0.75, p < .001).

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TABLE 4
Dynamic parameters of furosemide injected (2.5 mg/kg) to conscious rabbits, control rabbits, and rabbits with moderate hypoalbuminemia in absence or in presence of warfarin (5 mg/kg)

	Discussion

Top Abstract Introduction Materials and methods Results Discussion References

This study demonstrates that warfarin increases the unbound fraction of furosemide by almost 300%, leading to an increasein its renal metabolic clearance and to a decrease in its urinaryexcretion. Moreover, the administration of warfarin is associatedwith a marked reduction in natriuretic and diuretic effects offurosemide. The effect of warfarin on the kinetics of furosemideis essentially elicited at the renal level, because in rabbitswith functional nephrectomy, warfarin also enhanced furosemideunbound fraction by 300% but did not affect furosemide extrarenalclearance or its volume ofdistribution.

It is unlikely that the decrease in furosemide urinary clearance may be secondary to a direct interaction with warfarin atthe level of tubular secretion, because this drug is neither secretedby the proximal tubule nor metabolized in the kidney (Ganevalet al., 1985; Shetty et al., 1989). Further support of such astatement is the fact that the warfarin-induced changes in furosemidekinetics and dynamics were completely reversed when the diureticwas injected mixed with albumin, despite similar plasma concentrationof warfarin. Therefore, the changes in the kinetics of furosemidereported in this study appear to be secondary to the displacementof furosemide from its binding sites to albumin and to an increasein its unboundfraction.

Warfarin induced changes in the kinetics of furosemide similar to those triggered by moderate hypoalbuminemia, i.e., increasein the renal metabolic clearance and reduction in the urinaryexcretion of furosemide (Pichette et al., 1996). In studies withisolated proximal tubules, it has been reported that albumin promotesthe proximal secretion of two organic anions, para-aminohippurateacid and methotrexate, an effect that appears unrelated to thebinding of the anions to albumin (Besseghir et al., 1989). Onthe other hand, the results of the present study indicate thatin vivo, albumin per se does not influence the proximal secretionof furosemide, because the levels of albumin in control rabbitswere similar to those measured in rabbits pretreated with warfarin.Further support that the binding of furosemide to albumin influencedits renal metabolism and secretion rather than albumin per seis the fact that when furosemide binding to albumin is enhancedto control values by the administration of the diuretic mixedwith albumin, the changes in furosemide kinetics induced by warfarinarereversed.

The present results indicate that binding of furosemide to albumin reduces its renal metabolism, whereas it enhances its secretion.To be excreted in the urine or metabolized by the kidney, furosemidemust enter the proximal tubular cell via an anion carrier (Pichetteand du Souich, 1996). Thus, the results of the present study couldtentatively be explained on the basis that distinct organic anioncarriers are present along the different segments of the proximaltubule. Because the cells of these segments differ in their functionin handling organic anions (either metabolism or secretion) (Schaliand Roch-Ramel, 1982; Grantham and Chonko, 1993), the basolateralcarriers could be modulated differently depending on the bindingof the organic anion. If this hypothesis holds true, basolateralcarriers located in the S2 segment, where the ability to secretean anion is higher (Grantham and Chonko, 1993), should have highaffinity for furosemide, which would explain an increase in itssecretion when its binding to albumin is increased. On the otherhand, basolateral carriers located in the S1 segment, where theability to conjugate drugs appears higher (Schali and Roch-Ramel,1982), should have low affinity for furosemide, explaining anincrease in its renal metabolism when its binding to albumin isdecreased. Further studies are needed to confirm suchhypothesis.

The results of the present study may tentatively be extrapolated to humans. Indeed, it has been reported that in patientswith heart failure who are treated with furosemide and who receiveda vitamin K anticoagulant concomitantly, furosemide volume ofdistribution and metabolic clearance were greater than the valuesreported in patients not receiving the anticoagulant (Andreasenand Mikkelsen, 1977).

Pretreatment of rabbits with warfarin produces a marked decrease in the diuretic response of furosemide, decrease that isprevented by the administration of furosemide mixed with albumin,i.e., by correcting the warfarin-induced reduction in furosemidebinding to plasma proteins. These results suggest that the displacementof furosemide from its binding sites to albumin could be a causeof diuretic resistance. Moreover, it could be a frequent mechanismof diuretic resistance, because there is a long list of drugscommonly used that are potential competitive displacers of furosemidebinding to albumin, i.e., phenytoin, tolbutamide, chlorpropamide,nonsteroidal anti-inflammatory agents, and sulfonamides (Sjoholmet al., 1979). For example, it has been shown that phenytoin reducesthe efficiency of furosemide by an unknown mechanism (Tongia,1981). In light of our results, it is tempting to speculate thatphenytoin decreased furosemide binding to albumin. The resultsof the present study may have clinical implications, because theysuggest that a condition associated with an increase in the unboundfraction of furosemide, i.e., hypoalbuminemia, drug-drug interactions,and disease states, could lead to a significant decrease in furosemideresponse.

The studies with anesthetized rabbits were conducted using a dose of warfarin (50 mg/kg) that generated plasma concentrationsof warfarin (182 ± 21 µg/ml) much greater than those usually attainedin humans (Chan et al., 1994). Because hypoalbuminemia, i.e.,albumin less than 35 g/liter, is a very frequent clinical conditionaffecting 3.1% of subjects older than 71 years (Salive et al.,1992), it was of interest to document the effect of moderate hypoalbuminemiacombined with smaller doses of warfarin on the natriuretic anddiuretic response to furosemide in conscious rabbits. The resultsshow that moderate hypoalbuminemia combined with doses of warfarinyielding plasma concentrations of 17.1 ± 1.7 µg/ml, which areclose to those obtained in humans (Chan et al., 1994), increasedthe unbound fraction of furosemide and decreased its pharmacologicalresponse. These results also suggest that in patients with moderatehypoalbuminemia, the administration of one or several acidic drugsthat may potentially displace furosemide from its binding sitescould be a cause of resistance todiuretics.

The rationale of combining furosemide with albumin in patients with severe hypoalbuminemia to promote its renal secretionand natriuretic response (Inoue et al., 1987) is reinforced bythe results of the present study. However, the success of thispractice may depend on the cause and/or severity of the hypoalbuminemia.For instance, in nephrotic patients with plasma concentrationsof albumin of 17.3 g/liter, the infusion of 0.5 g/kg of albumindid not increase the natriuretic or the diuretic effect of a highdose of furosemide (Akcicek et al., 1995). On the other hand,in nephrotic patients with plasma concentrations of albumin of27 g/liter, the administration of 40 g of albumin increased thediuresis to furosemide (Sjostrom et al., 1989). Several factorsmay explain the differences between these reports, such as themode of administration of albumin and furosemide (whether furosemidewas premixed with albumin or not), the severity of hypoalbuminemia,and the importance of the proteinuria known to bind furosemidein the tubular fluid (Kirchner et al., 1991).

In conclusion, the displacement of furosemide from its binding sites to albumin by warfarin enhances its unbound fraction.Consequently, there is an increase in the renal metabolism anda decrease in the proximal tubular secretion of furosemide, witha diminution in its natriuretic and diuretic response. Albuminappears to promote the renal secretion of furosemide by its roleas a ligand and not by a mechanism associated to its presence.From the results of this study we may postulate that the decreasein furosemide binding to albumin, secondary to hypoalbuminemiaand/or binding displacement, may be a frequent cause of resistanceto the diuretic that could be reversed by injecting the diureticmixed withalbumin.

	Acknowledgments

We are grateful to Lucie Héroux and Hélène Maurice for their skillful technical assistance and to Hoechst-Marion-RousselCanada Inc., who donated the methyl ester of furosemide used asstandard.

	Footnotes

Received March 30, 1998; accepted August 13, 1998.

This work was supported by the Medical Research Council of Canada (Grant MT-10874). Part of this work has been presented atthe 30th annual meeting of the American Society of Nephrologyin SanAntonio.

Send reprint requests to: Patrick du Souich, Department of Pharmacology, Faculty of Medicine, University of Montréal, Box 6128, Station "Centre Ville", Montréal, Québec Canada H3C 3J7. E-mail: dusouicp{at}ERE.UMontreal.CA

	Abbreviations

Abbreviations used are: GFR, glomerular filtration rate; AUC_0-60 or AUC_0-150, area under its plasma concentration-time curve, Cl_u, urinary clearance of furosemide.

	References

Top Abstract Introduction Materials and methods Results Discussion References

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