Disposition of Vessel Dilator and Long-Acting Natriuretic Peptide in Healthy Humans after a One-Hour Infusion

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Vol. 282, Issue 2, 603-608, 1997

Disposition of Vessel Dilator and Long-Acting Natriuretic Peptide in Healthy Humans after a One-Hour Infusion¹

Bruce H. Ackerman² , Rose M. Overton, Michael T. McCormick, Douglas D. Schocken and David L. Vesely

Department of Pharmacy Practice and Pharmacy Administration, Philadelphia College of Pharmacy and Science, Philadelphia, Pennsylvania (B.H.A.), and Departments of Internal Medicine (R.M.O., D.D.S., D.L.V.) and Pharmacy (M.T.M.), James A. Haley Veterans Hospital and University of South Florida Health Sciences Center, Tampa, Florida

	Abstract

Top Abstract Introduction Methods Results Discussion References

The present investigation was designed to determine half-lives, distribution phases and metabolic clearance of two new cardiacpeptide hormones in humans. Long-acting natriuretic peptide (LANP)and vessel dilator were infused at 100 ng/kg of b.wt./min concentrationsfor 60 min with their respective concentrations measured by specificradioimmunoassays in plasma during and for 3 hr after infusion.The half-life of vessel dilator was 107 min, whereas the half-lifeof LANP was 28 min. The average time that the respective peptideswere retained in the body (mean residence time) was 214 ± 34 minfor vessel dilator and 178 ± 12 min for LANP, which indicatesthat they are widely distributed outside the initial space (i.e.,circulation). The metabolic clearance normalized to 1.73 m² body surface area was 241 ml/min for vessel dilator and 249 ml/minfor LANP. The total body clearance normalized to 1.73 m² body surface area was 130 ml/min for vessel dilator and 293 ml/minfor LANP. The significantly (P < .001) longer half-lives and slowermetabolic clearance of LANP and vessel dilator compared with atrialnatriuretic factor (half-life, 2.5 min, metabolic clearance, 582-2,581ml/min/1.7 m²) explain why these peptides circulate at concentrations 15- to24-fold higher than atrial natriuretic factor in healthy humans.

	Introduction

Top Abstract Introduction Methods Results Discussion References

The atrial natriuretic peptide hormonal system consists of a 126-a.a. prohormone synthesized within myocytes of the heartand stored in storage granules within the heart for release intothe circulation (Vesely, 1992, 1995). This hormonal system containsseveral peptides from the same 126-a.a. prohormone with bloodpressure lowering, natriuretic, diuretic and/or kaliuretic (i.e.,potassium-excreting) properties (Martin et al., 1990; Vesely etal., 1994a, 1994b) (fig. 1). Thus, peptides consisting of a.a.1 to 30 (i.e., LANP), 31 to 67 (vessel dilator), 79 to 98 (kaliureticpeptide) and 99 to 126 (ANF) each have blood pressure-lowering,diuretic, natriuretic and/or kaliuretic properties in both humans(Vesely et al., 1994a, 1994b) and animals (Martin et al., 1990;Vesely et al., 1987b). When released into the circulation, thesepeptides circulate as a 98-a.a. amino terminus and a 28-a.a. carboxylterminus (i.e., ANF) of this prohormone (Meleagros et al., 1988;Sundsfjord et al., 1988; Winters et al., 1988a, 1988b). In addition,vessel dilator and LANP circulate as distinct entities after havingbeen proteolytically cleaved from the rest of the amino terminusby proteases (Gower et al., 1994; Vesely et al., 1993, 1994b)(fig. 1).

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Fig. 1. Origination of LANP, vessel dilator, kaliuretic peptide and ANF from the ANF prohormone. LANP consisting of amino acids (a.a.)1 to 30, vessel dilator composed of a.a. 31 to 67 and kaliureticpeptide composed of a.a. 79 to 98 originate from the amino terminusof the ANF prohormone, whereas ANF consisting of a.a. 99 to 126originates from the carboxyl terminus of this 125-a.a. prohormone.Each of these peptide hormones circulate as distinct entitiesand each lowers blood pressure via vasodilation of blood vessels.

Vessel dilator, LANP and ANF bind to specific receptors (Vesely et al., 1990a, 1990b, 1992); then, each of these peptidesenhances the particulate form of the enzyme guanylate cyclase(EC4.6.1.2) as part of their mechanism(s) of action (Veselyet al., 1987a, 1987b). The enhancement of guanylate cyclase byeach of the respective atrial natriuretic peptides increases theintracellular messenger cGMP (Vesely et al., 1987a, 1987b; Waldmanet al., 1984), which causes vasodilation itself. Vessel dilatorand LANP also inhibit renal Na⁺, K⁺-ATPase as part of their mechanism(s) of action causing a natriuresis(Chiou and Vesely, 1995; Gunning et al., 1992). In contradistinction,ANF does not have any effect on renal Na⁺, K⁺-ATPase (Charlton and Baylis, 1990; Chiou and Vesely, 1995; Gunninget al., 1992; Pollock et al., 1983). Vessel dilator and LANP eachenhance prostaglandin E₂ synthesis, which appears to be the mediatorof the inhibition of Na⁺, K⁺-ATPase by these peptides (Chiou and Vesely, 1995; Gunning etal., 1992).

Vessel dilator, LANP and ANF are released simultaneously with central hypervolemia (Vesely et al., 1989) and with rapid heartrates of 125 $>=$ beats/min (Ackerman et al., 1992; Ngo et al., 1989,1990). These peptides are also released simultaneously in vitrofrom isolated perfused atria by atrial distension (Dietz et al.,1991). The half-life of ANF in the circulation of humans is wellcharacterized with half-lives of 1.2 to 6.9 min (average, 2.5-3min) being reported (Nakao et al., 1986; Tan et al., 1993; Yandleet al., 1986). The half-lives of vessel dilator and LANP havenever been investigated in humans. The present investigation wasdesigned to determine the half-lives, distribution, MC and TBCof vessel dilator and LANP after their exogenous administrationat 100 ng/kg of b.wt./min for 1 hr to human subjects followedby a 3-hr postinfusion evaluation of their circulating concentrations.

	Methods

Top Abstract Introduction Methods Results Discussion References

Materials. The human forms of LANP, vessel dilator and ANF were synthesized by Peninsula Laboratories (Belmont, CA). Before their usein these studies, samples of these commercially synthesized peptideswere subjected to HPLC to determine their purity using a NovapakC18 (5-µm) cartridge column (Waters Chromatography Division, MilliporeCorporation, Milford, MA). The flow rate for the HPLC study was1 ml/min with 0.1% trifluoroacetate solvent in pump A and 60%acetonitrile in 0.1% trifluoroacetate in pump B, with a gradientof 0% to 60% acetonitrile achieved in 40 min. This evaluationverified their purity and authenticity compared with the knownHPLC elution profile of these peptides (Winters et al., 1989).After determining that the respective peptides were pure, thepeptides were dissolved in 0.9% saline solution in the hospitalpharmacy, where pyrogen and sterility testing was performed beforedispensing the 100 ng/kg b.wt. concentrations of each peptideinto two 10-ml syringes. Each 10-ml syringe infused all of itscontents over a 30-min time period. After completing the experiment,each of the syringes and the infusion catheter were examined bythe RIAs described below to determine the amount of the respectivepeptides that may have remained within the syringes or tubing.Approximately 5% of each peptide remained on the walls of thesyringes and tubing after completion of the infusion. This wasdetermined after completion of the experiment by flushing thesyringes three times with 4 ml of 0.9% saline and then measuringby the respective RIAs the amount of each peptide present in the0.9% saline flush. The amount measured was then compared withthe amount infused to determine the percentage that had remainedon the walls of the syringes and tubing.

Experimental subjects. Ten healthy subjects (six men and four women; ages, 20-54 years; average, 33 years) were investigated. These subjects hadheart rates ranging from 66 to 80 beats/min, with respirationbetween 12 and 14/min. Each of the volunteers were normotensivewith blood pressures of <125/80 mm Hg. These volunteers were dividedinto two similar groups based on age, blood pressure, heart rateand gender (equal number of men and women in each group) (table1). For comparison of half-lives and MC, another group of sixsubjects (average age, 34 years) with blood pressure of <125/80mm Hg had ANF infused at the same concentration (100 ng/kg/min)as the more recently discovered atrial natriuretic peptides.

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TABLE 1
Blood pressure, heart rate, age, weight, height and BSA of human volunteers receiving LANP and vessel dilator
There was no significant difference in age, gender, weight, heart rate or blood pressure of the individuals in the respectivegroups when evaluated with an unpaired t test.

None of the volunteers had any known disease. Of importance, none of the subjects had any abnormality of sodium or water metabolism.Specifically, none of the healthy volunteers had any edema onphysical examination, and their blood urea nitrogen and serumsodium levels were within the normal range. None of the volunteerswere taking any medication. Blood pressure (in mm Hg measuredwith a sphygmomanometer compression cuff) and heart rate (withstethoscope at cardiac apex) were measured and recorded every5 min throughout the investigation. Each of the subjects consumedtheir normal diets until the night before the infusion of thepeptides. After the overnight fast, no food was consumed duringthe time of experimentation. The subjects' urine output was replacedorally with 1 ml of water for each milliliter of urine output.Informed consent was obtained from each of the volunteers afterthe nature and possible consequences of the studies were fullyexplained. This study was approved by the Institutional ReviewBoard of the University of South Florida Health Sciences Centerand the Research Committee of the James A. Haley Veterans Hospital.This study was also approved by the United States Food and DrugAdministration (FDA IND 32,119).

Experimental protocol. After obtaining written informed consent from each participant, an Insyte-w 20-gauge 1.5-in catheter was placed into one forearmof each subject for infusion, and a second Insyte-w 20-gauge 1.5-inchcatheter was placed in the opposite forearm for blood sampling.A 60-min base-line period preceded each infusion. Each of thesepeptides was infused by a constant rate infusion pump over a 60-minperiod. Blood samples were obtained every 20 min during the infusionand at 30-min intervals during the 1-hr preinfusion and 3-hr postinfusionperiods. A rate of 100 ng/kg b.wt./min was chosen for infusionof these atrial natriuretic peptides because the rate of releaseof the amino-terminal ANF prohormone peptides from the atriumof the heart with physiological stimuli is 138 to 292 ng/kg b.wt./min(Ackerman et al., 1992). All subjects were studied in the morningafter an overnight fast, beginning their base-line period at 8:00a.m. Each volunteer was studied in the seated position and receivedonly one peptide infusion. Molar equivalents of the 100 ng/kgb.wt. dose were 29 and 26 pmol/l/kg b.wt. for LANP and vesseldilator, respectively.

Measurement of LANP, vessel dilator and ANF. Each of the blood samples and the results of flushing the syringes and tubing with 4 ml of 0.9% sodium chloride were collectedinto chilled 5-ml EDTA tubes to prevent proteolytic breakdownof any peptides that might be present. These samples were transportedon ice and immediately centrifuged at 3000 × g for 15 min. Aftercentrifugation, each sample was extracted with 100% ethanol (1:2dilution), vortexed and allowed to stand at 4°C for 30 min (Veselyet al., 1994b; Winters et al., 1989). We have previously describedin detail RIAs to measure LANP, vessel dilator, and ANF (Veselyet al., 1994a; Winters et al., 1989). For each RIA, the extractedplasma was first reconstituted in 100 µl of 0.1 M phosphate buffer,pH 7.4, containing 0.05 M NaCl, 0.1% BSA, 0.1% Triton X-100 and0.01% NaN₃. To the redissolved sample, 100 µl (0.03 mg) of rabbitimmunoglobulin G (second antibody) plus 100 µl of LANP, vesseldilator or ANF antisera was added and incubated for 24 hr. Then,100 µl of ¹²⁵I-labeled atrial peptides (10,000 cpm) were added, mixed and incubatedfor 18 hr at 4°C. Precipitation of the antibody-bound tracer wasaccomplished by adding 100 µl of goat anti-rabbit globulin afterthe above-described 18-hr period and incubating this mixture for2 hr at room temperature. Each tube was then centrifuged at 3000× g for 20 min. The supernatant was aspirated, and the pelletwas counted in a $gamma$ -counter. All determinations were performedin triplicate.

The intra-assay coefficients of variation for LANP, vessel dilator and ANF were 4.8%, 5.3% and 5.7% respectively. The interassaycoefficients of variation were 8% for both LANP and vessel dilator,whereas the interassay coefficient of variation for ANF was 7.3%.Recovery was examined by adding synthetic unlabeled LANP, vesseldilator and ANF at 100, 200 and 400 pg/ml to pooled plasma. Recoveryfor LANP, vessel dilator and ANF were 83 ± 13%, 100 ± 9% and 92± 11%, respectively. The lowest detectable concentrations of LANP,vessel dilator and ANF were 40 (140 pg), 35 (136 pg) and 1.4 fmol(4.2 pg)/tube, whereas the nonspecific binding was 2.1%, 2.5%and 2.9% in their respective RIAs.

Statistical analysis. Determination that individuals in the two different groups were equal with respect to age, weight, height, gender, blood pressure,base-line peptide levels, MC rates, half-lives and AUC by noncompartmentalanalyses were compared using an unpaired t test (EPISTAT, RoundRock, TX). The plasma concentration-time data of vessel dilator,LANP and ANF were analyzed by the computerized least-squares,nonlinearized regression program JANA (Statistical Consultants,Lexington, KY). Compartmental analysis was performed using PCNONLIN(Statistical Consultants) and AUMC.BAS (Ron Kluza, Universityof Arkansas, Little Rock, AR). In addition, the MC rate of thevessel dilator, LANP and ANF were determined as follows:

MC rate<IT>=</IT><FR><NU>Infusion rate of peptide</NU><DE>Plateau − base-line plasma concentration</DE></FR>

This MC is equivalent to a central compartment (i.e., systemic circulation) TBC. To confirm that the infusions of LANP vesseldilator, and ANF were actually infusing the correct amount ofthe respective peptides, respective concentrations of each infusatewere determined by RIA measurement from samples collected throughoutthe infusion. The plasma half-lives of these peptides were determinedby nonlinear regression using PCNONLIN. The pharmacokinetic analysisof these peptides assumes that there is no change in the endogenousproduction of these peptides during the period of study. MRT wascalculated using PCNONLIN and AUMC computer programs, which usederiviates of the AUC and AUMC in an equation to do so.

The AUCs were determined using AUMC and PCNONLIN with the "trapezoidal rule" method. PCNONLIN also calculated an AUC usingthe polynomial equation method. AUCs were compared using a t test,and no significant difference in AUC was noted between AUMC andPCNONLIN methods. Postinfusion data were used exclusively to determinehybrid constants for the PCNONLIN program, which requests thesepostinfusion estimates using the program JANA, which is includedin PCNONLIN. The plasma concentration-time data are "fit" usingthe postinfusion estimates as initial starting points for iterationof the actual data points. To accurately calculate the TBC, theinfusion portion of the AUC must be included in the calculations.PCNONLIN provided the pharmacokinetic parameters as did AUMC withoutany additional calculation. PCNONLIN does not correct for BSA,which was corrected for to permit comparison with the AUMC data.For evaluation of the AUCs, the basal (endogenous) concentrationsof the peptides (measured before infusion) were subtracted fromthis equation.

	Results

Top Abstract Introduction Methods Results Discussion References

Mean blood pressure, heart rate, age, weight, height and BSA of the human volunteers receiving LANP or vessel dilator aredelineated in table 1. Base-line and peak values of the respectivepeptides and compartmental disposition parameters after the infusionof vessel dilator or LANP are enumerated in table 2. The measuredcumulative infused doses of LANP and vessel dilator are also detailedin table 2. The concentration-time profiles of each of thesepeptides during and after the infusions are illustrated in figure2.

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TABLE 2
Compartmental disposition parameters, base-line concentrations and peak concentrations in healthy individuals after infusionof vessel dilator and/or LANP

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Fig. 2. The concentration-time curves for LANP ( $square$ ), vessel dilator ( $bullet$ ) and ANF ( $black-triangle$ ). LANP and vessel dilator remain elevated abovebase line significantly (P < .001) longer than ANF when evaluatedby the unpaired t test.

The half-life of vessel dilator was 107 ± 62 min (mean ± S.D.) (table 3). The half-life of LANP was 28 ± 11 min. The half-lifefor LANPs was decreased compared with that of vessel dilator atleast partially because of the large volume of distribution ofsubjects 2 and 4, who received LANP. Comparison of the half-livesof LANP, vessel dilator and ANF of all subjects are illustratedin figure 3. In this figure, half-lives of vessel dilator andLANP are significantly longer than the half-life of ANF.

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TABLE 3
Noncompartmental analysis of data vs. MC rate

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Fig. 3. Comparison of the half-lives and MC of ANF, LANP and vessel dilator in the circulation of healthy humans. The half-lives ofLANP and vessel dilator were significantly (P < .01) longer, whereastheir MC values were significantly lower (p < .0) than those ofANF when evaluated by the unpaired t test (EPISTAT) (n = 6 forANF and vessel dilator, 4 for LANP).

The $alpha$ -distribution phase rate constants that reflect the movement of peptides into the circulation and their binding to tissueswere then determined. The $alpha$ -distribution phase rate constant (i.e.,rate at which the concentration of a hormone or substance decreasesin the circulation) for vessel dilator was 0.047 ± 0.014 min¹ (i.e., these reciprocal minutes are the rate at which its concentrationdecreases per minute), whereas the $alpha$ -distribution rate constantfor LANP was 0.108 ± 0.082 min¹, as outlined in table 2. The S.D. of the $alpha$ -distribution rateconstant phase was 0.014 min¹ for vessel dilator, whereas the S.D. for the $alpha$ -phase rate constantof LANP was 0.082 min¹ due to the very large $alpha$ -phase distribution rate constant of subject4 receiving LANP. If this subject was deleted from the calculationof the mean $alpha$ -phase distribution rate constant of LANP, the average $alpha$ -distribution of this peptide in the other subjects was 0.070± 0.03 min¹. Furthermore, if subject 2 as well as subject 4 was removed fromthe calculation, the average $alpha$ -phase distribution rate constantfor the other subjects for LANP was 0.048 ± 0.005 min¹, a value very similar to the $alpha$ -phase distribution rate constantfor vessel dilator. The $beta$ -distribution phase rate constant reflectsthe distribution of these peptides within tissues. The $beta$ -distributionphase rate constant for vessel dilator was 0.008 min¹ with a S.D. of 0.004 min¹ (table 2). The $beta$ -distribution phase rate constant for LANP was0.027 min¹ with a S.D. of 0.010 min¹ (table 2). The $beta$ -distribution phase is an observed slowing ofthe clearance of these peptides as a result of their broader distributionin tissues.

Noncompartmental analysis of the infusion of vessel dilator and LANP revealed that the average time for the respective peptidesto be retained by the body (i.e., MRT) was 214 ± 34 min for vesseldilator and 178 ± 6 min for LANP (table 3). The MRT reflectsthe sustained presence of vessel dilator and LANP above base line.MRT is identical to the turnover for an endogenous substance andreflects when 63.2% of an administered dose has been eliminated.The TBC (in ml/min) normalized to 1.73 m² BSA averaged 130 ± 26 ml/min for vessel dilator and 293 ± 82ml/min for LANP (table 3). The MC rate also normalized to 1.73m² BSA was 241 ± 51 ml/min for vessel dilator and 249 ± 62 ml/minfor LANP (table 3). The MC was significantly less (P < .01) forvessel dilator and LANP compared with ANF (fig. 3).

Comparison of the MC with the TBC revealed a significant difference for vessel dilator (P < .05), whereas this same evaluationrevealed no significant difference for LANP (P = .42). The volumeof distribution during the clearance of these peptides (V_dss)in liters/kg was similar for vessel dilator (0.098 ± 0.02) andLANP (0.123 ± 0.039) (table 3). The V_dss is the steady-statedistribution volume and it differs from the $beta$ -distribution volumein that it is independent of the clearance of a respective peptide.Comparisons of AUCs by both compartmental and noncompartmentalanalysis using the unpaired t test demonstrated no differencebetween vessel dilator and LANP. The AUC for proANF 31-67 was64,913 ± 14,660 ng/liter/min (compartmental) and 68,642 ± 7092ng/liter/min (noncompartmental), whereas the AUC for proANF 1-30was 70,251 ± 9123 ng/liter/min (compartmental) and 64,885 ± 12,484ng/liter/min (noncompartmental).

	Discussion

Top Abstract Introduction Methods Results Discussion References

The present investigation revealed that the distribution volumes for vessel dilator and LANP are both slightly larger thanthe plasma volume. This is what one would expect if a peptidehormone is not subject to reuptake and recirculation. The presentdata, thus, suggest that vessel dilator and LANP are not takenup by tissues and then rereleased into the circulation.

The half-lives of vessel dilator and LANP determined in the present investigation were both significantly longer than thatdetermined previously for ANF in humans (Nakao et al., 1986; Tanet al., 1993; Yandle et al., 1986). Their longer half-lives andslower metabolic clearance (ANF MC rate; 582 ± 53 ml/min/1.73m² measured by us and 740-2,581 ml/min/m² reported by Iervasi et al., 1993) is the probable reason thatvessel dilator and LANP circulate in healthy humans at 15- to24-fold higher concentrations than ANF, a peptide hormone derivedfrom the same prohormone from which vessel dilator and LANP originate(fig. 1).

The longer half-lives of vessel dilator and LANP may account for their significantly (p < .001) prolonged natriuretic anddiuretic effects in humans compared with ANF (Vesely et al., 1994b).The MRTs for vessel dilator and LANP to be eliminated from thebody were 214 ± 34 and 178 ± 12 min, respectively. These valuesindicate that there is a considerable persistence of these twopeptide hormones after their respective infusions into healthyhumans and that they are widely distributed outside their initialspace (i.e., circulation). The average postdistribution phasehalf-life (i.e., when the plasma concentrations fell by 50% inthe postdistribution phase) of vessel dilator was 107 min. Thetotal postdistribution phase of (214 min) is nearly identicalto the MRT (214 ± 34 min) for vessel dilator and indicates thatthe V_dB is very close to the volume of distribution of the centralcompartment (VC) or the plasma volume.

LANP had a much longer TBC than did vessel dilator with no marked difference in V_dB. A t test comparison of MRC with TBC forLANP with both corrected to 1.73 m² BSA resulted in a t value of 0.8546, indicating no significantdifference between the two methods for determining clearance.The present exogenously administered pharmacological peptide investigationwould appear to have physiological significance in that endogenousLANP, vessel dilator and ANF when increased by pacing the heartof dogs, have a very similar temporal pharmacodynamic effect asthe exogenously administered peptides (Ackerman et al., 1992).It is important to note that the administration of the peptidesin the present investigation caused significant (p < .001) natriuresisand diuresis in the healthy subjects (Vesely et al., 1994b).

MC and TBC are measures of the disappearance of the respective peptides from the circulation. An error often incorporatedinto the one-compartment model is the difference in the dose andthe actual amount of the peptide hormone (or drug) in the bodyat the end of the infusion, which is the value of the numerator(Ackerman et al., 1990). This error can be eliminated by actuallymeasuring the concentration of the respective peptides at theend of its infusion, as was done in the present investigation.

In summary, this investigation reveals that vessel dilator and LANP hormones have half-lives of 107 and 28 min respectively.The MC rates of 241 ± 51 and 249 ± 62 ml/min/1.73 m² BSA for vessel dilator and LANP, respectively, were similar andare thus cleared much slower than ANF (582 ± 53 ml/min/1.73 m² BSA). The significantly (P < .001) longer half-lives and slowerclearance rates of LANP and vessel dilator compared with ANF explainwhy these peptides circulate at concentrations 15- to 24-foldhigher than ANF in healthy humans.

	Acknowledgments

We thank Sue Isaacs, Barbara Griffin, Persida Broussard and Charlene Pennington for excellent secretarial assistance and MargaretA. Douglass, RN, and George Rodriguez-Paz, MD, for assistancein the infusion of the cardiac peptides.

	Footnotes

Accepted for publication April 7, 1997.

Received for publication June 25, 1996.

¹ This work supported in part by a United States Department of Veterans Affairs Merit Review Grant and an American Heart AssociationFlorida Affiliate Grant to Dr. Vesely.

² Present address: SmithKline Beecham Pharmaceuticals, Philadelphia, PA.

Send reprint requests to: David L. Vesely, M.D. Ph.D., James A. Haley Veterans Hospital-151, 13000 Bruce B. Downs Boulevard, Tampa, FL 33612.

	Abbreviations

ANF, atrial natriuretic factor; LANP, long-acting natriuretic peptide; MRT, mean residence time; MC, metabolic clearance; BSA, body surface area; AUMC, area under the moment curve; RIA, radioimmunoassay; AUC, area under concentration curves; TBC, total body clearance; V_dB, $beta$ -distribution volume; a.a., amino acid(s); HPLC, high-pressure liquid chromatography; VC, volume of distribution of central compartment.

	References

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