Tissue and Perfusate Pharmacokinetics of Melphalan in Isolated Perfused Rat Hindlimb

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Vol. 282, Issue 3, 1131-1138, 1997

Tissue and Perfusate Pharmacokinetics of Melphalan in Isolated Perfused Rat Hindlimb¹

Zhen-Yu Wu, B. Mark Smithers and Michael S. Roberts

Departments of Medicine (Z.Y.W., M.S.R.) and Surgery (B.M.S.), University of Queensland, Princess Alexandra Hospital, Brisbane, Queensland, Australia 4102

	Abstract

Top Abstract Introduction Methods Results Discussion Conclusion References

Melphalan is commonly used as a cytotoxic agent in isolated limb perfusion for locally recurrent malignant melanoma. The timecourse of melphalan concentrations in perfusate and tissues duringa 60-min melphalan perfusion and 30-min drug-free washout in thesingle-pass perfused rat hindlimb was examined using a physiologicallybased pharmacokinetic model. The rat hindlimbs were perfused withKrebs-Heinseleit buffer containing 4.7% bovine serum albumin (BSA)or 2.8% dextran 40 at a constant rate of 3.8 ml/min. The concentrationof melphalan in perfusate and tissues was determined by high-performanceliquid chromatography. The tissue concentrations of melphalanwere significantly higher with the perfusate containing dextranthan BSA during the 60-min perfusion. During the washout period,the melphalan concentration in the perfusates decreased rapidlyin first few minutes, followed by a slower monoexponential decline.The estimated half life (t_1/2) for melphalan removal from skinand fat was 59 ± 2 min for both BSA and dextran perfusates. However,the estimated t_1/2 for melphalan removal from muscle was 79 and96 min for BSA and dextran washout perfusates, respectively. Thepredicted concentration-time profiles obtained for melphalan withBSA and dextran perfusates appear to correspond closely to theobserved data. This study showed that the uptake of melphalaninto perfused tissues is impaired by the use of perfusates inwhich melphalan is highly bound. Melphalan washout from muscle,but not skin and fat, was facilitated by the use of perfusatesin which melphalan is highly protein bound.

	Introduction

Top Abstract Introduction Methods Results Discussion Conclusion References

ILP is a form of regional chemotherapy for cancer that involves the exposure of a tumour-bearing limb to a high concentrationof anticancer agent, although sparing the patient from systemictoxicity (Ghussen et al., 1989; Krementz et al., 1985; Krementzet al., 1987; Scott et al., 1992a, Thompson and Gianoutsos, 1992).Creech et al. (1958) first used the isolated cytotoxic limb perfusiontechnique to treat a patient with multiple superficial recurrencesof melanoma localised to the leg. The efficacy and safety of theprocedure has improved considerably and ILP is now widely acceptedas the treatment of choice for locally recurrent melanoma restrictedto the limbs, with response rates of 50 to 80% having been reported(Hartley and Fletcher, 1987; Baas et al., 1988; Krementz et al.,1987; Scott et al., 1992a; Hafstrom et al., 1991; Thompson etal., 1994). ILP has also been successfully used in treatment ofsarcomas of the extremities (Englund et al., 1971; Lejeune etal., 1988; Stehlin et al., 1984; Di Filippo et al., 1988; Kettelhacket al., 1990). The drug of choice in ILP for melanoma is melphalan.Although this drug has been in use for many years, an understandingof the pharmacokinetic behaviour of the melphalan in the perfusedtissues, on which an optimal dosage and treatment schedule couldbe based, has not been available (Hafstrom et al., 1984; Brieleet al., 1985; Benckhuijsen et al., 1986; Scott et al., 1992b).

Benckhuijsen et al. (1988) estimated the time course of tissue levels of melphalan during ILP using a biexponential modelfor the perfusate melphalan concentration versus time curves.Three previous studies (Scotter et al., 1987; Scott et al., 1992a;Klaase et al., 1994) have reported melphalan concentrations inthe limb perfusate and tissues during ILP. However, the tissueconcentrations of melphalan in these studies were generally lowerthan those calculated by Benckhuijsen et al. (1988) who also suggestedthat the uptake of melphalan into the normal tissues during ILPgreatly exceeded uptake by the tumor tissue. Quantitative dataon the amount of drug taken up by limb tissues during perfusionfor different perfusate conditions appears undefined but relevantin determining the optimal composition of perfusate to be usedin ILP.

Leakage of drug-containing medium into the systemic circulation after ILP is unavoidable, even if limited in extent (Hafstromet al., 1984; Lejeune and Ghanem, 1987). Systemic melphalan concentrationsare about 1 to 4% of peak concentrations in perfusate (Hafstromet al., 1984; Minor et al., 1985; Scott et al., 1992b). Rauscheckeret al. (1991) suggested that between 1.4 and 18% of the totalmelphalan dose reaches the systemic circulation after reconnection.They suggested that a careful washing-out procedure was neededto ensure that the unwanted escape of melphalan into the systemiccirculation was minimised (Rauschecker et al., 1991; Scott etal., 1992b). This washout procedure is undertaken before disconnectionof the limb from the perfusion circuit, with removal of the melphalan-containingperfusate by a single-pass perfusion using drug-free perfusate.The washout solutions that have been used are of variable compositionsand include plasma expanders mixed with electrolyte solutions(Rauschecker et al., 1991), Ringer's lactate (Scott et al., 1992a&b)and dextran (Krementz et al., 1987; Egerton, 1982). Currently,there is no pharmacokinetic data describing the kinetics of melphalanremoval during the washout period.

In our study, we have investigated the tissue and perfusate concentrations of melphalan during and after melphalan perfusionin the IPRH model (Wu et al., 1993). Given that melphalan canexhibit variable protein binding in the perfusate (Wu et al.,1995a), we examined whether melphalan perfusate binding was adeterminant of melphalan tissue concentrations during ILP andwashout. An overall aim of this study was to examine whether melphalanwould be best administered with a perfusate containing eitheralbumin or dextran during ILP and similarly for melphalan removalduring the washout period. We therefore quantified tissue andperfusate concentrations of melphalan using BSA and dextran perfusatesduring both perfusion and washout period. This data enabled usto design a physiologically based pharmacokinetic model whichmay assist in understanding the processes of melphalan distributionand removal during ILP.

	Methods

Top Abstract Introduction Methods Results Discussion Conclusion References

Rat Hindlimb Perfusion Preparation

The details of the single-pass rat hindlimb perfusion system have been described previously (Wu et al., 1993, 1995b). Briefly,rats (male Wistar, 320 ± 20 g) were anaesthetized, the abdomenopened and the right femoral artery cannulated (PE50) via thedorsal aorta. A second cannula (PE205) was placed in the dorsalvena cava, and the hindlimb perfused in a humidicrib with oxygenated(95% O₂/5% CO₂) Krebs-Heinseleit buffer (pH 7.4, 37°C), containing4.7% BSA (Fraction V, Sigma Chemical Co., Sydney, Australia) or2.8% dextran 40 (Sigma Chemical Co.). The oncotic pressures ofperfusate containing 2.8% dextran 40 corresponded to the oncoticpressure produced by 4.7% BSA (Cross et al., 1996). In an attemptto modify the allergic response of rats to dextran (hindlimb edemaduring perfusion), animals were given an i.p. injection of 2.5ml of 2.8% dextran 40 in perfusate 24 hr before the perfusionstudies (Perez-Trepichio et al., 1991). We have validated thestability of the rat hindlimb perfusion for up to 2 hr by testinginflowing and outflowing perfusate samples for pH, dissolved oxygenconcentrations, K⁺, lactate dehydrogenase and creatinine kinase as markers of celldamage (Wu et al., 1993). Perfusion flow rates of 3.80 ± 0.21ml/min, were controlled by a graduated peristaltic pump and weremeasured at the beginning and end of each perfusion.

Experimental Procedures

Before each experiment, melphalan powder (donated by Welcome Australia) was dissolved in HPLC-grade methanol to give a stocksolution of 1 mg/ml. Melphalan solution (15.26 µg/ml) was preparedin the perfusate containing 4.7% BSA or 2.8% dextran 40 immediatelyprior to melphalan perfusion. Rat hindlimbs were perfused withmelphalan perfusate for 60 min, followed by a drug-free eitherBSA or dextran perfusate washout for 30 min. Perfusate inflowand outflow samples (0.5 ml) were taken at 0, 4, 8, 16, 20, 30,40, 50, 60, 61, 62, 65, 70 and 90 min. Additional groups of ratswere also sacrificed at various times (2, 5, 10, 15, 20, 30, 60,70 and 90 min) during melphalan perfusion and hindlimb dissected.The perfused rat hindlimb was depilated with commercial Nair hair-removalcream and tissue samples (skin, fat and muscle) (500 mg) weretaken in duplicate from selected points in the hindlimb for melphalananalysis.

Determination of Melphalan Concentrations

Melphalan concentrations in perfusate and tissue samples were analyzed by a HPLC assay previously developed in our laboratory(Wu et al., 1995a). Briefly, perfusate samples were analysed followingmethanol precipitation (100 µl sample with 200 µl methanol containinginternal standard, dansyl-arginine), using a phenyl column andfluorescence detection. The detector was programmed to 265 nmexcitation and 360 nm emission for melphalan and 265 nm excitationand 575 nm emission for the internal standard. The mobile phaseconsisted of methanol-water-glacial acetic acid (25:75:2, v/v),pH = 2.7, with 1-octanesulphonic acid added at a concentrationof 50 mg/100 ml. The flow rate was 2 ml/min and the injectionvolume 20 µl.

Tissue samples (100 mg) were minced using scissors and suspended in 200 µl of methanol. The mixture was sonicated, on ice,for 1 min using an ultrasonic microtip and centrifuged at 10,000× g for 15 min. The supernatant was removed and 20 µl injectedinto the HPLC system. The limit of quantitation of this assayfor melphalan was 7.2 ng for tissue sample on column (Wu et al.,1995a).

Determination of Tissue Vascular Space

To calculate the vascular space in each tissue of the perfused rat hindlimb, ¹²⁵I-labeled albumin was mixed with melphalan in the perfusate ofthe IPRH. After 60 min perfusion, assuming the albumin had reachedsteady-state, an inflow sample was taken to measure the dpm/mlof albumin in the perfusate (C_perfusate). The tissue samples (skin,muscle and fat) were taken to determine the concentration of albumin(dpm) per g of tissue (C_tissue). The total weight (g) of eachtissue type (Wt) present in the perfused limb was then determinedby complete dissection. The skin hair was removed by the commercialNair hair-removal cream. The quantity of ¹²⁵I-labeled albumin was determined in a Cobra II gamma-counter (Packard,Meriden, CT). The vascular space of each tissue (V_p) (ml) in theperfused rat hindlimb was then determined from the following formula:

VP=<FR><NU>Cperfusate</NU><DE>Ctissue</DE></FR> Wt (1)

Determination of Tissue Blood Flow

The blood flow in skin, muscle and fat during perfusion at flow rate of 3.8 ml/min in the IPRH were determined using the radiolabeledmicrosphere (⁵¹Cr, 10 µ) method described in an earlier study (Wu et al., 1995b).The total blood flow to each tissue type in the perfused hindlimbwas assumed to equal the blood flow of tissue (ml/min/g of tissue)multiplied by the weight of each tissue type in the perfused hindlimb.

Theoretical Section

Model development. The physiological pharmacokinetic model proposed to describe melphalan distribution into the perfused tissues (skin, fat andmuscle) after isolated perfused rat hindlimb is presented in figure1. Each tissue can be described as a single compartments, connectedto a single central plasma compartment (fig. 1). The differentialmass balance equations can then be written for four compartmentsassuming: 1) a pseudo equilibrium exists between a given tissueand the perfusate in the hindlimb; 2) each tissue acts as a well-stirredcompartment; 3) lateral spread of melphalan from one tissue toanother tissue is negligible; 4) each tissue is a noneliminatingorgan, except for hydrolysis, where the rate constant in eachtissue is the same.

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Fig. 1. Diagrammatic representation of the pharmacokinetic model used to describe the disposition of melphalan in the isolated perfusedrat hindlimb. Refer to text for meaning of various terms.

Given that a monoexponential decline was observed in the concentration of melphalan due to hydrolysis in inflow perfusatesolution (fig. 2), the concentration of melphalan before reachingthe perfused rat hindlimb at any time is defined by

C=C<SUB>0</SUB> exp (−<IT>K<SUB>h</SUB> t</IT>)

(2)

The rate of amount change of melphalan in the perfusate (dA_p/dt) at any time during the perfusion period (t $<=$ 60) is definedby

<FR><NU>dA<SUB>p</SUB></NU><DE>dt</DE></FR>=C<SUB>0</SUB> Q exp (−<IT>K<SUB>h</SUB> t</IT>)<IT>−</IT><FR><NU><IT>f</IT><SUB><IT>u</IT></SUB></NU><DE><IT>V</IT><SUB><IT>p</IT></SUB></DE></FR><IT> </IT>(<IT>PS<SUB>s</SUB>+PS<SUB>m</SUB>+PS</IT><SUB><IT>f</IT></SUB>)<IT> A<SUB>p</SUB>+ </IT><FR><NU><IT>f</IT><SUB><IT>ut</IT><SUB><IT>s</IT></SUB></SUB></NU><DE><IT>V</IT><SUB><IT>t</IT><SUB><IT>s</IT></SUB></SUB></DE></FR><IT> PS<SUB>s</SUB> A</IT><SUB><IT>t</IT><SUB><IT>s</IT></SUB></SUB>

+ <FR><NU>f<SUB>ut<SUB>m</SUB></SUB></NU><DE>V<SUB>t<SUB>m</SUB></SUB></DE></FR> PS<SUB>m</SUB> A<SUB>t<SUB>m</SUB></SUB>+ <FR><NU>f<SUB>ut<SUB>f</SUB></SUB></NU><DE>V<SUB>t<SUB>f</SUB></SUB></DE></FR> PS<SUB>f</SUB> A<SUB>t<SUB>f</SUB></SUB>−QC<SUB>p</SUB>

where A_p is the amount of melphalan in perfusate, A_{t_s}, A_{t_m} and A_{t_f}are the amounts of melphalan in skin, muscle and fat; PS_s, PS_mand PS_f are the permeability-surface area products for the movementof melphalan from the perfusate into skin, muscle and fat, respectively;V_p is the vascular space in whole hindlimb; V_{t_s},V_{t_m} and V_{t_f} are the apparentdistribution volume of melphalan in each tissue and f_u, f_{ut_s},f_{ut_m} and f_{ut_f} are fractionsunbound of melphalan in perfusate and each tissue, respectively.C₀ is the initial concentration of melphalan in the perfusatereservoir, K_h is the melphalan hydrolysis rate constant in theperfusate and Q is the perfusion flow rate (ml/min).

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Fig. 2. The concentration-time profile of melphalan in perfusates containing 4.7% BSA ( $bullet$ ) or 2.8% dextran 40 ( $open circle$ ) at 37°C. Mean ± S.D.,n = 3.

Equation 3 can also be expressed in terms of the rate of change of melphalan concentration in the perfusate with time (dC_p/dt):

<FR><NU>dC<SUB>p</SUB></NU><DE>dt</DE></FR>=C<SUB>0</SUB> <FR><NU>Q</NU><DE>V<SUB>p</SUB></DE></FR> exp (−<IT>K<SUB>h</SUB> t</IT>)<IT>−</IT><FR><NU><IT>f</IT><SUB><IT>u</IT></SUB></NU><DE><IT>V</IT><SUB><IT>p</IT></SUB></DE></FR><IT> </IT>(<IT>PS<SUB>s</SUB>+PS<SUB>m</SUB>+PS</IT><SUB><IT>f</IT></SUB>)<IT> C<SUB>p</SUB></IT>

+<FENCE><FR><NU>f<SUB>ut<SUB>s</SUB></SUB></NU><DE>V<SUB>t<SUB>s</SUB></SUB></DE></FR> <FR><NU>PS<SUB>s</SUB></NU><DE>V<SUB>p</SUB></DE></FR></FENCE> A<SUB>t<SUB>s</SUB></SUB>

+<FENCE><FR><NU>f<SUB>ut<SUB>m</SUB></SUB></NU><DE>V<SUB>t<SUB>m</SUB></SUB></DE></FR> <FR><NU>PS<SUB>m</SUB></NU><DE>V<SUB>p</SUB></DE></FR></FENCE> A<SUB>t<SUB>m</SUB></SUB>+<FENCE><FR><NU>f<SUB>ut<SUB>f</SUB></SUB></NU><DE>V<SUB>t<SUB>f</SUB></SUB></DE></FR> <FR><NU>PS<SUB>f</SUB></NU><DE>V<SUB>p</SUB></DE></FR></FENCE> A<SUB>t<SUB>f</SUB></SUB>−<FR><NU>Q</NU><DE>V<SUB>p</SUB></DE></FR> C<SUB>p</SUB>

During the 30-min drug-free washout period after melphalan perfusion (t > 60), the input concentration of melphalan was effectivelyzero, and equation 4 reduces to:

<FR><NU>dC<SUB>p</SUB></NU><DE>dt</DE></FR>=<FENCE><FR><NU>f<SUB>ut<SUB>s</SUB></SUB></NU><DE>V<SUB>t<SUB>s</SUB></SUB></DE></FR> <FR><NU>PS<SUB>s</SUB></NU><DE>V<SUB>p</SUB></DE></FR></FENCE> A<SUB>t<SUB>s</SUB></SUB>+<FENCE><FR><NU>f<SUB>ut<SUB>m</SUB></SUB></NU><DE>V<SUB>t<SUB>m</SUB></SUB></DE></FR> <FR><NU>PS<SUB>m</SUB></NU><DE>V<SUB>p</SUB></DE></FR></FENCE> A<SUB>t<SUB>m</SUB></SUB>+<FENCE><FR><NU>f<SUB>ut<SUB>f</SUB></SUB></NU><DE>V<SUB>t<SUB>f</SUB></SUB></DE></FR> <FR><NU>PS<SUB>f</SUB></NU><DE>V<SUB>p</SUB></DE></FR></FENCE> A<SUB>t<SUB>f</SUB></SUB>−<FR><NU>Q</NU><DE>V<SUB>p</SUB></DE></FR> C<SUB>p</SUB>

−<FR><NU>f<SUB>u</SUB></NU><DE>V<SUB>p</SUB></DE></FR> (PS<SUB>s</SUB>+PS<SUB>m</SUB>+PS<SUB>f</SUB>) C<SUB>p</SUB>

The change in the amount of melphalan in the perfused skin with time can be expressed as

<FR><NU>dA<SUB>t<SUB>s</SUB></SUB></NU><DE>dt</DE></FR>=f<SUB>u</SUB> <FR><NU>PS<SUB>s</SUB></NU><DE>V<SUB>p</SUB></DE></FR> A<SUB>p</SUB>−<FR><NU>f<SUB>ut<SUB>s</SUB></SUB></NU><DE>V<SUB>t<SUB>s</SUB></SUB></DE></FR> PS<SUB>s</SUB> A<SUB>t<SUB>s</SUB></SUB>−K<SUB>m</SUB> A<SUB>t<SUB>s</SUB></SUB>

(6)

where A_p = C_p V_p and K_m is the rate constant of melphalan hydrolysis, and thus equation 6 can be modified to:

<FR><NU>dA<SUB>t<SUB>s</SUB></SUB></NU><DE>dt</DE></FR>=f<SUB>u</SUB>PS<SUB>s</SUB> C<SUB>p</SUB>−<FR><NU>f<SUB>ut<SUB>s</SUB></SUB></NU><DE>V<SUB>t<SUB>s</SUB></SUB></DE></FR> PS<SUB>s</SUB> A<SUB>t<SUB>s</SUB></SUB>−K<SUB>m</SUB> A<SUB>t<SUB>s</SUB></SUB>

(7)

The corresponding expressions for the change in the amount of melphalan with time in perfused muscle and fat are definedby equations 8 and 9:

<FR><NU>dA<SUB>t<SUB>m</SUB></SUB></NU><DE>dt</DE></FR>=f<SUB>u</SUB>PS<SUB>m</SUB> C<SUB>p</SUB>−<FR><NU>f<SUB>ut<SUB>m</SUB></SUB></NU><DE>V<SUB>t<SUB>m</SUB></SUB></DE></FR> PS<SUB>m</SUB> A<SUB>t<SUB>m</SUB></SUB>−K<SUB>m</SUB> A<SUB>t<SUB>m</SUB></SUB>

(8)

<FR><NU>dA<SUB>t<SUB>f</SUB></SUB></NU><DE>dt</DE></FR>=f<SUB>u</SUB>PS<SUB>f</SUB> C<SUB>p</SUB>−<FR><NU>f<SUB>ut<SUB>f</SUB></SUB></NU><DE>V<SUB>t<SUB>f</SUB></SUB></DE></FR> PS<SUB>f</SUB> A<SUB>t<SUB>f</SUB></SUB>−K<SUB>m</SUB> A<SUB>t<SUB>f</SUB></SUB>

(9)

Data analysis. The concentration of melphalan in the inflow perfusate at time zero is defined as C₀. The rate constant of melphalan hydrolysisin inflow perfusate was calculated from a semilogarithmic plotof concentration versus time (equation 2). The total amount ofmelphalan in the perfused rat hindlimb was calculated from theconcentration of melphalan in each tissue (µg/g of tissue) multipliedby the weight of each tissue. The total vascular space was takenas the sum of the estimated vascular spaces for skin, muscle andfat.

The nonlinear regression program MINIM V3.08 (Shen et al., 1989

), was used to numerically integrate four differential equationsdefined by the sum of equations 4 and 5, together with equations7, 8 and 9 to fit the melphalan data obtained from the outflowperfusate, skin, muscle and fat using weighted (1/y_obs) leastsquares with the Hartley modification of the Gauss-Newton algorithm.The final model fitting was deemed acceptable on the basis ofthe regression goodness-of-fit criteria that included the Akaikeinformation criteria (AIC) (Landlaw and Distefano, 1984

), a lackof systemic deviations in the residuals, and the percentage ofdata accounted for by the regression (R² > 0.99).

Simulations of the model were performed using the equations defined earlier for the nonlinear regression of eqs 4, 5, 7, 8and 9, with varying fractions unbound of melphalan in the perfusate(0.01-1), corresponding to possible perfusates of plasma, dextran,red blood cell solution and other solutions. The perfusate andtissue profiles were also simulated for variable amount of melphalanhydrolysed in tissues (K_m from 0-0.1). In addition, the simulationswere used to estimate the speed at which melphalan could be removedfrom each tissue during washout.

Each observation is the mean ± S.D. of three or four determinations. Statistical analyses were carried out using Student'st test for two groups and analysis of variance and Tukey testfor more than two groups. Statistical significance was acceptedat P < .05.

	Results

Top Abstract Introduction Methods Results Discussion Conclusion References

Tissue vascular volume and blood flow. Individual perfusate flow rates in skin, muscle and fat determined in the rat hindlimb by perfusion with microspheres andperfused tissue vascular volumes determined by ¹²⁵I albumin perfusion are given in table 1. The volume and bloodflow of each tissue were in the order of muscle > skin > fat,the vascular volume ratio of skin to fat and muscle to fat were6.7 and 21.4, respectively, in correspondence with perfusate flowratios of skin/fat and muscle/fat of 7.8 and 23.0, respectively.

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TABLE 1
The perfused hindlimb tissue vascular space and blood flow during isolated perfused rat hindlimb with perfusion flow rateof 3.8 ml/min (n = 4)

Perfusate kinetics of melphalan. Melphalan hydrolysis in the perfusate followed an apparent monoexponential decline (fig. 2) with a hydrolysis rate constantof 0.011 ± 0.001 (4.7% BSA perfusate) or 0.011 ± 0.0004 min¹ (2.8% dextran 40 perfusate).

Figures 3A and 4A show the outflow profiles of melphalan concentration obtained using both BSA and dextran perfusate duringmelphalan perfusion. Also shown in figures 3A and 4A are the washoutprofiles obtained from the drug-free perfusate during removalof melphalan from IPRH. It was observed that the melphalan concentrationin both perfusates (BSA and dextran) decreased rapidly duringthe first few minutes of the washout period, followed by a slowermonoexponential decline. The estimated half life for melphalanremoval during this latter washout phase was 71 ± 9, and 86 ±12 min, for BSA and dextran perfusates respectively.

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Fig. 3. Concentration or amount-time profiles for melphalan ( $bullet$ ) in the outflow perfusate (A), skin (B), muscle (C) and fat (D) during60 min melphalan perfusion followed by 30-min drug-free washoutwith 4.7% BSA containing perfusate. The solid line is the predictionfrom the model shown in figure 1, according to equations 4, 5,7, 8 and 9. Values are reported as mean ± S.D. (n = 3).

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Fig. 4. Concentration or amount-time profiles for melphalan ( $bullet$ ) in the outflow perfusate (A), skin (B), muscle (C) and fat (D) during60 min melphalan perfusion followed by 30-min drug-free washoutwith 2.8% dextran 40 containing perfusate. The solid line is thenonlinear regression using the model shown in figure 1, accordingto equations 4, 5, 7, 8 and 9. The dotted line is that obtainedby simulation using parameters derived for a perfusate containing4.7% BSA (table 2) and f_u be altered from 0.521 (4.7% BSA) to0.873 (2.8% dextran-40). Values are reported as mean ± S.D. (n= 3).

Distribution and pharmacokinetics of melphalan in perfused tissues. The total amount of melphalan in skin, muscle and fat in the IPRH increased with the time during melphalan (15.26 µg/ml) perfusion.The relative amounts of melphalan in each tissue was in the order:muscle > skin > fat for both BSA and dextran perfusions (figs.3 and 4). A comparison of figures 3 and 4 shows that the amountof melphalan in each tissue was significantly higher using dextranperfusate than using BSA perfusate (P < .05). The amount of melphalanwashed out from skin and fat using drug-free perfusate was characterizedby an estimated apparent t_1/2 of 59 ± 2 min for both BSA and dextranperfusate (fig. 5A). However, the amount of melphalan removalfrom muscle was much slower and characterized by an estimatedt_1/2 of 79 and 96 min for both BSA and dextran washout perfusatesrespectively (fig. 5A). The melphalan concentration remainingin the tissues after 30 min washout with dextran drug-free perfusatewas slightly higher but not significantly different from a washoutwith BSA perfusate after 60 min melphalan perfusion with 4.7%BSA perfusate (P > .05) (fig. 5B). A similar result was obtainedfollowing perfusion of melphalan for 60 min using 2.8% dextran40 perfusate (P > .05) (fig. 5C).

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Fig. 5. A, Simulation of percentage melphalan remaining in tissues using 4.7% BSA (key of lines: 1. skin, 2. muscle, 3. fat) or 2.8%dextran 40 (key of lines: 4. skin, 5. muscle, 6. fat) washoutsolutions after melphalan (15.26 µg/ml) perfusions with 4.7% BSAfor 60 min. B, The amount of melphalan in skin, muscle and fatwith 4.7% BSA perfusate (60 min) and 30-min washout with drug-freeperfusate containing 4.7% BSA (open symbol) or 2.8% dextran (filledsymbol). C, The amount of melphalan in skin, muscle and fat with2.8% dextran 40 perfusate (60 min) and 30 min wash with drug-freeperfusate containing 4.7% BSA (open symbol) or 2.8% dextran (filledsymbol). Values are reported as mean ± S.D. (n = 3).

The nonlinear regression of experimental data with equations 4, 5, 7, 8 and 9 yielded predicted concentrations or amountsof melphalan in perfusate and each tissue which corresponded closelyto the observed data (figs. 3 and 4). The percentage of data accountedfor by the regression, R², for melphalan in both BSA and dextran perfusate exceeded 0.99.Table 2 shows the estimated parameters in the pharmacokineticmodel for melphalan disposition for both BSA and dextran perfusate.The PS products of melphalan into each tissue were muscle > skin> fat, and f_ut/V_t were fat > skin > muscle (table 2). The valuesfor the PS product and f_ut/V_t of melphalan were not significantlydifferent between BSA and dextran perfusates during perfusion.The melphalan hydrolysis in the tissues appeared to be insignificant.

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TABLE 2
Pharmacokinetic parameters of melphalan during isolated rat hindlimb perfusion using 4.7% BSA or 2.8% dextran perfusate

Figure 4 also shows the simulations of melphalan perfusate concentrations and amounts in each tissue for dextran perfusateusing the parameters estimated by nonlinear regression of theBSA perfusate data together with a f_up for melphalan in dextranperfusate of 0.87. The f_up of melphalan in albumin perfusate is0.52. Comparable profiles were observed for the simulated, nonlinearregression and the experimental data for both perfusate and tissues(fig. 4).

	Discussion

Top Abstract Introduction Methods Results Discussion Conclusion References

This work has shown that melphalan concentrations differ significantly in muscle, skin and fat after perfusion in the IPRH.Scott et al. (1992a), in measuring the concentration of melphalanin skin and fat during in ILP, had previously shown a significantlylower melphalan concentration in fat (1.48 µg/g) than in skin(3.83 µg/g). Klaase et al. (1994) reported that the uptake ofmelphalan into muscle (6.5 µg/g) was higher than into skin (3.2µg/g) after ILP. Our results are consistent with these reportsin that the melphalan concentration in each tissue after melphalanperfusion with 4.7% BSA perfusate were of the order: muscle (18.38µg/g) > skin (12.94 µg/g) > fat (9.76 µg/g). The differences inmelphalan tissue concentration in this study compared to earlierwork in humans arises in part from the use of the constant infusioninput in this study as distinct from the bolus input used in theprevious studies (Scott et al., 1992a; Klaase et al., 1994).

In the IPRH, the amount melphalan in each tissue increased during the time of perfusion (60 min) (figs. 3 and 4). The physiologicalpharmacokinetic model proposed appears to adequately describethe amount of melphalan in each tissue during this perfusion period.The only other data on melphalan tissue concentration-time profilesin a single subject have been reported by Benckhuijsen et al.(1988). However, these authors deduced, rather than measured,the tissue concentrations using a biexponential representationof the melphalan perfusate concentration-time data obtained during60 min ILP after an initial bolus input of melphalan. They suggesteda peak tissue concentration of melphalan at 15 min and the modelassumed a single homogeneous tissue compartment in the ILP. Inpresent work, melphalan concentrations had not reached steady-stateduring the 60 min infusion. This result is consistent with a reportby Thompson et al. (1995), who used a noncompartmental momentanalysis to show that the mean residence time of melphalan is43 to 51 min during ILP.

A limitation in the analysis of data shown in figures 3 and 4 is the use of a compartmental model, in which each plasma ortissue compartment is regarded as being well-stirred (Wagner,1988). The model is consistent with the physiologically basedpharmacokinetic model developed by Bischoff and Dedrick (1968)which depicts the body as a number of well-stirred vascular compartmentsrepresenting individual organs. The model assumes that intercompartmentaltransport occurs by blood flow only and that instantaneous equilibriumis achieved between tissue and the perfusing blood. The modelmay be extended to include well-stirred tissue compartments (Gerlowskiand Jain, 1983). In reality, the representation of the body asa number of well stirred compartments is not consistent with theactual anatomy and physiology of the organs (Roberts and Rowland,1985, 1996). In this study, a four-compartment model was usedto describe the amount of melphalan in each tissue and in theperfusate. A simpler model, in which each tissue is consideredseparately as a two-compartment model with distribution of melphalanfrom the vascular space to the tissue defined by the measuredblood flow, was also applied to the tissue data. The summed predictedperfusate concentration time course arising from the three tissues,with corrections for the flow rate in each tissue, appeared tocorrespond closely to the observed total perfusate outflow concentrationprofile for melphalan with time. Although the two compartmentmodel of each tissue allows the description of the melphalan dispositionin the IPRH, a more complicated model is needed to fit the observedperfusate and tissue data simultaneously.

In this study, the PS of melphalan was estimated to be 1.7 ml/min, the molecular weight (MW) is 305, pKa at pH 7.4 are 1.83and 9.13 (Fasman, 1976). Sexton and Laughlin (1994) have reportedthat ⁵¹Cr-EDTA (MW 341) has a PS of 1.18 ml/min. The main source of thedifference is likely to be differences of the chemical propertiesof melphalan and EDTA. The PS products for melphalan in each tissueis of the order: muscle > skin > fat, consistent with the ⁵¹Cr-EDTA results published by Sexton and Laughlin (1994) and Paaske(1976). Rowland and Tozer (1989) reported that the protein concentrationin various tissues are also in the order: muscle > skin > fat.As an approximation, the fraction unbound of drug in a given tissueis given by: f_ut = 1/(1 + K_a * P_t), where K_a is the associationconstant of drug for the protein in the tissue and P_t is the totalamount of protein in the tissue. Accordingly, the fraction unboundof drug in each tissue is of the order: muscle < skin < fat. Notingthat the distribution volume (V_t) in each tissue is in the orderof muscle > skin > fat, the f_ut/V_t in each tissue is predictedto be in the order: f_{ut_f}/V_{t_f}> F_{ut_s}/V_{t_s} > f_{ut_m}/V_{t_m}.Our results for f_ut/V_t in various tissues (table 2) are consistentwith this finding. The overall effect of these relationships isan outcome of the amount of melphalan uptake into muscle beingsignificantly higher than that of into skin and fat.

As an alternative to PS and f_ut/V_t, the rate constant of influx in each tissue could also be expressed as K_12i = (f_u/V_p) *PS_i, and the rate constant of efflux from each tissue by K_21i= (f_{ut_i}/V_{t_i}) * PS_i, wherei represents each tissue. Whereas PS_i and f_{ut_i}/V_{t_i}are not significantly different between 4.7% BSA and 2.8% dextran40 perfusate, for the K_12i, the dextran 40 perfusate is significantlyhigher than the BSA perfusate. The differences in K_12i arise fromthe presence of f_u in this parameter. The fraction of melphalanunbound in the dextran perfusate (0.87 ± 0.10) is significantlyhigher than in BSA perfusate (0.52 ± 0.04) perfusate. In contrast,f_u is not a component of K_21i and similar values for K_21i wereobtained for perfusates containing BSA and dextran.

By definition (equations 7, 8 and 9), the amount of melphalan in each tissue is related to the melphalan of f_u in perfusate,PS product and f_ut/V_t. The change of f_u in perfusate will thereforeaffect melphalan uptake into perfused tissues. The outcome isthat a perfusate with low binding capacity for melphalan willfacilitate melphalan uptake into the perfused tissues.

Rauschecker et al. (1991) reported that the majority of melphalan in the systemic circulation appeared immediately after reconnectionof the vasculature when ILP finished, and that it is of majorimportance in the consideration of melphalan induced systemicside effects. Melphalan from the perfused limb tissues and vasculaturewill wash into the systemic circulation after reconnection ofthe ILP. At the end of the 60-min melphalan perfusion in the IPRH,the vascular space contained only 1.1% of the melphalan remainingin the tissues (figs. 3 and 4). In addition, whereas the perfusateis rapidly cleared of melphalan during first few min of the washout(figs. 3A and 4A), the release of melphalan from tissue is muchslower. The slow efflux is consistent with previous studies (Scottet al., 1992a; Rauschecker et al., 1991), reporting that a majorfraction of the melphalan was retained in the perfused tissueand that redistribution from the tissue compartment into the systemiccircuit was slow. Rauschecker et al. (1991) suggested that 1.4to 18% of the total melphalan dose reaches the systemic circulationafter reconnection in ILP. In present study, approximately 14.5%of total melphalan dose would reach the systemic circulation ifa washout procedure was not used.

A number of melphalan-free perfusates have been used in the washout procedure during ILP. They include plasma expander mixedwith electrolyte solution (Rauschecker et al., 1991), Ringer'slactate (Scott et al., 1992a) and dextran (Krementz et al., 1987;Egerton, 1982). To minimize the later distribution of melphalanfrom the perfused limb into the systemic circulation, techniquesfor the washing-out phase need to be optimised (Rauschecker etal., 1991). We had hypothesized that a drug free washout solutioncontaining BSA and longer washout periods may better facilitatemelphalan removal from the perfused limb than a perfusate withoutany binding capacity for melphalan. In present study, no differencein melphalan removal from skin and fat were found between BSAand dextran perfusates (fig. 5A). This result suggests removalfrom tissue is effectively into perfusate under sink conditions,i.e., there is no substantial redistribution back to these tissuesfrom the perfusate. Redistribution may be important for musclesas the melphalan removal from muscle was faster using 4.7% BSAthan with using 2.8% dextran perfusate. Given that 72 to 74% ofthe melphalan is in perfused muscle for both BSA and dextran perfusate(figs. 3 and 4), the use of washout perfusate containing BSA toreduce the amount of melphalan reaching the systemic circulationwill be that primarily from the perfused muscle.

In this work, a comparison of drug-free BSA or dextran perfusates during the washout period was conducted following identicalmelphalan perfusion conditions. With either 4.7% BSA or 2.8% dextranperfusate with melphalan perfusion, the amount of melphalan ineach tissue after 30 min washout was less for the 4.7% BSA drugfree perfusate than for the 2.8% dextran perfusate (fig. 5). Thisresult suggests that using washout solutions that bind melphalanhighly may facilitate melphalan removal from the perfused limb.However, the removal of 50% of the melphalan from each tissueby 4.7% BSA perfusate would require more than 1 hr washout time,especially for muscle. At present, the washout time in clinicalpractice is between 3 min (Scotter et al., 1987) and 4 min (Rauscheckeret al., 1991).

A variety of media has been used that are likely to influence oxygen supply, arteriolar recruitment, drug binding in bloodand perfusion pressure (Wu et al., 1993). What the desirable compositionof the perfusate should be was raised by Kroon (1988) in his reviewof ILP procedures. Our work has suggested that protein bindinginfluences both the input and output of melphalan in muscle duringperfusion and washout. Melphalan has been reported (Greig et al.,1987) to bind to red blood cells (36.7%), plasma (84.1%) and humanalbumin (46.1%). Wu et al. (1995a) reported that melphalan bindingto 4.7% BSA was 47.9%. In figure 6, the effect of changing f_uin the perfusate to the melphalan concentration-time profilesin outflow perfusate, skin, muscle and fat after the applicationof a constant input source to the IPRH is examined using the pharmacokineticmodel (fig. 1) derived in this work. The conditions used werean initial applied concentration of 15.26 µg/ml and a perfusionflow rate of 3.8 ml/min with perfusate containing BSA, dextran,RBC, plasma or other solutions. The melphalan concentrations inthe outflow perfusate with varying f_u of melphalan in the perfusateare in the order: f_u = 0.01 > f_u = 0.16 (plasma) > f_u = 0.52 (4.7%BSA) > f_u = 0.63 (RBC) > f_u = 0.87 (2.8% dextran 40) > f_u = 1.Consistent with model predictions, the amount of melphalan uptakeinto each tissue was highest for the highest fu with an order:f_u = 1 > f_u = 0.87 (2.8% dextran 40) > f_u = 0.63 (RBC) > f_u =0.52 (4.7% BSA) > f_u = 0.16 (plasma) > f_u = 0.01. It is apparentthat a perfusate with a high protein content perfusate impairsmelphalan uptake into perfused tissues.

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Fig. 6. Simulated concentration or amount-time profiles of melphalan in perfusate (A), skin (B), muscle (C) and fat (D) after melphalan(15.26 µg/ml) perfusion for 60 min and washout with drug freeperfusate for 30 min according to the model in figure 1 usingperfusates in which the melphalan fraction unbound (f_u) varies.Key: (1) f_u = 0.01, (2) f_u = 0.16 (plasma), (3) f_u = 0.521 (4.7%BSA), (4) f_u = 0.633 (red blood cell), (5) f_u = 0.873 (2.8% dextran40), (6) f_u = 1.

Because the commonly applied process of hyperthermia may enhance melphalan hydrolysis, the effect of potential hydrolysisin tissues was examined in figure 7. The simulated melphalan concentration-timeprofile in the outflow perfusate was constant for K_m ranging from0 to 0.1. However, the amount of melphalan in each tissue decreasedproportionately as K_m increased.

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Fig. 7. Simulated concentration or amount-time profiles of melphalan in perfusate (A), skin (B), muscle (C) and fat (D) after melphalan(15.26 µg/ml) perfusion for 60 min and washout by drug free perfusate(4.7% BSA) for 30 min for various melphalan hydrolysis rates constantsin tissues. Key: (1) K_m = 0, (2) K_m = 10¹⁴, (3) K_m = 10⁴, (4) K_m = 0.01 and (5) K_m = 0.1.

	Conclusion

Top Abstract Introduction Methods Results Discussion Conclusion References

A physiological pharmacokinetic model has been developed to describe the concentration-time profile of melphalan in both perfusateoutflow and tissues in the isolated perfused rat hindlimb duringperfusion with melphalan and washout periods. The predicted concentration-timeprofiles obtained appear to correspond closely to the observeddata. Further simulations enabled the prediction of melphalanperfusate and tissue profiles with a dextran perfusate, aftercorrection for difference in melphalan binding to perfusate components.The work also shown that higher melphalan protein binding in theperfusate impairs its uptake into tissue. However, the effectof protein binding on the washout kinetics was small, a comparablerate of elimination being observed for dextran and albumin perfusates.It is implied throughout that this physiological pharmacokineticmodel will have use in the understanding of limb exposure to achemotherapeutic agent such a melphalan during a local limb perfusion.The description of washout of drug from the perfused limb assistsin understanding systemic drug exposure.

	Footnotes

Accepted for publication April 28, 1997.

Received for publication July 23, 1996.

¹ This work was supported by the Queensland Cancer Fund. M.S.R. was supported by Australian National Health & Medical ResearchCouncil and the Queensland and Northern New South Wales LionsKidney & Medical Research Foundation.

Send reprint requests to: Dr. Michael S. Roberts, Department of Medicine, University of Queensland, Princess Alexandra Hospital, Brisbane, Queensland, Australia 4102.

	Abbreviations

PK, pharmacokinetics; IPRH, isolated perfused rat hindlimb; ILP, isolated limb perfusion; f_u, fraction unbound; BSA, bovine serum albumin; HPLC, high-performance liquid chromatography; RBC, red blood cell.

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Tissue and Perfusate Pharmacokinetics of Melphalan in Isolated Perfused Rat Hindlimb1

Tissue and Perfusate Pharmacokinetics of Melphalan in Isolated Perfused Rat Hindlimb¹