Pharmacokinetics, excretion, and mass balance of 14C after administration of 14C-cholesterol-labeled AmBisome to healthy volunteers.

Amphotericin B (AmB) in small unilamellar liposomes (AmBisome) provides higher plasma concentrations and greater safety than the conventional deoxycholate formulation. The authors compared the disposition of the liposome's drug and cholesterol components by measuring AmB and radioactivity in plasma, urine, and feces for 1 week after a single 2-hour infusion of 14C-cholesterol-labeled AmBisome (2 mg/kg, 1 microgCi/kg) in healthy adults (4 males, 1 female). The plasma profile of 14C-cholesterol differed from that of AmB, lacking an initial rapid disappearance phase, having a lower total clearance, and having a volume of distribution (0.13 L/kg) close to that of the plasma compartment. The biphasic disappearance and long plasma half-life (147 h) of 14C-cholesterol were similar to those of other low-clearance liposomes. This and the low clearance of 14C-cholesterol from the plasma compartment suggest that it served as a liposome marker. The plasma drug-lipid ratio fell during the study, showing that AmB was cleared from plasma more rapidly than cholesterol or liposomes and suggesting that the composition of the liposomes changed over time. 14C-radioactivity was recovered mainly in the feces (9.5% of dose), consistent with the catabolism of cholesterol to bile salts. Combined fecal and renal clearances were < 18% of total clearance, suggesting that most of the liposomal drug and lipid remained in the body 1 week after dosing. Thus, AmBisome remains in the circulation for an extended period of time while releasing AmB, resulting in its markedly altered pharmacokinetic and safety profiles.

Safety, toxicokinetics and tissue distribution of long-term intravenous liposomal amphotericin B (AmBisome): a 91-day study in rats.

PURPOSE: Amphotericin B in small, unilamellar liposomes (AmBisome) is safer and produces higher plasma concentrations than other formulations. Because liposomes may increase and prolong tissue exposures, the potential for drug accumulation or delayed toxicity after chronic AmBisome was investigated. METHODS: Rats (174/sex) received intravenous AmBisome (1, 4, or 12 mg/kg), dextrose, or empty liposomes for 91 days with a 30-day recovery. Safety (including clinical and microscopic pathology) and toxicokinetics in plasma and tissues were evaluated. RESULTS: Chemical and histopathologic changes demonstrated that the kidneys and liver were the target organs for chronic AmBisome toxicity. Nephrotoxicity was moderate (urean nitrogen [BUN] < or = 51 mg/dl; creatinine unchanged). Liposome-related changes (vacuolated macrophages and hypercholesterolemia) were also observed. Although plasma and tissue accumulation was nonlinear and progressive (clearance and volume decreased, half-life increased with dose and time), most toxic changes occurred early, stabilized by the end of dosing, and reversed during recovery. There were no delayed toxicities. Concentrations in liver and spleen greatly exceeded those in plasma: kidney and lung concentrations were similar to those in plasma. Elimination half-lives were 1-4 weeks in all tissues. CONCLUSIONS: Despite nonlinear accumulation, AmBisome revealed predictable hepatic and renal toxicities after 91 days, with no new or delayed effects after prolonged treatment at high doses that resulted in plasma levels >200 microg/ml and tissue levels >3000 microg/g.

Safety and toxicokinetics of intravenous liposomal amphotericin B (AmBisome) in beagle dogs.

PURPOSE: Amphotericin B (AmB) in small, unilamellar liposomes (AmBisome) has an improved therapeutic index, and altered pharmacokinetics. The repeat-dose safety and toxicokinetic profiles of AmBisome were studied at clinically relevant doses. METHODS: Beagle dogs (5/sex/group) received intravenous AmBisome (0.25, 1, 4, 8, and 16 mg/kg/day), empty liposomes or vehicle for 30 days. AmB was determined in plasma on days 1, 14, and 30, and in tissues on day 31. Safety parameters included body weight, clinical chemistry, hematology and microscopic pathology. RESULTS: Seventeen of twenty animals receiving 8 and 16 mg/kg were sacrificed early due to weight loss caused by reduced food intake. Dose-dependent renal tubular nephrosis, and other effects characteristic of conventional AmB occurred at 1 mg/kg/day or higher. Although empty liposomes and AmBisome increased plasma cholesterol, no toxicities unique to AmBisome were revealed. Plasma ultrafiltrates contained no AmB. AmBisome achieved plasma levels 100-fold higher than other AmB formulations. AmBisome kinetics were non-linear, with clearance and distribution volumes decreasing with increasing dose. This, and nonlinear tissue uptake, suggest AmBisome disposition was saturable. CONCLUSIONS: AmBisome has the same toxic effects as conventional AmB, but they appear at much higher plasma exposures. AmBisome's non-linear pharmacokinetics are not associated with increased risk, as toxicity increases linearly with dosage. Dogs tolerated AmBisome with minimal to moderate changes in renal function at doses (4 mg/kg/day) producing peak plasma concentrations of 18-94 microg/mL.

Pharmacokinetics and urinary excretion of amikacin in low-clearance unilamellar liposomes after a single or repeated intravenous administration in the rhesus monkey.

Liposomal aminoglycosides have been shown to have activity against intracellular infections, such as those caused by Mycobacterium avium. Amikacin in small, low-clearance liposomes (MiKasome) also has curative and prophylactic efficacies against Pseudomonas aeruginosa and Klebsiella pneumoniae. To develop appropriate dosing regimens for low-clearance liposomal amikacin, we studied the pharmacokinetics of liposomal amikacin in plasma, the level of exposure of plasma to free amikacin, and urinary excretion of amikacin after the administration of single-dose (20 mg/kg of body weight) and repeated-dose (20 mg/kg eight times at 48-h intervals) regimens in rhesus monkeys. The clearance of liposomal amikacin (single-dose regimen, 0.023 +/- 0.003 ml min-1 kg-1; repeated-dose regimen, 0.014 +/- 0.001 ml min-1 kg-1) was over 100-fold lower than the creatinine clearance (an estimate of conventional amikacin clearance). Half-lives in plasma were longer than those reported for other amikacin formulations and declined during the elimination phase following administration of the last dose (from 81.7 +/- 27 to 30.5 +/- 5 h). Peak and trough (48 h) levels after repeated dosing reached 728 +/- 72 and 418 +/- 60 micrograms/ml, respectively. The levels in plasma remained > 180 micrograms/ml for 6 days after the administration of the last dose. The free amikacin concentration in plasma never exceeded 17.4 +/- 1 micrograms/ml and fell rapidly (half-life, 1.47 to 1.85 h) after the administration of each dose of liposomal amikacin. This and the low volume of distribution (45 ml/kg) indicate that the amikacin in plasma largely remained sequestered in long-circulating liposomes. Less than half the amikacin was recovered in the urine, suggesting that the level of renal exposure to filtered free amikacin was reduced, possibly as a result of intracellular uptake or the metabolism of liposomal amikacin. Thus, low-clearance liposomal amikacin could be administered at prolonged (2- to 7-day) intervals to achieve high levels of exposure to liposomal amikacin with minimal exposure to free amikacin.

Bioavailability of a small unilamellar low-clearance liposomal amikacin formulation after extravascular administration.

Amikacin in small, low-clearance liposomes (MiKasome) has prolonged plasma and tissue residence and in vivo activity against extracellular infections, including Klebsiella pneumonia and Pseudomonas endocarditis. Small liposomes may cross endothelial barriers, and enter the systemic circulation after extravascular administration. We compared the systemic bioavailability (F) of low-clearance liposomal amikacin in rats following intravenous (i.v.), intraperitoneal (i.p.), intramuscular (i.m.) and subcutaneous (s.c.) injection (20 mg/kg) and intratracheal (i.t.) instillation (10 mg/kg). Drug-containing liposomes were extensively absorbed after i.p. (F = 87-146%) and i.t. (F = 64%) administration, with maximum amikacin plasma concentrations of 171 micrograms/ml at 9 h and 80 micrograms/ml at 18 h, respectively. Absorption was slower and less extensive following s.c. (plasma Tmax: 20.3 micrograms/ml at 48 h) and i.m. (plasma Tmax: 49.6 micrograms/ml at 19 h) injection, but a significant fraction (12-27%) of the liposomes was absorbed. The plasma AUCs of liposomal amikacin exceeded the AUC of conventional i.v. amikacin by at least 25-fold for all routes. Amikacin AUCs in regional lymph nodes exceeded plasma AUCs by 4-fold after s.c. and i.m. injection of liposomal amikacin. AUCs in tissues surrounding the injection sites were 20- and 191-fold higher than plasma AUCs after i.m. and s.c. injection, respectively. Thus, small low-clearance liposomes produced sustained levels of liposome-encapsulated amikacin in plasma, local tissues and lymph nodes after extravascular administration, suggesting applications in perioperative prophylaxis, pneumonias and intralesional therapy as well as sustained systemic delivery of encapsulated drugs.

Altered tissue distribution and elimination of amikacin encapsulated in unilamellar, low-clearance liposomes (MiKasome).

PURPOSE: Amikacin in small unilamellar liposomes (MiKasome) has prolonged plasma residence (half-life > 24hr) and sustained efficacy in Gram-negative infection models. Since low-clearance liposomes may be subject to a lower rate of phagocytic uptake, we hypothesized this formulation may enhance amikacin distribution to tissues outside the mononuclear phagocyte system. METHODS: Rats received one intravenous dose (50 mg/kg) of conventional or liposomal amikacin. Amikacin was measured for ten days in plasma, twelve tissues, urine and bile. RESULTS: Liposomal amikacin increased and prolonged drug exposure in all tissues. Tissue half-lives (63-465 hr) exceeded the plasma half-life (24.5 hr). Peak levels occurred within 4 hours in some tissues, but were delayed 1-3 days in spleen, liver, lungs and duodenum, demonstrating the importance of characterizing the entire tissue concentration vs. time profile for liposomal drugs. Predicted steady-state tissue concentrations for twice weekly dosing were >100 microg/g. Less than half the liposomal amikacin was recovered in tissues and excreta, suggesting metabolism occurred. Amikacin was not detected in plasma ultrafiltrates. Tissue-plasma partition coefficients (0.2-0.8 in most tissues) estimated from tissue-plasma ratios at Tmax were similar to those estimated from tissue AUCs. CONCLUSIONS: Low-clearance liposomal amikacin increased and prolonged drug residence in all tissues compared to conventional amikacin. The long tissue half-lives suggest liposomal amikacin is sequestered within tissues, and that an extended dosing interval is appropriate for chronic or prophylactic therapy with this formulation.

Comparative tissue distribution and elimination of amphotericin B colloidal dispersion (Amphocil) and Fungizone after repeated dosing in rats.

The pharmacokinetic profiles of amphotericin B (AmB) after administration of Amphocil, an AmB/cholesteryl sulfate colloidal dispersion (ABCD) and the micellar AmB/deoxycholate (Fungizone) were compared after repeated dosing in rats. After administration of ABCD and Fungizone at an equal AmB dose (1 mg/kg), AmB concentrations in plasma and most tissues were lower for the ABCD dose, especially in the kidneys where reduced drug concentration correlated with reduced nephrotoxicity. In contrast, AmB concentrations in the liver were substantially higher when ABCD was administered; however, without an accompanying increase in hepatotoxicity. Daily administration of ABCD for 14 days did not lead to AmB accumulation in plasma; while a slight accumulation was observed after multiple administration of Fungizone. AmB was eliminated more slowly from the plasma and various tissues and urinary and fecal recoveries of AmB were reduced after ABCD administration. These results suggest that ABCD may be stored in tissues in a form that is less toxic and is eliminated from the systemic circulation by a different mechanism than the free and protein-bound AmB in plasma. AmB accumulation in the spleen was observed when higher, doses of ABCD (5 mg/kg) were administered, which could be due to saturation of hepatic uptake of AmB. Comparison of spleen concentrations of AmB between ABCD and Fungizone at 5 mg/kg AmB doses was not possible because of Fungizone's toxicity in rats. In all other organs, AmB concentrations reached or approached a steady state within two weeks of dosing with ABCD. Urinary and fecal clearences of AmB were not different between ABCD and Fungizone administration.(ABSTRACT TRUNCATED AT 250 WORDS)

Recombinant human hemoglobin inhibits both constitutive and cytokine-induced nitric oxide-mediated relaxation of rabbit isolated aortic rings.

A genetically engineered recombinant human hemoglobin (rHb1.1) was recently developed for use as a blood substitute (Nature 1992;356:258-60). Like other mammalian hemoglobin (Hb) molecules, it might bind and antagonize the actions of nitric oxide (NO). We used an isolated rabbit aortic ring preparation to examine the ability of rHb1.1 to inhibit acetylcholine (ACh)- and interleukin-1 beta (IL-1 beta)-induced reductions of vasoconstrictor responses to the alpha-adrenoceptor agonist phenylephrine (PE). rHb1.1 (0.04-4.4 microM) rapidly and reversibly inhibited, in a concentration-dependent manner, both ACh- and IL-1 beta-induced decreases in PE contractile responses. These inhibitory effects of rHb1.1 were non-competitive and were equipotent to those of purified, cell-free human Hb (p.hHb). These two forms of soluble Hb were at least 10 times more potent than Hb in erythrocytes (red blood cells: RBC-Hb). Both NG-nitro-L-arginine (10 microM) a NO synthase inhibitor, and LY-83583 (10 microM), a guanylyl cyclase inhibitor, mimicked the effects of rHb1.1. The inhibitory effects of rHb1.1 were not shared by either human serum albumin (HSA 44 microM), which combines with but does not deactivate NO, or cytochrome C (44 microM), a heme-containing protein that does not bind NO; neither were they reversed by L-arginine (L-ARG) (1 mM), the presumed NO precursor. These and other results suggest that the chemical antagonism of NO is likely to be the mechanism by which rHb1.1 and other Hbs inhibit ACh- and IL-1 beta-induced decreases in the response to PE in rabbit aortic rings.

High-performance liquid chromatographic analysis of amphotericin B in plasma, blood, urine and tissues for pharmacokinetic and tissue distribution studies.

A sensitive and reproducible high-performance liquid chromatographic method was developed to assay ampherotericin B in plasma, blood, urine and various tissue samples. Amphotericin B was isolated from each sample matrix by solid-phase extraction (Bond-Elut). The eluate from Bond-Elut containing amphotericin B was injected onto a reversed-phase C18 column (Waters, mu Bondpak, 10 microns, 300 mm x 3.9 mm I.D.) with a mobile phase of 45% acetonitrile in 2.5 mM Na2EDTA at 1 ml/min. Detection of amphotericin B was by ultraviolet absorption at 382 nm. Blood and tissues were homogenized and extracted with methanol prior to Bond-Elut extraction. The extraction efficiencies of amphotericin B from plasma, blood and tissues were approximately 90, 70 and 75%, respectively. The sensitivity of the assay was less than or equal to 5 ng/ml for plasma, less than or equal to 25 ng/ml for blood, 2.5 ng/ml for urine and 50 ng/g for tissues. The linearity of the assay method was up to 2.5 micrograms/ml for plasma, 5 micrograms/ml for blood, 500 ng/ml for urine and 500 micrograms/g for tissues. The assay was reproducible with an intra-day coefficient of variation (C.V., n = 3) of less than 5% in general for plasma, blood and tissues. The inter-day C.V. of the assay was less than 5% for plasma (n = 5), less than 10% for blood (n = 4) and less than 5% for tissues (n = 3). The overall variability in the urine assay was generally less than 10%. This method has demonstrated significant improvement in the sensitivity and reproducibility in assaying amphotericin B in plasma and especially in blood, urine and tissues. We have employed this assay to compare the pharmacokinetic and tissue distribution profiles of amphotericin B in rats and dogs following administration of Fungizone and ABCD (amphotericin B-cholesteryl sulfate colloidal dispersion), a lipid-based dosage form. In addition, the assay method for plasma and urine samples can also be applied to pharmacokinetics studies of amphotericin B in man.

Factors affecting the release rate of terbutaline from liposome formulations after intratracheal instillation in the guinea pig.

Maximum duration of bronchodilator efficacy in inhaled liposome-based formulations depends on optimizing the in vivo release rate of the encapsulated bronchodilator. We investigated the effect of several formulation variables on the pulmonary residence time of 3H-terbutaline sulfate liposomes administered intratracheally in guinea pigs, using an improved method enabling the measurement of pulmonary drug absorption for extended periods of time in conscious animals. Half-lives of liposome-encapsulated 3H-terbutaline disappearance from the lungs and airways after instillation ranged from 1.4 to 18 hr and were markedly affected by liposome size, cholesterol content, and phospholipid composition. This study demonstrates that liposomes can significantly prolong the residence time of bronchodilators in the lungs and that precise control over the pulmonary residence time of encapsulated bronchodilators can be achieved by controlling formulation variables.

Relationship of pharmacokinetics and drug distribution in tissue to increased safety of amphotericin B colloidal dispersion in dogs.

The safety, pharmacokinetics, and distribution in tissue of an amphotericin B (AmB)-cholesteryl sulfate colloidal dispersion (ABCD) were compared with those of micellar amphotericin B-deoxycholate (m-AmB). Dogs received 14 daily injections of ABCD (0.6 to 10 mg/kg of body weight per day) or m-AmB (0.6 mg/kg/day). Safety was evaluated by monitoring body weight, hematology, clinical chemistry, and urinalysis during the study and by microscopic examination of tissues at the time of necropsy (day 16). AmB concentrations in plasma were measured in some groups on days 1, 7, and 14 and in necropsy tissue samples. ABCD produced a spectrum of toxic effects in the kidneys, gut, and liver similar to those of m-AmB, but ABCD was eightfold safer than m-AmB. The highest tolerated dose of ABCD (5.0 mg/kg/day) produced effects similar to those of m-AmB (0.6 mg/kg/day). ABCD produced lower concentrations in plasma than an equal dose of m-AmB did. Clearances on days 7 and 14 were higher for ABCD (304 and 295 ml/h.kg) than they were for m-AmB (67 and 53 ml/h.kg). Concentrations in plasma reached steady state after ABCD administration, but they increased after repeated dosing with m-AmB. Diurnal fluctuations in AmB concentrations in plasma were observed 4 to 8 h after the time of dosing. ABCD resulted in lower AmB concentrations in tissue than m-AmB did, except in the reticuloendothelial system. Up to 90% of AmB administered as ABCD was recovered from the liver and spleen on day 16. Reduced drug levels in the kidneys and gut correlated with reduced indications of toxicity in these organs after ABCD administration. Although ABCD increased concentrations of AmB in the reticuloendothelial system, increased toxicity was not observed in these organs.

Comparative pharmacokinetics of amphotericin B after administration of a novel colloidal delivery system, ABCD, and a conventional formulation to rats.

The pharmacokinetics and tissue distribution of two amphotericin B dosage forms were compared in rats. A novel lipid-based colloidal delivery system for amphotericin B (Amphotericin B Colloidal Dispersion [ABCD]) which reduces the toxicity of amphotericin B in animals was compared with a conventional micellar formulation. Male Sprague-Dawley rats received a single intravenous injection of 1.0 mg of ABCD, 5.0 mg of ABCD, or 1.0 mg of micellar amphotericin B per kg. Plasma and tissue samples were obtained at 0.5 to 96 h after dosing and analyzed for amphotericin B by high-pressure liquid chromatography. Animals receiving ABCD demonstrated reduced peak levels in plasma, a three- to sevenfold reduction in amphotericin B delivery to the kidneys (the major target organ for toxicity), and prolonged residence time compared with those receiving the micellar formulation. In contrast, amphotericin B concentrations in the liver were two- to threefold higher with ABCD than with the micellar formulation: nearly 100% of the amphotericin B administered as ABCD was recovered from the liver 30 min after dosing. These results suggest that the colloidal particles of ABCD are taken up by the liver, which then acts as a reservoir of amphotericin B.

Time-dependent, plasma-sulfate-independent kinetics of salicylamide in dogs.

The mechanisms of the dose-dependent elimination kinetics of salicylamide in dogs were examined. Salicylamide was infused continuously over three consecutive 90-min periods. The rates of infusion during Periods I and III were the same. During Period II the infusion rate was 2.5-fold higher. Plasma concentrations of inorganic sulfate were kept constant by the administration of exogenous sulfate. The plasma concentrations of salicylamide, which reached steady state during Period I but not during II or III, were twice as high at the end of Period III than those at the end of Period I. Typical Michaelis-Menten kinetics do not explain these results. When salicylamide was given as 40 mg/kg single oral dose, clearance of an intravenous tracer dose of radiolabeled salicylamide was greatly reduced within 10 min but returned to baseline values by 240 min after the oral dose, despite persistently low plasma concentrations of inorganic sulfate. Therefore, dose- and time-dependent factors other than Michaelis-Menten kinetics, depletion of inorganic sulfate concentrations, and rate limitation of supply of "active sulfate" from plasma inorganic sulfate stores produce the dose- and time-dependent kinetics of salicylamide in the dog. Product inhibition of salicylamide sulfoconjugation remains a possible explanation.

Nonlinear intestinal first-pass metabolism of salicylamide in dogs after portacaval transposition.

The dose-dependent first-pass metabolism and pharmacokinetics of salicylamide (SAM) were studied at four dose levels in dogs before and after portacaval transposition. Four minutes after each p.o. dose, a tracer dose of [14C]SAM was given i.v. to determine clearance and bioavailability. Over the dosage range studied pretransposition, 5 to 40 mg/kg, bioavailability increased from 0.24 +/- 0.14 (mean +/- S.D.) to 0.76 +/- 0.20 (P less than .05). Clearance decreased from 3.4 +/- 1.0 to 0.6 +/- 0.11 liter/min (P less than .01) and half-life increased from 5.0 +/- 1.2 to 23.5 +/- 6.1 min (P less than .01). Over the dosage range studied post-transposition, 1.5 to 20 mg/kg, bioavailability increased from 0.31 +/- 0.09 to 0.99 +/- 0.08. Clearance and half-life had the same values and showed the same dose-dependence as in the normal dogs. The amount of SAM removed by the intestine during first-pass remained constant at about 1 mg/kg over the dose range given to the post-transposition animals. Therefore, although more easily saturable than the liver, the intestine plays an important role in first-pass metabolism of low p.o. doses of SAM. In contrast to previous results in the normal dog, the p.o. coadministration of sodium sulfate did not reduce the bioavailability of SAM in transposed dogs. This indicates that the nonlinear intestinal first-pass metabolism of SAM is not due to the depletion of the cosubstrate precursor, inorganic sulfate.

Extrahepatic extraction of salicylamide in dogs.

Extrahepatic conjugation may be an important mechanism for the metabolism of many phenolic compounds. We have observed dose-dependent sulfoconjugation of salicylamide (SAM) in the lung, kidney and forelimb of dogs during steady-state infusions. The lungs alone accounted for more than one-half the total elimination at the lowest infusion rate (0.3 microgram/min/kg). The limbs appeared to play an important secondary role in SAM elimination whereas the kidneys made only a minor contribution to total elimination. At the highest infusion rate (500 micrograms/min/kg), extrahepatic extraction approached zero and elimination by the three extrahepatic sites fell to less than 31% of total elimination. Dose-dependent elimination at the three extrahepatic sites was responsible for most of the dose dependence observed in these studies. Extrahepatic extraction was insensitive to plasma inorganic sulfate. Clearance significantly, but only slightly, increased on coinfusing sodium sulfate at a rate that increased plasma inorganic sulfate from one-sixth (after depletion by SAM infusion) to two times normal.

Dose-dependent sulfoconjugation of salicylamide in dogs: effect of sulfate depletion or administration.

The effects of plasma inorganic sulfate concentrations on the dose-dependent kinetics of salicylamide (SAM) were examined in the dog. Decreasing plasma sulfate concentrations from 0.9 mM to less than 0.3 mM significantly decreased clearance of a small dose of SAM (5 mg/kg) to the sulfate conjugate. Infusing sodium sulfate to prevent the decrease in plasma inorganic sulfate concentration that follows a p.o. 20-mg/kg dose of SAM did not increase SAM elimination. However, sodium sulfate given p.o. decreased SAM bioavailability, which suggests a local effect of sulfate on intestinal first-pass metabolism of SAM. These data show some dependence of SAM metabolism on plasma inorganic sulfate concentrations, but only when they are markedly reduced.