Drug reformulation for a neglected disease. The NANOHAT project to develop a safer more effective sleeping sickness drug

Background

Human African trypanosomiasis (HAT or sleeping sickness) is caused by the parasite Trypanosoma brucei sspp. The disease has two stages, a haemolymphatic stage after the bite of an infected tsetse fly, followed by a central nervous system stage where the parasite penetrates the brain, causing death if untreated. Treatment is stage-specific, due to the blood-brain barrier, with less toxic drugs such as pentamidine used to treat stage 1. The objective of our research programme was to develop an intravenous formulation of pentamidine which increases CNS exposure by some 10–100 fold, leading to efficacy against a model of stage 2 HAT. This target candidate profile is in line with drugs for neglected diseases inititative recommendations.

Methodology

To do this, we evaluated the physicochemical and structural characteristics of formulations of pentamidine with Pluronic micelles (triblock-copolymers of polyethylene-oxide and polypropylene oxide), selected candidates for efficacy and toxicity evaluation in vitro, quantified pentamidine CNS delivery of a sub-set of formulations in vitro and in vivo, and progressed one pentamidine-Pluronic formulation for further evaluation using an in vivo single dose brain penetration study.

Principal Findings

Screening pentamidine against 40 CNS targets did not reveal any major neurotoxicity concerns, however, pentamidine had a high affinity for the imidazoline₂ receptor. The reduction in insulin secretion in MIN6 β-cells by pentamidine may be secondary to pentamidine-mediated activation of β-cell imidazoline receptors and impairment of cell viability. Pluronic F68 (0.01%w/v)-pentamidine formulation had a similar inhibitory effect on insulin secretion as pentamidine alone and an additive trypanocidal effect in vitro. However, all Pluronics tested (P85, P105 and F68) did not significantly enhance brain exposure of pentamidine.

Significance

These results are relevant to further developing block-copolymers as nanocarriers, improving BBB drug penetration and understanding the side effects of pentamidine.

Sleeping sickness or human African Trypanosomiasis (HAT) is a disease caused by a parasite, which is transferred to humans by the bite of an infected tsetse fly. There are two disease stages: the first stage is the blood-based stage of the disease and the second stage affects the brain. It is fatal if left untreated. The blood-brain barrier (BBB) makes the brain stage difficult to treat because it prevents 99% of all drugs from entering the brain from the blood. Those anti-HAT drugs that do enter the brain are toxic and have serious side effects. Pentamidine is a less toxic blood stage drug, which our research has shown has a limited ability to cross the BBB due to its removal by proteins called transporters. The objective of this study was to use Pluronic to improve pentamidine delivery to target sites, whilst reducing its side effects. Pluronic is a polymer, which can assemble into micelles and encapsulate the drug. Thus, prolonging its circulation time and protecting it. Our study indicated that the selected Pluronics did not increase the brain delivery of pentamidine. However. Pluronic-pentamidine formulations were identified that harboured trypanocidal activity and did not increase safety concerns compared to unformulated pentamidine.

Oral pentamidine-loaded poly(d,l-lactic-co-glycolic) acid nanoparticles: an alternative approach for leishmaniasis treatment

Leishmaniasis is a group of diseases caused by a protozoa parasite from one of over 20 Leishmania species. Depending on the tissues infected, these diseases are classified as cutaneous, mucocutaneous and visceral leishmaniasis. For the treatment of leishmaniasis refractory to antimony-based drugs, pentamidine (PTM) is a molecule of great interest. However, PTM displays poor bioavailability through oral routes due to its two strongly basic amidine moieties, which restricts its administration by a parenteral route and limits its clinical use. Among various approaches, nanotechnology-based drug delivery systems (nano-DDS) have potential to overcome the challenges associated with PTM oral administration. Here, we present the development of PTM-loaded PLGA nanoparticles (NPs) with a focus on the characterization of their physicochemical properties and potential application as an oral treatment of leishmaniasis. NPs were prepared by a double emulsion methodology. The physicochemical properties were characterized through the mean particle size, polydispersity index (PdI), zeta potential, entrapment efficiency, yield process, drug loading, morphology, in vitro drug release and in vivo pharmacological activity. The PTM-loaded PLGA NPs presented with a size of 263 ± 5 nm (PdI = 0.17 ± 0.02), an almost neutral charge (-3.2 ± 0.8 mV) and an efficiency for PTM entrapment of 91.5%. The release profile, based on PTM dissolution, could be best described by a zero-order model, followed by a drug diffusion profile that fit to the Higuchi model. In addition, in vivo assay showed the efficacy of orally given PTM-loaded PLGA NPs (0.4 mg kg^-1) in infected BALB/c mice, with significant reduction of organ weight and parasite load in spleen (p-value < 0.05). This work successfully reported the oral use of PTM-loaded NPs, with a high potential for the treatment of visceral leishmaniasis, opening a new perspective to utilization of this drug in clinical practice.

inPentasomes: An innovative nose-to-brain pentamidine delivery blunts MPTP parkinsonism in mice

Preclinical and clinical evidences have demonstrated that astroglial-derived S100B protein is a key element in neuroinflammation underlying the pathogenesis of Parkinson's disease (PD), so much as that S100B inhibitors have been proposed as promising candidates for PD targeted therapy. Pentamidine, an old-developed antiprotozoal drug, currently used for pneumocystis carinii is one of the most potent inhibitors of S100B activity, but despite this effect, is limited by its low capability to cross blood brain barrier (BBB). To overcome this problem, we developed a non-invasive intranasal delivery system, chitosan coated niosomes with entrapped pentamidine (inPentasomes), in the attempt to provide a novel pharmacological approach to ameliorate parkinsonism induced by subchronic MPTP administration in C57BL-6 J mice. inPentasomes, prepared by evaporation method was administered daily by intranasal route in subchronic MPTP-intoxicated rodents and resulted in a dose-dependent manner (0.001-0.004 mg/kg) capable for a significant Tyrosine Hydroxylase (TH) positive neuronal density rescue in both striatum and substantia nigra of parkinsonian mice. In parallel, inPentasomes significantly decreased the extent of glial-related neuroinflammation through the reduction of specific gliotic markers (Iba-1, GFAP, COX-2, iNOS) with consequent PGE₂ and NO₂^- release reduction, in nigrostriatal system. inPentasomes-mediated S100B inhibition resulted in a RAGE/NF-κB pathway downstream inhibition in the nigrostriatal circuit, causing a marked amelioration of motor performances in intoxicated mice. On the basis of our results, chitosan coated niosomes loaded with pentamidine, the inPentasome system, self-candidates as a promising new intranasal approach to mitigate parkinsonism in humans and possibly paves the way for a possible clinical repositioning of pentamidine as anti-PD drug.

Specific Cell Targeting Therapy Bypasses Drug Resistance Mechanisms in African Trypanosomiasis

African trypanosomiasis is a deadly neglected disease caused by the extracellular parasite Trypanosoma brucei. Current therapies are characterized by high drug toxicity and increasing drug resistance mainly associated with loss-of-function mutations in the transporters involved in drug import. The introduction of new antiparasitic drugs into therapeutic use is a slow and expensive process. In contrast, specific targeting of existing drugs could represent a more rapid and cost-effective approach for neglected disease treatment, impacting through reduced systemic toxicity and circumventing resistance acquired through impaired compound uptake. We have generated nanoparticles of chitosan loaded with the trypanocidal drug pentamidine and coated by a single domain nanobody that specifically targets the surface of African trypanosomes. Once loaded into this nanocarrier, pentamidine enters trypanosomes through endocytosis instead of via classical cell surface transporters. The curative dose of pentamidine-loaded nanobody-chitosan nanoparticles was 100-fold lower than pentamidine alone in a murine model of acute African trypanosomiasis. Crucially, this new formulation displayed undiminished in vitro and in vivo activity against a trypanosome cell line resistant to pentamidine as a result of mutations in the surface transporter aquaglyceroporin 2. We conclude that this new drug delivery system increases drug efficacy and has the ability to overcome resistance to some anti-protozoal drugs.

Systematic exploration of synergistic drug pairs

Drug synergy allows a therapeutic effect to be achieved with lower doses of component drugs. Drug synergy can result when drugs target the products of genes that act in parallel pathways ('specific synergy'). Such cases of drug synergy should tend to correspond to synergistic genetic interaction between the corresponding target genes. Alternatively, 'promiscuous synergy' can arise when one drug non-specifically increases the effects of many other drugs, for example, by increased bioavailability. To assess the relative abundance of these drug synergy types, we examined 200 pairs of antifungal drugs in S. cerevisiae. We found 38 antifungal synergies, 37 of which were novel. While 14 cases of drug synergy corresponded to genetic interaction, 92% of the synergies we discovered involved only six frequently synergistic drugs. Although promiscuity of four drugs can be explained under the bioavailability model, the promiscuity of Tacrolimus and Pentamidine was completely unexpected. While many drug synergies correspond to genetic interactions, the majority of drug synergies appear to result from non-specific promiscuous synergy.

Diamidines for human African trypanosomiasis

Aromatic diamidines are potent trypanocides. Pentamidine, a diamidine, has been used for more than 60 years to treat human African trypanosomiasis (HAT); however, the drug must be administered parenterally and is active against first-stage HAT only, prior to the parasites causing neurological deterioration through invasion of the CNS. A major research effort to design novel diamidines has led to the development of orally active prodrugs and, remarkably, a new generation of compounds that can penetrate the CNS. In this review, progress in the development of diamidines for the treatment of HAT is discussed.

Diacetyldiamidoximeester of pentamidine, a prodrug for treatment of protozoal diseases: synthesis, in vitro and in vivo biotransformation

Pentamidine is an effective antimicrobial agent. To increase its poor oral bioavailability due to the strong basic amidine functionality, the less basic O-acetylamidoxime prodrug, the diacetyldiamidoximeester, was used, which has greatly improved lipophilicity. The objectives of this investigation were the synthesis of all potential metabolites of the double prodrug, the conformational analysis of its structure, and to study the in vitro and in vivo biotransformation by ester cleavage and N-reduction to pentamidine via four intermediate metabolites. The biotransformation of diacetyldiamidoximeester to pentamidine involving the reduction of the amidoxime function and the ester cleavage could be demonstrated. The kinetic parameters were determined. Amidoximes were efficiently metabolized by several enzyme systems located in microsomes and mitochondria of different organs including the final formation of the active metabolite pentamidine. The formation of pentamidine after oral administration of the diacetyldiamidoximeester to rats could be demonstrated as well.

Loss of the high-affinity pentamidine transporter is responsible for high levels of cross-resistance between arsenical and diamidine drugs in African trypanosomes

Treatment of many infectious diseases is under threat from drug resistance. Understanding the mechanisms of resistance is as high a priority as the development of new drugs. We have investigated the basis for cross-resistance between the diamidine and melaminophenyl arsenical classes of drugs in African trypanosomes. We induced high levels of pentamidine resistance in a line without the tbat1 gene that encodes the P2 transporter previously implicated in drug uptake. We isolated independent clones that displayed very considerable cross-resistance with melarsen oxide but not phenylarsine oxide and reduced uptake of [(3)H]pentamidine. In particular, the high-affinity pentamidine transport (HAPT1) activity was absent in the pentamidine-adapted lines, whereas the low affinity pentamidine transport (LAPT1) activity was unchanged. The parental tbat1(-/-) line was sensitive to lysis by melarsen oxide, and this process was inhibited by low concentrations of pentamidine, indicating the involvement of HAPT1. This pentamidine-inhibitable lysis was absent in the adapted line KO-B48. Likewise, uptake of the fluorescent diamidine 4',6-diamidino-2-phenylindole dihydrochloride was much delayed in live KO-B48 cells and insensitive to competition with up to 10 muM pentamidine. No overexpression of the Trypanosoma brucei brucei ATP-binding cassette transporter TbMRPA could be detected in KO-B48. We also show that a laboratory line of Trypanosoma brucei gambiense, adapted to high levels of resistance for the melaminophenyl arsenical drug melarsamine hydrochloride (Cymelarsan), had similarly lost TbAT1 and HAPT1 activity while retaining LAPT1 activity. It seems therefore that selection for resistance to either pentamidine or arsenical drugs can result in a similar phenotype of reduced drug accumulation, explaining the occurrence of cross-resistance.

Accumulation and intracellular distribution of antitrypanosomal diamidine compounds DB75 and DB820 in African trypanosomes

The aromatic diamidine pentamidine has long been used to treat early-stage human African trypanosomiasis (HAT). Two analogs of pentamidine, DB75 and DB820, have been shown to be more potent and less toxic than pentamidine in murine models of trypanosomiasis. The diphenyl furan diamidine, DB75, is the active metabolite of the prodrug DB289, which is currently in phase III clinical trials as a new orally active candidate drug to treat first-stage HAT. The new aza analog, DB820, is the active diamidine of the prodrug DB844, currently undergoing preclinical evaluation as a new candidate to treat HAT of the central nervous system. The exact mechanisms of antitrypanosomal activity of aromatic dications remain poorly understood, with multiple mechanisms hypothesized. Pentamidine is known to be actively transported into trypanosomes and binds to DNA within the nucleus and kinetoplast. A long-hypothesized mechanism of action has been that DNA binding ultimately leads to interference with DNA-associated enzymes. Both DB75 and DB820 are intensely fluorescent, which provides an important tool for determining the kinetics of accumulation and intracellular distribution in trypanosomes. We show in the current study that DB75 and DB820 rapidly accumulate and strongly concentrate within trypanosomes, with intracellular concentrations over 15,000-fold higher than mouse plasma concentrations. Both compounds initially accumulate in the DNA-containing nucleus and kinetoplast, but at later time points, they concentrate in non-DNA-containing cytoplasmic organelles. Analyses of the kinetics of uptake and intracellular distribution are necessary to begin to define antitrypanosomal mechanisms of action of DB75, DB820, and other aromatic diamidines.

Characterization of the choline carrier of Plasmodium falciparum: a route for the selective delivery of novel antimalarial drugs

New drugs are urgently needed to combat the growing problem of drug resistance in Plasmodium falciparum malaria. The infected erythrocyte is a multicompartmental system, and its transporters are of interest as drug targets in their own right and as potential routes for the delivery of antimalarial drugs. Choline is an important nutrient that penetrates infected erythrocyte membranes through the endogenous carrier and through parasite-induced permeability pathways, but nothing is known about its transport into the intracellular parasite. Here we present the first characterization of choline transport across the parasite membrane. Transport exhibits Michaelis-Menten kinetics with an apparent Km of 25.0 ± 3.5 μM for choline. The carrier is inhibitor-sensitive, temperature-dependent, and Na+-independent, and it is driven by the proton-motive force. Highly active bis-amidine and bis-quaternary ammonium compounds are also known to penetrate the host erythrocyte membrane through parasite-induced permeability pathways. Here, we demonstrate that the parasite choline transporter mediates the delivery of these compounds to the intracellular parasite. Thus, the induced permeability pathways in the host erythrocyte membrane and the parasite choline transporter described here form a cooperative transport system that shows great promise for the selective targeting of new agents for the chemotherapy of malaria. (Blood. 2004;104: 3372-3377)

Mechanisms of arsenical and diamidine uptake and resistance in Trypanosoma brucei

Sleeping sickness, caused by Trypanosoma brucei spp., has become resurgent in sub-Saharan Africa. Moreover, there is an alarming increase in treatment failures with melarsoprol, the principal agent used against late-stage sleeping sickness. In T. brucei, the uptake of melarsoprol as well as diamidines is thought to be mediated by the P2 aminopurine transporter, and loss of P2 function has been implicated in resistance to these agents. The trypanosomal gene TbAT1 has been found to encode a P2-type transporter when expressed in yeast. Here we investigate the role of TbAT1 in drug uptake and drug resistance in T. brucei by genetic knockout of TbAT1. Tbat1-null trypanosomes were deficient in P2-type adenosine transport and lacked adenosine-sensitive transport of pentamidine and melaminophenyl arsenicals. However, the null mutants were only slightly resistant to melaminophenyl arsenicals and pentamidine, while resistance to other diamidines such as diminazene was more pronounced. Nevertheless, the reduction in drug sensitivity might be of clinical significance, since mice infected with tbat1-null trypanosomes could not be cured with 2 mg of melarsoprol/kg of body weight for four consecutive days, whereas mice infected with the parental line were all cured by using this protocol. Two additional pentamidine transporters, HAPT1 and LAPT1, were still present in the null mutant, and evidence is presented that HAPT1 may be responsible for the residual uptake of melaminophenyl arsenicals. High-level arsenical resistance therefore appears to involve the loss of more than one transporter.

Current chemotherapy of human African trypanosomiasis

Human African trypanosomiasis is a fatal disease caused by Trypanosoma brucei gambiense and Trypanosoma brucei rhodesiense that has re-emerged in recent years. However, very little progress has been made in the development of new drugs against this disease. Most drugs still in use were developed one or more decades ago, and are generally toxic and of limited effectiveness. The most recently introduced compound, eflornithine, is only useful against sleeping sickness caused by T. b. gambiense, and is prohibitively expensive for the African developing countries. We present here an overview of today's approved and clinically used drugs against this disease.

Arsenicals (melarsoprol), pentamidine and suramin in the treatment of human African trypanosomiasis

Human African trypanosomiasis (HAT), otherwise known as sleeping sickness, has remained a disease with no effective treatment. Recent progress in HAT research suggests that a vaccine against the disease is far from being successful. Also the emergence of drug-resistant trypanosomes makes further work in this area imperative. So far the treatment for the early stage of HAT involves the drugs pentamidine and suramin which have been very successful. In the second stage of the disease, during which the trypanosomes reside in the cerebrospinal fluid (CSF), treatment is dependent exclusively on the arsenical compound melarsoprol. This is largely due to the inability to find compounds that can cross the blood brain barrier and kill the CSF-residing trypanosomes. This review summarises our current understanding on the treatment of HAT.

Resistance to pentamidine in Leishmania mexicana involves exclusion of the drug from the mitochondrion

The uptake of [(3)H]pentamidine into wild-type and drug-resistant strains of Leishmania mexicana was compared. Uptake was carrier mediated. Pentamidine-resistant parasites showed cross-resistance to other toxic diamidine derivatives. A substantial decrease in accumulation of the drug accompanied the resistance phenotype, although the apparent affinity for pentamidine by its carrier was not altered when initial uptake velocity was measured. The apparent V(max), however, was reduced. An efflux of pentamidine could be measured in both wild-type and resistant cells. Only a relatively small proportion of the total accumulated pentamidine was available for efflux in wild-type cells, while in resistant cells the majority of loaded pentamidine was available for release. Pharmacological reagents which diminish the mitochondrial membrane potential reduced pentamidine uptake in wild-type parasites, and the mitochondrial membrane potential was shown to be reduced in resistant cells. A fluorescent analogue of pentamidine, 4',6'-diamidino-2-phenylindole, accumulated in the kinetoplast of wild-type but not resistant parasites. These data together indicate that diamidine drugs accumulate in the Leishmania mitochondrion and that the development of the resistance phenotype is accompanied by lack of mitochondrial accumulation of the drug and its exclusion from the parasites.

A novel HPLC assay for pentamidine: comparative effects of creatinine and inulin on GFR estimation and pentamidine renal excretion in the isolated perfused rat kidney

PURPOSE

1. To develop and validate an analytical method for pentamidine (PTM) by reversed-phase HPLC. 2. To compare the effects of creatinine and inulin on PTM excretion in the isolated perfused rat kidney.

METHODS

The HPLC method utilized a base deactivated, 5 micro, C18 column and a mobile phase containing acetonitrile (24%) and 0.025 M monobasic phosphate buffer, pH 3.2 (76%). Mobile phase flow rate and UV detection wavelength were 1 mL/min and 270 nm, respectively. Sulfadiazine (SDZ) was used as the internal standard. The method was used to measure pentamidine in perfusate and urine samples generated from studies with the isolated perfused rat kidney (IPK) model. Perfusion experiments were conducted in the presence of two different GFR markers: creatinine and inulin (PTM dose 800 micro g). Both creatinine and inulin were assayed using colorimetric methods.

RESULTS

The HPLC assay is rapid, sensitive and reproducible. The method was validated over two standard concentration ranges: 0.1 to 1 micro g/mL, and 1 to 10 micro g/mL. In control (drug-naïve) IPK perfusions, creatinine clearance was approximately 15% greater than inulin clearance (0.80+/- 0.21 mL/min vs. 0.69+/-0.17 mL/min, p > 0.05). In the presence of PTM, however, creatinine clearance was reduced to 0.56+/-0.27 (p < 0.05 compared to control). Inulin clearance was not altered by PTM administration (0.76+/-0.26 mL/min). Cumulative urinary excretion of PTM (% dose) was 3.0+/-0.47% and 9.6+/-4.2% in the presence of creatinine and inulin, respectively. PTM clearance was significantly reduced (0.06+/-0.01 mL/min vs. 0.13+/-0.01 mL/min, p < 0.05) and % kidney accumulation significantly enhanced (66+/-4.7% vs. 37+/-9.7%, p < 0.05) by creatinine.

CONCLUSIONS

Creatinine overestimated GFR in the IPK. The altered renal excretion of PTM by creatinine is consistent with inhibition of PTM tubular secretion. Because of increased kidney accumulation, detrimental effects of PTM on renal function were observed. Based on these findings, creatinine should be used cautiously as an indicator of GFR in IPK experimentation.

Serial pentamidine levels in bronchial epithelial lining fluid after aerosol administration

BACKGROUND

There is no information on serial pharmacokinetic assessment in the lungs after administration of aerosolized pentamidine.

OBJECTIVE

The present study was performed to evaluate the elimination of aerosolized pentamidine from bronchial airways following inhalation.

METHODS

We used 4 sheep with tracheotomies in the present study. Pentamidine (300 mg) was administered by inhalation to each animal. Serial bronchial washing to obtain epithelial lining fluid (ELF) was performed 1, 7, 10, 14, 21 and 28 days after administration of aerosolized pentamidine in each animal. The pentamidine concentration in the supernatant of ELF was measured by high-performance liquid chromatography.

RESULTS

The maximal pentamidine level on the first day (12 h after inhalation) was 616.5 +/- 238.2 ng/ml (mean +/- SE) in ELF. The pentamidine levels rapidly decreased within 2 weeks (8.9 +/- 1.2 ng/ml at 14 days), followed by slow elimination (8.9 +/- 0.8 ng/ml at 28 days). Thus, inhaled pentamidine showed a rapid clearance from the bronchial wall within the first 2 weeks.

CONCLUSIONS

These findings may be useful in designing and interpreting future studies of aerosolized pentamidine in patients who are receiving inhaled pentamidine, especially for those with failure of prophylaxis for Pneumocystis carinii pneumonia.

Diamidine compounds: selective uptake and targeting in Plasmodium falciparum

Extensive drug resistance in Plasmodium falciparum emphasizes the urgent requirement for novel antimalarial agents. Here we report potent antimalarial activity of a number of diamidine compounds. The lead compound pentamidine is concentrated 500-fold by erythrocytes infected with P. falciparum. Pentamidine accumulation can be blocked by inhibitors of hemoglobin digestion, suggesting that the drug binds to ferriprotoporphyrin IX (FPIX). All of the compounds bound to FPIX in vitro and inhibited the formation of hemozoin. Furthermore, inhibitors of hemoglobin digestion markedly antagonized the antimalarial activity of the diamidines, indicating that binding to FPIX is crucial for the activity of diamidine drugs. Pentamidine was not accumulated into uninfected erythrocytes. Pentamidine transport into infected cells exhibits an initial rapid phase, nonsaturable in the micromolar range and sensitive to inhibition by furosemide and glibenclamide. Changing the counter-ion in the order Cl(-) < Br(-) < NO(2)(-) < I(-) <SCN(-) markedly stimulated pentamidine transport. These data suggest that pentamidine is transported although a pore or ion channel with properties similar to those of the recently characterized 'induced permeability pathway' on the infected red cell membrane. In summary, the diamidines exhibit two levels of selectivity against P. falciparum. The route of entry and molecular target are both specific to malaria-infected cells and are distinct from targets in other protozoa. Drugs that target the hemoglobin degradation pathway of malaria parasites have a proven record of accomplishment. The employment of induced permeability pathways to access this target represents a novel approach to antiparasite chemotherapy and offers an additional level of selectivity.

Transporters in African trypanosomes: role in drug action and resistance

Sleeping sickness is an increasing problem in many parts of sub-Saharan Africa. The problems are compounded by the lack of new medication, and the increasing resistance against traditional drugs such as melarsoprol, berenil and isometamidium. Over the last few years, much progress has been made in understanding how drug action, and the development of resistance, is related to the mechanisms by which the parasite ingests the drugs. In some cases novel transporters have been identified. In other cases, transporters do not appear to be involved in drug uptake, and selectivity must lie with other parasite features, such as a specific target or activation of the drug. Lessons learned from studying the uptake of drugs currently in use may assist the design of a much needed new generation of trypanocides.

A chlorodiazirine analog of pentamidine with anti-trypanosomal activity

A chlorodiazirine derivative of pentamidine was synthesized and tested for anti-trypanosomal activity using EATRO stock 164 trypanosomes in cell culture. Anti-trypanosomal activity was measured as a decrease in [3H]hypoxanthine incorporation by the organisms. The derivative, 3,3'-[1,5-pentanediylbis(oxy-4,1-phenylene)]bis(3-chloro-3H-diazir ine), at a treatment level of 0.1 microM inhibited isotope incorporation by 40-50% compared to nontreated controls. At this concentration, pentamidine inhibited incorporation only 10-15%. The derivative is a nonionic molecule with much different solubility properties than the parent compound and should readily cross the blood-brain barrier.

Physicochemical characteristics of pentamidine-loaded polymethacrylate nanoparticles: implication in the intracellular drug release in Leishmania major infected mice

This work describes the preparation, the physicochemical properties, the tolerance and the intracellular trafficking of pentamidine loaded nanoparticles. Pentamidine was bound to the polymer by ionic interaction. This interaction involved the carboxylic acid functions of methacrylic acid (10% of the polymer) and the amine groups of the drug. Pentamidine fixation and release were pH dependent. An acidic pH led to a decrease of fixation or a release. At pH 5, which is the pH value of lysosomes and parasitophorous vacuoles, the release reached up to 50%. At this pH value, pentamidine is ionized and therefore can not traverse the biological membranes. Unloaded nanoparticles and pentamidine-loaded nanoparticles were tested in vitro on U937 cells and no cytotoxicity was observed. In vivo, in Leishmania infected mice, no significant weight loss was found. Ultrastructural studies showed the different steps of drug loaded nanoparticles trafficking inside Leismania-infected Küpffer cells. The nanoparticle uptake by macrophagic cells led to the location of nanoparticles inside phagocytosis vacuoles which fused with primary lysosomes to form secondary lysosomes. Ultimate fusion of secondary lysosomes containing nanoparticles with parasitophorous vacuoles was also observed. Nanoparticles were identified close to amastigotes but internalization by the parasite was not observed.

Uptake into leishmania donovani promastigotes and antileishmanial action of an organometallic complex derived from pentamidine

Iridium (Ir)-(COD)-pentamidine tetraphenylborate (CAS 225-75-4) was selected from a primary screening to be evaluated in vitro on three Leishmania (L.) strains comparatively to pentamidine used as reference compound. The IC50 values obtained from in vitro evaluation on promastigotes of L. major CRE 26, L. donovani DD8 and L. donovani LV9 were 3.9, 23.5, and 3.3 mumol/l for Ir-(COD)-pentamidine tetraphenylborate and 1.6, 7.7, and 3.9 mumol/l for pentamidine isethionate, respectively. Cytotoxicity on mouse peritoneal macrophages led to determine a chemotherapeutic index of 1.7 for Ir-(COD)-pentamidine tetraphenylborate and 4 for pentamidine. Considering L. donovani DD8, the uptake of iridium complex by the promastigotes was shown to be saturable with a Km value of 17.4 mumol/l and Vmax of 1.3 nmol/mg protein/2 h. After 2 and 4 h incubation of treated promastigotes in drug free medium the absence of Ir-complex efflux is in favour of intracellular drug binding. As a matter of fact iridium complex was shown to bind ribosomal subunits in vitro, with no effect on macromolecular biosynthesis.

Controlled dissolution from wax-coated aerosol particles in canine lungs

Treatment of pulmonary and systemic diseases may be improved and toxicity reduced by pulmonary deposition of drug-containing aerosols exhibiting delayed dissolution. Aqueous disodium fluorescein and pentamidine aerosols were dried, concentrated, and condensation coated with paraffin wax. The apparent mass median aerodynamic diameters of the coated fluorescein particles were 2.8-4.0 microns. Wax-to-fluorescein ratios were 0.38-1.05. The dissolution half times determined using a single-pass flow system were 1.5 min for uncoated fluorescein and 0.8 min for uncoated pentamidine. These increased over threefold when the aerosols were coated with paraffin wax to maxima of 5.3 and 2.6 min, respectively. Wax-coated aerosols generated from fluorescein mixed with 99mTc-labeled iron oxide colloid delivered to the canine lungs demonstrated a 3.4-fold increase in the absorption half time of disodium fluorescein compared with uncoated fluorescein (11.2 vs. 38.4 min). The absence of changes in pulmonary function on inhalation of these wax-coated aerosols, together with a high drug load and delayed release, establishes a foundation for future therapeutic applications.

Disposition of intravenous 123iodopentamidine in man

This study compared the disposition of the radiopharmaceutical [123I]iodopentamidine with that of pentamidine after intravenous infusion by measuring plasma concentrations of each using scintilation counting and high-performance liquid chromatography (HPLC), respectively. There was rapid hepatic uptake and biliary excretion of the 123I label. Distribution kinetics of the 123I label were similar to those of pentamidine, but its elimination half-life (41 +/- 27 h) was longer than that of pentamidine measured by HPLC (11 +/- 8 h). [123I]iodopentamidine distribution reflects that of pentamidine, but elimination of the radiopharmaceutical appears slower.

Trypanocidal effect of Ir-(COD)-pentamidine tetraphenylborate on Trypanosoma brucei and T. b. gambiense rodent models and serum kinetics in sheep

Pentamidine di-(iridium cyclo-octadiene)tetraphenylborate, called Ir-(COD)-pentamidine tetraphenylborate, was selected from a primary screening as a promising trypanocidal compound. The compound was evaluated against three isolates: Trypanosoma brucei brucei CMP, T.b. brucei GVR 35 and T.b. gambiense Feo. On the T.b. brucei GVR 35 murine CNS model, no mouse was cured when the treatment was commenced 21 days post-infection whatever the treatment regimen. Nevertheless, in vitro the compound killed the trypomastigote forms of T. b. gambiense Feo at 0.6 microM. In vivo, the compound cured all mice infected 1 hour previously with T. b. gambiense Feo after a 10 mg/kg (6.3 mumol/kg) treatment subcutaneously administered in a single dose. Moreover, the compound was active at 1 mg/kg (0.6 mumol/kg) in a single dose against the early stage of the T. b. brucei Antat 1-9 sheep model. Serum kinetics data showed that pentamidine di-(iridium cyclo-octadiene) tetraphenylborate was distributed within deep compartment according to a monocompartmental model. The maximum iridium serum concentration was 198 micrograms/l corresponding to 1 mumol/kg of iridium derivative and this value remained stable for 30-50 hours post-treatment. Iridium was completely eliminated from the serum 700 hours post-treatment. all data obtained from these models are in favour of an activity in the early stage of the disease but indicate that the compound could not cross the blood-brain barrier despite its lipophilicity. Although iterative treatments with the compound rapidly induced the selection of iridium derivative refractory populations, the compound could be studied on pentamidine refractory strains.

Pentamidine uptake in Leishmania donovani and Leishmania amazonensis promastigotes and axenic amastigotes

A transport system for pentamidine in Leishmania donovani and Leishmania amazonensis promastigotes and axenic amastigotes has been identified and characterized. Pentamidine is not metabolized by these parasites. Its uptake process is saturable, carrier-mediated and energy-dependent. This drug does not inhibit purine or pyrimidine uptake, whereas it inhibits uptake of several amino acids non-competitively and that of putrescine and spermidine competitively. The results suggest that pentamidine shares polyamine-carrier systems in these parasites.

Pharmacokinetic interaction between intravenous 2',3'-dideoxyinosine and pentamidine in rats

PURPOSE

This study examined the pharmacokinetic interaction between 2',3'-dideoxyinosine (ddI) and pentamidine.

BACKGROUND

ddI and pentamidine are often coadministered to patients with acquired immunodeficiency syndrome, and are both associated with pancreatic toxicity. Information on potential interaction would be useful to assess the need for dose modification and the basis of the higher incidence of pancreatic toxicity associated with coadministration of the two drugs.

METHODS

ddI (200 mg/kg) and pentamidine (10 mg/kg) were administered by continuous infusion to rats over 3 hr, either alone or concomitantly. Drug analysis was by high pressure liquid chromatography with UV or fluorescence detection, or by radioimmunoassay.

RESULTS

Pentamidine coadministration significantly increased the apparent volume of distribution at steady state of ddI from 1.4 to 3.4 l/kg (p = 0.004), and increased the mean residence time from 36.3 to 50.0 min (p = 0.015). Pentamidine enhanced the distribution of ddI from plasma into pancreas (p = 0.001) and muscle (p = 0.026). ddI distribution into spleen and liver was also increased, with differences approaching statistical significance (p = 0.08 and 0.06, respectively). In contrast, ddI coadministration did not affect the total body clearance but increased the urinary excretion and the renal clearance of pentamidine by about 5-fold (p = 0.0003).

CONCLUSIONS

These data indicate that pentamidine increased the distribution of ddI into pancreas and muscle, whereas ddI increased the renal elimination of pentamidine.

Intrapulmonary and systemic pharmacokinetics of aerosolized pentamidine used for prophylaxis of pneumocystis carinii pneumonia in patients infected with the human immunodeficiency virus

A study was conducted to determine the intrapulmonary and systemic pharmacokinetics of aerosolized pentamidine prophylaxis (APP) in patients infected with human immunodeficiency virus (HIV). 151 patients received high-dose (300 mg twice a month or 600 mg once a month) APP as part of a previously published clinical trial, and 29 additional patients received standard-dose (300 mg once a month) APP. Serial blood samples were obtained from the first cohort: 577 samples were obtained from 76 patients in the group given 600 mg once a month, and 554 blood samples were obtained from 75 patients in the group given 300 mg twice a month. In 9 of the 151 patients, bronchoscopy and tri-lobar (right upper, middle, and lower lobe) bronchoalveolar lavage (BAL) were performed 6 and 12 months after initiation of APP. Unilobar (right middle lobe) BAL was performed in the 29 patients infected with HIV who underwent bronchoscopy for diagnostic purposes. Pentamidine was measured using a chromatographic (HPLC) assay. The concentrations (mean +/- SD) of pentamidine in plasma in the groups given 300 mg twice a month and 600 mg once a month were 5.3 +/- 6.1 ng/mL and 8.8 +/- 9.6 ng/mL, respectively, and accumulation did not occur. The BAL supernatant and alveolar cell pentamidine concentrations were not significantly different in the 3 lobes and ranged from 16.5 +/- 7.7 ng/mL to 29.2 +/- 19.5 ng/mL and 1255 +/- 1142 ng/mg protein to 1572 +/- 1161 ng/mg protein in the group given 300 mg twice a month; and from 5.5 +/- 2.9 ng/mL to 9.4 +/- 7.7 ng/mL and 339 +/- 201 ng/mg protein to 571+/- 681 ng/mg protein in the group given 600 mg once a month. The intropulmonary concentrations of pentamidine at 6 and 12 months were not significantly different. In 18 of the 29 patients who received 1 to 7 prior monthly doses of standard APP, drug concentrations in BAL increased linearly (y = 2.05x) with the number of doses administered before bronchoscopy. These data indicate that intrapulmonary drug concentrations continue to increase for approximately 6 months after the initiation of APP, at which time steady state is achieved, and that administration of high dose APP is probably safe.

Pharmacokinetics and adverse reactions after a single dose of pentamidine in patients with Trypanosoma gambiense sleeping sickness

1. Plasma concentrations of pentamidine were measured up to 1-8 months after a single 2 h i.v. infusion of 3.0 to 4.8 mg kg-1 pentamidine isethionate in 11 patients with late stage Trypanosoma gambiense sleeping sickness. 2. Maximum plasma drug concentrations varied between 713 and 2461 nmol 1-1. After termination of infusion, a rapid distribution phase over 10 min was followed by a slower distribution phase and an elimination phase prolonged over weeks to months. 3. The 'terminal' elimination rate constant could be determined in six patients and subsequent kinetic calculations showed a three to fourfold variation in plasma clearance and 'terminal' half-life (median 1126 (range 553-2036) ml min-1 and 265 (107-446) h, respectively). The median apparent volume of distribution (Vss) was 11,850 1. Renal clearance accounted for a median of 11% of total plasma clearance, indicating that metabolism is a major route of pentamidine elimination in man. 4. Side effects were few and mild and a slight or moderate decrease in blood pressure was the most common registered adverse reaction observed in four subjects. 5. The prolonged elimination of pentamidine seems inconsistent with the present recommended dosage regimen of pentamidine for treatment of trypanosomiasis of 7 to 10 parenteral doses given once daily or every second day.

Estimation of fetal risk from aerosolized pentamidine in pregnant healthcare workers

Inhaled pentamidine is used to treat Pneumocystis carinii pneumonia. Its potential effects on DNA have raised concerns about its safety for pregnant healthcare workers. We used a pharmacokinetic approach to estimate the fetal risks, based on the published data of pentamidine renal clearance and of urinary pentamidine concentrations in healthcare workers exposed to aerosolized pentamidine. The maximum pentamidine doses (intravenous equivalent) that healthcare workers were exposed to were calculated to be 9.8 micrograms/kg/d and 1.7 microgram/kg/d at the two different institutions reported. In parallel, based on animal data, we derived the intravenous-equivalent reference doses for embryolethality and for teratogenicity, the doses that can be viewed as tentative safe exposure levels. These analyses reveal that the exposure levels of a healthcare worker to aerosolized pentamidine are estimated to be in the vicinity of the teratogenic reference dose (4 micrograms/kg/d) and greater than the embryolethal reference dose (0.08 microgram/kg/d). Further improvement of the pentamidine administration technique and of environmental management in hospitals is warranted.

N-hydroxylation of the antiprotozoal drug pentamidine catalyzed by rabbit liver cytochrome P-450 2C3 or human liver microsomes, microsomal retroreduction, and further oxidative transformation of the formed amidoximes. Possible relationship to the biological oxidation of arginine to NG-hydroxyarginine, citrulline, and nitric oxide

Previous investigations have shown that the antiprotozoal drug pentamidine is N-hydroxylated by rabbit and rat liver microsomal fractions. Indirect evidence for the participation of the cytochrome P-450 enzyme system was obtained. In this study, rabbit liver cytochrome P-450 2C3 is shown by reconstitution experiments with highly purified variants of P-450 2C3 isolated from rabbit liver and purified variants of P-450 2C3 expressed by recombinant Escherichia coli to be a microsomal pentamidine N-hydroxylase. The two variants, P-450 2C3 (6 beta H) and P-450 2C3 (6 beta L), are equally efficient for the formation of the monoamidoxime derivative of pentamidine. N-hydroxypentamidine is further oxidized to the respective amide by reconstituted rabbit liver P-450 enzyme systems involving the oxidase and peroxidase activities of this enzyme. Formation of nitric oxide [(NO); endothelium-derived relaxing factor] during this oxidation is shown by the detection of the cytochrome P-420-Fe(II)-NO complex by visible difference spectroscopy. The possibility for the N-hydroxylation of pentamidine to the corresponding amidoximes and subsequent oxidative conversion to the respective amide derivatives is comparable with the physiological transformation of arginine to citrulline via N-hydroxyarginine with liberation of NO (endothelium-derived relaxing factor). The N-hydroxylated derivatives of pentamidine are easily retroreduced by microsomal fractions from rabbit liver. NADH is preferred to NADPH as cofactor for this reduction, and the reaction is strongly suppressed by the addition of N-methylylhydroxylamine. The N-hydroxylation of pentamidine and the retroreduction are also catalyzed by human liver microsomes.(ABSTRACT TRUNCATED AT 250 WORDS)

Pulmonary deposition of aerosolised pentamidine using a new nebuliser: efficiency measurements in vitro and in vivo

The therapeutic efficacy of nebulised pentamidine in the prophylaxis of Pneumocystis carinii pneumonia (PCP) depends on the absolute pulmonary deposition of the drug. We studied the performance of a new nebuliser (Pentasave) by comparison both in vitro and in vivo with a standard nebuliser (Respirgard II). In vitro, deposition of pentamidine labelled with technetium-99m human serum albumin was measured indirectly by capturing inhaled particles on an absolute filter and measuring radioactivity with a gamma camera. The nebulisers were initially assessed with a pentamidine dose of 100 mg in 5 ml at 44 psi and an air flow of 10 l/min for Respirgard II and 16 l/min for Pentasave. Nebuliser output, expressed as the percentage of the initial nebuliser radioactivity captured by the inhalation filter, was 15% +/- 2% (mean +/- SD) for Respirgard II, and significantly increased to 23% +/- 3% for an initial version and to 33% +/- 2% for the final version of Pentasave. Measurements with a gamma camera in a group of ten patients with human immunodeficiency virus infection were made in vivo. The results revealed that pulmonary drug distributions are good using both Respirgard II and Pentasave. The literature reports that once-monthly pulmonary deposition of 9 mg pentamidine seems enough to produce prophylactic effects against Pneumocystis carinii. We measured pulmonary pentamidine deposition of 20.22 +/- 4.31 mg (mean +/- SD) using Respirgard II (with 300 mg in 5 ml) and of 16.00 +/- 7.18 mg using Pentasave (with 150 mg in 6 ml). These findings show that the therapeutic dose of pentamidine (9 mg) was widely exceeded with both nebulisers. Further investigations might demonstrate that about 200 mg and 125 mg pentamidine for Respirgard II and Pentasave, respectively, will achieve a pulmonary deposition of therapeutic dose, allowing significant savings in terms of drug and expense.

Plasma pentamidine concentrations vary between individuals with Pneumocystis carinii pneumonia and the drug is actively secreted by the kidney

The multiple-dose pharmacokinetics of pentamidine were studied in six AIDS patients with acute Pneumocystis carinii pneumonia given infusions of pentamidine isethionate 3.7-4 mg/kg/day i.v. Plasma and urine concentrations of pentamidine of repeated samples taken on days 1, 4 and 7 of treatment were assayed by HPLC. Creatinine clearance Clcr was also determined. On day 7, the area under the plasma concentration versus time curve (AUC) varied fourfold (3263 to 12776 nmol.h/L) between individuals. It was lowest in a patient receiving concomitant treatment with carbamazepine, suggesting that this drug may induce the metabolism of pentamidine. On day 7, a mean of 12% of the dose was excreted unchanged in the urine. Clcr was decreased significantly on day 7 compared with day 1 (mean decrease 31%, range 11-63%). Renal clearance of pentamidine (Clr) decreased over time but always exceeded the Clcr, indicating tubular secretion. The decrease of Clr may be explained by capacity-limited secretion and/or a tubulotoxic effect of the drug. The variation of the AUC values is consistent with interindividual differences in rates of metabolism, which supports individual dosing strategies for pentamidine.

The pharmacokinetics of 1,3-di(4-imidazolino-2-methoxyphenoxy) propane.lactate (DMP.lactate), a new agent against opportunistic infections, in male beagle dogs

The pharmacokinetics and oral bioavailability of 1,3-di(4-imidazolino-2-methoxyphenoxy) propane.lactate (DMP) was determined in male dogs following iv and po administrations of DMP.lactate containing trace amounts of [14C]DMP.HCl. Following the iv administration of [14C]DMP.lactate (2.5 mg/kg), plasma concentrations of DMP declined in a biexponential manner and were measurable to 48 hr. The terminal elimination half-life was 37.7 hr. The mean AUC0-infinity of DMP was 1.58 micrograms.hr/ml. The volume of distribution was 89 liters/kg and the body clearance was 27 ml/min/kg. The disposition of total radioactivity was similar to that of DMP. Approximately 14% of the dose was eliminated in urine as DMP or total radioactivity. Renal clearance was 10% of the body clearance. Following the po administration of [14C]DMP.lactate (14 mg/kg) the mean Cmax of total radioactivity and DMP was 0.20 and 0.17 micrograms/ml, respectively. The respective mean AUC0-T was 0.37 and 0.21 micrograms.hr/ml. The mean oral bioavailability based on DMP plasma concentrations was 2.4%. The mean Cmax of DMP following a 100 mg/kg po dose of DMP.lactate was 14 micrograms/ml and the AUC0-T was 1.87 micrograms.ml/hr; the bioavailability was 3.2%. Approximately 1% of the orally administered dose was eliminated in urine as DMP.

Regional deposition and regional ventilation during inhalation of pentamidine

In most patients, the deposition of aerosolized pentamidine (AP) is less in the apex of the lung relative to the base. As the apex of the lung is relatively less ventilated than the base, it is possible that reduced regional ventilation may explain the inhomogeneity in regional drug deposition. The purpose of this study was to measure the relationship between regional deposition of AP and regional ventilation, and the influence of particle size and airway caliber on this relationship. Ten subjects with HIV infection who were receiving prophylaxis with AP were recruited. Using krypton (81mKr), we measured regional ventilation during treatment with AP, labeled with 99mTc. Two nebulizers were used (Respirgard II and Fisoneb) that produced particles of different size. In addition, patients were studied with and without a bronchodilator because changes in airway geometry can affect sites of particle deposition. There was no significant correlation between regional ventilation and regional particle deposition (r = 0.00, linear regression). Particle deposition in the upper lobes relative to the lower lobes was less than would be predicted by regional ventilation, by a ratio of 0.84 +/- 0.03 (mean +/- SE). Using two-way analysis of variance (ANOVA), the upper to lower zone deposition pattern was not affected by either nebulizer or by the use of albuterol. The Fisoneb had significantly more central deposition relative to the jet nebulizer (mean +/- SE, skC/P: Fisoneb 1.3 +/- 0.1, Respirgard 1.1 +/- 0.1, p = 0.005, two-way ANOVA). The use of a bronchodilator did not significantly affect the central/peripheral deposition pattern. We conclude that differences in deposition between upper and lower lung regions are not accounted for simply by differences in regional ventilation in patients undergoing prophylaxis with AP. In assessing the cause of regional inhomogeneities of pharmaceutical aerosol deposition (and in devising strategies to achieve more uniform distribution), regional ventilation should be measured directly rather than be inferred from the deposition pattern of the aerosol.

Pentamidine accumulates in rat liver lysosomes and inhibits phospholipid degradation

The subcellular distribution and the effects of pentamidine on the ultrastructure of the rat liver were studied. Rats were given single or repeated daily intraperitoneal injections of 10, 25 or 50 mg pentamidine isethionate/kg b. wt. for 1, 4, 6, 9 or 16 days. The livers were removed for ultrastructural and biochemical analyses on the day after termination of each series of injections and in addition 7 and 35 days after the 16th injection. Electron microscopy of liver tissues showed that the general cellular architecture of the hepatocytes was preserved. The subcellular organelles were normal, except for the secondary lysosomes, which were severely altered and laden with multilamellar, myelin structures (myelin bodies) that gradually increased with dose and time course following repeated injections. These altered lysosomes were enriched in phospholipids. The alteration of the lysosomes persisted for up to 5 weeks after cessation of administration. Pentamidine was highly enriched in the lysosomal fraction (30-50 times more than in the liver homogenate). It was calculated that the lysosomal pentamidine accounted for practically all pentamidine distributed to the liver. The demonstrated accumulation of pentamidine in the lysosomes may explain the known large volume of distribution of this drug and may be one mechanism for organ toxicity.

High-performance liquid chromatographic determination of pentamidine in plasma

This report describes the analysis of pentamidine by isocratic reversed-phase high-performance liquid chromatography (HPLC) using a commercially available compound (melphalan) as the external standard. Previously described assays use ion-pairing HPLC, an internal standard (hexamidine) that is not readily available, and require a relatively large sample size. In the present assay, pentamidine was extracted from plasma using solid-phase extraction and was analyzed using a C18 column and a mobile phase containing 18% acetonitrile, 2% methanol, 0.2 M ammonium acetate and 0.5% triethylamine. The identity of the eluting peaks was verified using a diode array detector. The extraction yield of pentamidine was 82%. The limit of detection was 8.6 ng/ml with a sample size of 100 microliters. The inter-day and intra-day coefficients of variation ranged between 0.3% and 10% with an average of 5%. This method was applied to study the pharmacokinetics of pentamidine in rodents.

Disposition of a new antiinfective agent 1,3-di(4-imidazolino-2-methoxyphenoxy)propane in male rats

The disposition of 1,3-di[4-imidazolino-2-methoxyphenoxy]propane (DMP) is described in male rats following a single 2.5 mg/kg intravenous or 10 mg/kg oral administration of DMP lactate in an aqueous (5% dextrose) solution. Following the intravenous administration, plasma concentrations of DMP declined in an apparent biexponential manner and were nonmeasurable after 24 hr. The mean terminal plasma elimination half-life was 14.9 hr. A volume of distribution of 18.7 liters/kg and a body clearance of 14.5 ml/min/kg were estimated. After oral administration, mean plasma concentrations of DMP reached a maximum of 39.6 ng/ml at 15 min and were nonmeasurable after 4 hr. The areas under the curve (AUC)0-24 of DMP was 2276 ng.hr/ml following the intravenous dose. The AUC0-4 was 68 ng.hr/ml following the oral dose. The AUC0-4 was 68 ng.hr/ml following the oral dose. Based on a comparison of AUC0-4, the oral bioavailability was 0.9%. A mean of 41.7 and 0.4% of the dose was excreted in urine as DMP following intravenous and oral administration, respectively. The tissue distribution and mass balance of total 14C were determined following a single 2.5 mg/kg intravenous administration of [14C]DMP.lactate. The concentrations of total 14C in all tissues were highest at 0.5 hr and declined with time thereafter. The highest concentration of 14C was in the kidneys, whereas the highest total amount was in the liver.(ABSTRACT TRUNCATED AT 250 WORDS)

Direct isotopic assessment of aerosolized pentamidine deposition: influence of nebuliser

OBJECTIVES

The aim of the present study was to compare the efficiency of pulmonary deposition of pentamidine using the Respirgard II jet nebuliser or the Fison ultrasonic nebuliser with 99m technetium (99m Tc) labelled pentamidine in the current conditions of recommended treatment. The study was designed in three stages, to verify particle size distribution, to validate the isotope labelling, and to compare pulmonary deposition of pentamidine isethionate with the two nebulisers.

METHODS

Count median aerodynamic diameter and mass median aerodynamic diameter were measured using the velocimetry technique and aerosol dispersion was calculated according to the standard deviation defined by the ratio of diameters between 84.3% and 50% of the total distribution. Stability of labelling was checked both in vitro, by radiochromatography, and in vivo, by the absence of free technetium thyroid fixation after intravenous injection of the preparation to a rat and inhalation by baboons. The direct isotopic technique was used to compare pulmonary deposition of 300 mg aerosolized 99m Tc labelled pentamidine isothionate with the two nebulisers in four HIV patients treated with primary prophylaxis.

RESULTS

Count median aerodynamic diameter and mass median aerodynamic diameter (MMAD) were higher with Fisoneb than with Respirgard II. Nevertheless Fisoneb MMAD remained in the optimal range for peripheral deposition. In one patient, pentamidine lung burden was higher using the Respirgard II (13% of dose originally in nebuliser) when compared with the Fisoneb (10.2% of dose originally in nebuliser). A better result was obtained in the 3 other patients with Fisoneb (mean = 14.3%) compared with Respirgard II (mean = 3.8%). In all 4 patients gastric contamination was higher with Fisoneb (mean = 5.2%) as compared with Respirgard II (mean = 2.6%). Cough and bronchospasm were not observed with either device.

CONCLUSION

This study showed that Fisoneb, a practical and cheap nebuliser which has proved to be effective in clinical studies when used for pentamidine nebulisation, leads to correct particle size distribution and pulmonary deposition of the drug. We believe that such studies to evaluate aerosol characteristics should be recommended for any kind of nebuliser.

A randomized comparison of once-monthly or twice-monthly high-dose aerosolized pentamidine prophylaxis

RESULTS

Ten of the 146 (7 percent) evaluable subjects developed PCP during the year study period, and there was no difference in the efficacy of the two regimens. Among patients receiving secondary prophylaxis, the attack rate of PCP at 1 year was 11 percent. This compares favorably with a 1-year attack rate of 19 percent in similar patients receiving standard dose (300 mg) prophylaxis and suggests, but does not prove, a dose-response effect. Concentrations of pentamidine in BAL fluid were not significantly different among the three lobes of the lung. Intrapulmonary pentamidine did not accumulate during the year of study. Aerosolized pentamidine was associated with a marginal but statistically significant increase in the residual volume, decreased flow rates, and increased airway reactivity.

OBJECTIVE

The optimal regimen of aerosolized pentamidine in unknown. Published data suggest that there is a dose-response effect and that the occurrence of Pneumocystis carinii pneumonia (PCP) has been associated with prolongation of the interval between doses. The purpose of this study was to compare the efficacy, pharmacokinetics, and physiologic effects of two high-dose regimens of aerosolized pentamidine prophylaxis.

DESIGN

Prospective, randomized study of 300 mg twice monthly vs 600 mg once monthly during a 1-year observation period. Pentamidine concentrations in plasma and bronchoalveolar lavage (BAL) fluid were measured and serial pulmonary function was measured.

SETTING

A large teaching hospital in San Francisco.

PATIENTS

One hundred fifty-one adult (age > 18 years) men with human immunodeficiency virus infection. Of 146 evaluable patients, prophylaxis was primary (no prior PCP) in 108 (75 percent) and secondary (one prior episode of PCP) in 38 (25 percent).

MEASUREMENTS

Date and diagnosis of PCP, occurrence of drug toxicity, pulmonary function testing, and concentrations of pentamidine in BAL and plasma.

CONCLUSIONS

The data suggest, but do not prove, that a dose-response effect has been demonstrated, and that high-dose aerosolized pentamidine may further reduce the attack rate of PCP. These preliminary observations should be confirmed in a double-blind trial comparing 300 mg with 600 mg administered once monthly. The clinical relevance of the adverse pulmonary effects is unclear and requires further investigation.

Pentamidine, an inhibitor of spinal flexor reflexes in rats, is a potent N-methyl-D-aspartate (NMDA) antagonist in vivo

The present study examined whether the antimicrobial agent pentamidine exerts an antagonistic action at the N-methyl-D-aspartate (NMDA) receptor as tested on spinal reflexes in rats in vivo. After intrathecal injection both the specific NMDA antagonist (-)-2-amino-7-phosphonoheptanoate and pentamidine dose-dependently reduced the magnitude of the polysynaptic flexor reflex without affecting the monosynaptic H-reflex. In contrast, the non-NMDA antagonist 6,7-dinitroquinoxaline-2,3-dione depressed the H-reflex in a dose-dependent manner without affecting the flexor reflex. The depressant effect of pentamidine on the flexor reflex was prevented by coadministration with NMDA but not with the non-NMDA agonist alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid. These data suggest that pentamidine exerts an antagonistic action at the NMDA receptor in vivo.

The accumulation of pentamidine and the toxic effects of the drug, its selected analogues and metabolites on isolated alveolar cells

Radiolabelled [3H]pentamidine is accumulated into 48-h and 7-day cultures of alveolar epithelial type 2 cells and alveolar macrophages in a linear, time and dose-dependent manner, with the rate of uptake being 15.3, 13.4 and 17.9 pmol/micrograms protein per 30 min, respectively. Uptake was not affected by metabolic inhibitors. The differential toxicity of the parent drug pentamidine, five analogues and six metabolites was assessed on freshly isolated and type 2 cells maintained in culture over 24 h. Toxicity, determined by the attachment ability of alkaline phosphatase positive cells containing lamellar bodies was greater in freshly isolated cells. Overall, three/four of the analogues proved less damaging to type 2 cells than the pentamidine with one derivative [1,3-bis(4-amidino-2-methoxy)propane], a compound particularly efficacious against pneumocystis in rats, showing minimal toxicity. Five metabolites (chain hydroxylated derivatives) were less toxic than the parent drug. However, one metabolite (N,N-dihydroxy derivative) was much more toxic than pentamidine to both type 2 cells and alveolar macrophages. It is concluded that as the type 2 cell can accumulate the drug, it represents a target cell which is particularly sensitive to pentamidine and/or some of its metabolites.

Trypanocidal activity and platinum plasma kinetics of cis-Pt pentamidine iodide in Trypanosoma brucei sheep model

The trypanocidal properties of cis-Pt pentamidine iodide have been studied on the T. b. brucei sheep model. The compound was evaluated on the lymphatic-plasma phase of the disease and appeared to be active on the circulating parasites. Cis-Pt pentamidine iodide was active at 5 mgl.kg-1 in one single dose both in mouse and sheep trypanosomiasis models. The chemotherapeutic index was about 200 in the mouse. As we observed previously with the chloride derivative, platinum plasma values for cis-Pt pentamidine iodide were rather constant between 24 and 48 hours. The nature of the salt associated to cis-Pt pentamidine had a direct effect on the compound kinetics. The iodide compound was distributed quickly and largely within deep compartments according to a monocompartmental model. The theoretical volume of distribution was 6.41.kg-1 for a 100% absorbed fraction. The two iodide ions of the complex probably played an important role in the compound kinetics mainly due to the extended release effect. The iodide salt of cis-Pt pentamidine could therefore be used in chemoprophylaxis of African trypanosomiasis.

Disposition of nebulized pentamidine measured using the direct radiolabel 123I-iodopentamidine

The pulmonary deposition of nebulized pentamidine (300 mg, Respirgard II nebulizer) was measured in seven human immunodeficiency virus (HIV)-positive men using a new radiopharmaceutical, 123I-iodopentamidine. Mean total pulmonary deposition was 15.3 mg or 5.1% of the initial nebulizer dose. Further studies in two of the patients showed that at 24 h, 87% of deposited 123I was retained in the lungs. Small amounts of activity (expressed as a percentage of the initial nebulizer activity) were also detected over the thyroid (0.4%), bladder (1%) and gut (0.7%). The ratio of 123I activity to pentamidine concentration was similar in the nebulizer solution and urine. These results suggest that 123I-pentamidine may be sufficiently stable in vivo to be used to study the biodistribution of inhaled and parenteral pentamidine in humans.

Dose-dependent distribution of 3H-pentamidine following intra-tracheal administration to rats

1. The acute toxicity to the lung, and disposition, of pentamidine isethionate as a function of a pulmonary-delivered dose was investigated in the rat. 2. Acute toxicity 24 h following intra-tracheal instillation of pentamidine was determined by analysis of acellular surface protein concentration and differential cell counting of bronchoalveolar lavage fluid. These two parameters indicated that pentamidine doses > 10 mg/kg lead to increasingly severe oedematous and inflammatory responses within the lung. 3. Following intra-tracheal administration of sub-toxic doses of 3H-pentamidine (0.2-10 mg/kg), the extent of activity in liver, kidney, gut and lavage fluid at 24 h correlated significantly with dose, whereas the level of activity in lung was saturated at doses > 0.8 mg/kg. 4. Values of << 1 for liver:lung and kidney:lung ratios of 3H-activity at low pentamidine doses demonstrated the high affinity of the lung for the compound. These ratios substantially increased with pentamidine dose, reflecting distribution of the drug to liver and kidney. Association of radioactivity with these organs was rapid (< 30 min), and indicated that pentamidine is effectively absorbed from the respiratory tract following intra-tracheal instillation.

[Determinants of serum pentamidine concentration in the human]

By means of serial measurements of pentamidine in plasma, urine and feces the significance of biologically available dose, volume of distribution, elimination and dose interval for serum concentration is investigated in patients with AIDS and bone marrow transplantation after inhaled and intravenous application. Aerosolisation of the drug yields to serum concentration mostly below the detection limit (HPLC). In urine only 0.15 to 0.8% of the substance biologically available in the lung are measured as unaltered pentamidine-base. After i.v. infusion the dose dependent low serum concentrations of 30 to 100 ng/ml indicate a fast distribution in peripheral compartments from which a very slow deliberation is seen. The half-life of the drug is also dose dependent and amounts under clinical conditions at minimum four days. The fecal excretion is found to be only one third of that measured in urine. A difference in the kinetic of elimination between bone marrow transplantated and AIDS-patients could not be evaluated. For clinical therapy the most important pharmacokinetic variable seems to be the terminal elimination constant which would implicate a prolongation of the common dose interval.

[Risk factors and prevention of pneumocystis carinii pneumonia after bone marrow transplantation]

For six months after bone marrow transplantation (BMT) there is a risk of 5 to 15% to suffer from interstitial pneumonia due to pneumocystis carinii (PcP). Prophylaxis with trimethoprim/sulfamethoxazol is therefore routinely and successfully applied. However myelotoxicity, allergic reactions, augmentation of the risk of nephrotoxicity with cyclosporine A and noncompliance may be serious problems. Since the prophylaxis of PcP with pentamidine-aerosol proved to be effective in patients with AIDS, we conducted a prospective trial with regular inhalations of pentamidine. The aim of this study was to evaluate the toxicity, safety, practicability and possible resorption of pentamidine when applied as aerosol. The first of 43 patients were treated with 60 mg pentamidine on two days before, at the day of BMT and 14 days after BMT. Starting four weeks after BMT, 300 mg pentamidine were given every four weeks up to six months. After the study, the four 60 mg inhalations were replaced by two 300 mg inhalations before BMT, because this proved to be more convenient for the patients. There was no pneumonia due to pneumocystis carinii. The only noteworthy side effects observed were cough (19.8%), salivation (9.6%) and sore throat (5.7%). In general pentamidine was well tolerated and well accepted by the patients. Pentamidine could only be detected in the serum of 40 to 60% of all patients. In those patients the serum levels were 7.5 to 9 ng/ml and similar to concentrations found in comparable patients with AIDS. We conclude, that pentamidine-aerosol has only minor side effects, is well tolerated and safe and is therefore an attractive alternative for PcP-prophylaxis after BMT.

Influence of Pneumocystis carinii pneumonia on serum and tissue concentrations of pentamidine administered to rats by tracheal injections

Pentamidine isethionate was administered by the tracheal route to control rats and immunodepressed rats with Pneumocystis carinii pneumonia (PCP). The serum concentration of pentamidine base 20 min after the administration was higher in the PCP rats (309 +/- 165 ng/ml) than in the control animals (71 +/- 36 mg/ml; p less than 0.001); 90 min after the injection the proportion of the pentamidine administered was lower in the right lung of the PCP rats (29 +/- 15%) than in the control rats (57 +/- 23%; p = 0.038); the proportion of pentamidine in the left kidney was higher in the PCP rats (14 +/- 4%) than in the control animals (4 +/- 2%; p less than 0.001). Respiratory clearance of 99mTc-DTPA, an index of the permeability of the respiratory epithelium, was higher in the PCP rats (1.84 +/- 0.42 %/min) than in the controls (0.44 +/- 0.11 %/min; p less than 0.001). We conclude that the more rapid diffusion of pentamidine from the alveolar lumen to the pulmonary circulation is explained by the increased alveolocapillary permeability as a result of pneumocystosis.