Samuel Z. Wilson

Amantadine and ribavirin aerosol treatment of influenza A and B infection in mice.

Ribavirin, amantadine, and the two drugs in combination given in small-particle aerosol were highly effective in the treatment of influenza A infection in mice. Treatment was started 72, 96, and 120 h after inoculation and was given continuously for 4 days. With increasing delay in start of treatment, there was a pronounced reduction in effectiveness of ribavirin but not in that of amantadine. The combination treatment reflected the loss of ribavirin activity. Leukocyte infiltration and virus titers in the lungs were inversely related to the effectiveness of treatment. Influenza B infection treated 72 h after inoculation responded only to ribavirin, as indicated by the criteria described for influenza A. Intraperitoneal administration of drug begun 72 h after inoculation in regimens equivalent to aerosol afforded less protection than aerosol treatment.

Ribavirin small-particle aerosol treatment of infections caused by influenza virus strains A/Victoria/7/83 (H1N1) and B/Texas/1/84.

In a double-blind study of influenza in a population of college students in 1984, ribavirin small-particle aerosol treatment of 38 patients (18 treated, 20 control) infected with a new antigenic variant, influenza virus strain A/Victoria/7/83 (H1N1), was associated with statistically significant reductions in the height and duration of fever, systemic symptoms, and virus shedding. Patients received a total of 2.4 g of ribavirin over 42 h during 68 h of hospitalization without any side effects. In addition, in a study of patients infected with influenza virus strain B/Texas/1/84 (seven treated, eight control) treated with ribavirin aerosol showed a trend of more rapid recovery than control patients.

Small particle aerosols of enviroxime-containing liposomes

Enviroxime inhibits the replication of all rhinoviruses tested in vitro at very low concentrations (10-100 ng/ml), but evaluations in humans have not consistently shown efficacy. Lack of an appropriate method for administering this water-insoluble drug may have contributed to the latter result. The present report describes the characteristics and utilization of small particle aerosols to continuously deliver enviroxime-containing liposomes (LE) throughout the respiratory tract. The enviroxime content of liposomes and biological fluids of exposed individuals was quantified by high performance liquid chromatography using C18 resin, a mobile phase of 60:40 acetonitrile:water, and monitoring at 215 nm. Small particle aerosols of LE generated by Puritan-Bennett nebulizers had mass median diameters ranging from 2.4 to 3.1 microns. The concentration of enviroxime in aerosol particles was proportional to the reservoir concentration; during the first hour of operation, the mean concentration was 20 micrograms of enviroxime/l of aerosol. Liposome particles in the reservoir, although initially heterogeneous in size (less than 0.1 to greater than 1 micron), were processed by passage through the nebulizer to smaller, more homogeneous particles; the majority were less than 0.2 micron. In a preliminary study to evaluate short term tolerance and toxicity, five volunteers were exposed to small particle aerosol of LE for 1 h. At 1 h post-treatment, large amounts of enviroxime were still present in the nasal wash as determined both by HPLC and biological assay. Enviroxime was not detected in any urine sample and was detected in only 1 of 5 serum samples. No side effects were noted. This data suggest that liposome aerosols offer a method for the delivery of hydrophobic compounds for the treatment of respiratory diseases.

Treatment of influenza A (H1N1) virus infection with ribavirin aerosol.

In a randomized, controlled study of ribavirin aerosol treatment of influenza A(H1N1) virus infection among college students, treated patients had a significantly shorter duration of fever than control patients. There was a trend of more rapid recovery in treated patients. Virus shedding was similar in treated and control patients, declining gradually from a 50% tissue culture infective dose of 3.5 log10 per ml at admission to 1.8 log10 per ml at 53 h after admission. There was no local or systemic intolerance and no hematological or biochemical abnormalities associated with ribavirin treatment.

High-dose, short-duration ribavirin aerosol therapy in children with suspected respiratory syncytial virus infection

Nine children (aged 6 weeks to 7 years) with suspected respiratory syncytial virus infection received aerosal treatment with ribavirin, 60 mg/ml for 2-hour periods three times daily for up to 5 days. Five children received treatment via an endotracheal tube and four via an oxygen hood. Blood samples (3 to 17 per patient) and respiratory secretions (4 to 23 per patient) were assayed for ribavirin with reverse-phase high-performance liquid chromatography. Ribavirin triphosphate in erythrocytes was determined by ion-exchange high-performance liquid chromatography. The mean (+/- SD) peak ribavirin level after the first dose was 1725 +/- 2179 mumol/L in secretions and 3.8 +/- 2.6 mumol/L in plasma. Ribavirin in the secretions was rapidly cleared, with a mean (+/- SD), half-life of 1.9 +/- 0.8 hours. Plasma ribavirin increased with treatments to reach a steady state of 5 to 10 mumol/L. Mean peak ribavirin triphosphate levels were 15- to 300-fold higher than plasma ribavirin levels by the end of therapy. More than 98% reduction of viral load without the emergence of resistant virus was noted on day 3 of therapy. High-dose treatment was compatible with the aerosol equipment routinely used (small-particle aerosol generator, model 2-6000) for ribavirin administration and with ventilators. High-dose, short-duration ribavirin therapy was well tolerated by all patients, permitted easier accessibility for patient care, and may result in less environmental exposure of health care workers.

Efficacy of high dose-short duration ribavirin aerosol in the treatment of respiratory syncytial virus infected cotton rats and influenza B virus infected mice

Fifteen to 20 mg/ml ribavirin administered as a small particle aerosol for 10-18 h per day is currently the regimen generally used to treat experimental or naturally-occurring respiratory syncytial (RS) or influenza virus infections in humans. To determine if such prolonged treatment schedules could be reduced, cotton rats and mice were inoculated with RS or influenza B virus, respectively, and then treated with different concentrations of ribavirin small particle aerosols. Aerosols generated from reservoirs containing 60 mg/ml ribavirin given 2 h twice daily, protected cotton rats from RS virus and mice from influenza B virus as well as aerosols generated from reservoirs containing 20 mg/ml ribavirin given 11 h daily. Aerosols generated from reservoirs containing 40 or 20 mg/ml given 2 h daily were less efficacious. There was no evidence of intolerance or pulmonary histopathology in infected or uninfected animals exposed to any of the doses of ribavirin tested. These studies indicate that use of aerosols containing higher concentrations of ribavirin than generally used to treat respiratory virus diseases may permit significantly shorter treatment schedules without loss of efficacy or increase in toxicity.

Activity against rhinoviruses, toxicity, and delivery in aerosol of enviroxime in liposomes.

Enviroxime has been shown to inhibit the replication of rhinoviruses and other enteroviruses in concentrations as low as nanograms per milliliter in in vitro assays but is markedly less effective in clinical trials. The marked hydrophobicity and water insolubility of this compound may be a factor for this disparity. To overcome this handicap, we incorporated enviroxime into liposomes and then tested the antirhinovirus activity and toxicity of the liposome-incorporated enviroxime (LE) in cell culture and studied its administration by small-particle aerosol. Free enviroxime and LE were found to have equivalent efficacies against rhinovirus strains 1A and 13 in in vitro assays; however, preparations of LE were 10- to greater than or equal to 50-fold less toxic to tissue culture cells than was free enviroxime. In contrast to free enviroxime, which could not be delivered by small-particle aerosol because of its water insolubility, LE (4 mg/ml) was readily and successfully delivered by small-particle aerosol to the upper and lower respiratory tracts of mice; after just 20 min, significant levels of enviroxime were detected in the lungs and noses of exposed mice. Moreover, mice exposed to aerosols of liposomes containing both enviroxime and fluorescein isothiophosphatidylethanolamine showed accumulations of the fluorescent marker in the lungs, particularly in or around the tall columnar epithelial cells lining the bronchi and bronchioles. Images

Aerosolized liposomal amphotericin B for treatment of pulmonary and systemic Cryptococcus neoformans infections in mice.

Cryptococcus infections of the lung and central nervous system have become major problems in immuno-compromised patients, leading to the need for additional treatment protocols. We have utilized a Cryptococcus-mouse model that mimics human cryptococcal disease to evaluate the efficacy of amphotericin B-liposomes (AmpB-Lip) when delivered by small-particle aerosol (SPA). In the model, initial intranasal inoculation leads to a pulmonary infection that spreads after 2 to 3 weeks to distant organs, including the brain. Aerosols of AmpB-Lip that were generated by a Collison nebulizer had mass median aerodynamic diameters of 1.8 microns and contained 10.3 micrograms of AmpB per liter. When AmpB-Lip SPA was begun at 24 h postinoculation, a single 2-h treatment (0.3 mg of AmpB per kg of body weight) was effective in reducing pulmonary Cryptococcus infection. This regimen was more effective than intravenous administration of AmpB-Lip given for 3 continuous days. This single 2-h exposure to AmpB-Lip also was effective in reducing pulmonary Cryptococcus infection when treatment was delayed for 7 or 14 days. At day 21, when organisms had spread to the brain in all animals, the single 2-h aerosol treatment reduced the number of cryptococci in the brain as well as in the lungs. AmpB-Lip SPA administered once for 2 h on days 7, 14, and 21 also was effective in increasing the duration of survival of infected animals. These results demonstrate that aerosolized AmpB-Lip can be effective in treating both local, pulmonary Cryptococcus disease and systemic disease.

Protection of mice from lethal influenza virus infection with high dose-short duration ribavirin aerosol.

An aerosol generated from a reservoir containing 60 mg of ribavirin per ml given for 2 h twice daily for 4 days afforded the same high level of protection against lethal influenza virus infection of mice as a longer, conventional treatment schedule (20 mg/ml given for 11 h daily for 4 days). Incremental decreases in ribavirin concentration made while maintaining the 2-h intermittent schedule provided progressively less protection of mice. Mice exposed to the 60-mg/ml doses had significantly increased pulmonary and serum drug levels when compared with mice given 20 mg of drug per ml, these increases were transient, and no evidence of pulmonary intolerance was detected. These studies suggest that protective effects of ribavirin against influenza virus infection can be achieved without untoward effects if higher doses and shorter periods of administration are used.

Aerosol and intraperitoneal administration of ribavirin and ribavirin triacetate: pharmacokinetics and protection of mice against intracerebral infection with influenza A/WSN virus.

Ribavirin is active in vitro but not in vivo against a number of viruses capable of causing encephalitis. Ribavirin triacetate (RTA), a lipophilic derivative, has been reported to be more effective than ribavirin in protecting animals from encephalitis. By using an influenza A/WSN virus encephalitis model, we demonstrated that RTA administered by small-particle aerosol was able to decrease the death rate and increase the time of survival. To determine if this beneficial effect was due to increased delivery of drug, the pharmacokinetic properties of ribavirin and RTA when administered as an aerosol or by intraperitoneal injection were examined. Aerosol administration of ribavirin or RTA gave significantly higher concentrations of ribavirin in the lungs and serum of mice than did intraperitoneal injection. There was no difference, however, in ribavirin levels when either ribavirin or RTA was administered by small-particle aerosol. In brain tissue, ribavirin concentrations increased with time and did not appear to decrease as rapidly as in lungs and serum. Mean peak ribavirin concentrations in the brain were higher following aerosol administration of ribavirin than RTA, and both were higher than that following intraperitoneal injection of either drug. Administration of ribavirin or RTA by intraperitoneal injection failed to protect mice from a lethal intracerebral inoculation of influenza A/WSN virus, while aerosolized RTA did protect mice. The pharmacokinetics of ribavirin in brain tissue following aerosol administration of either drug did not explain the advantage of RTA over ribavirin in protecting mice from intracerebral infection with influenza A/WSN virus.