Investigation of a combination therapy approach for the treatment of melioidosis.

The efficacy of finafloxacin as a component of a layered defense treatment regimen was determined in vitro and in vivo against an infection with Burkholderia pseudomallei. Doxycycline was down-selected from a panel of antibiotics evaluated in vitro and used in combination with finafloxacin in a Balb/c mouse model of inhalational melioidosis. When treatment was initiated at 24 h post-infection with B. pseudomallei, there were no differences in the level of protection offered by finafloxacin or doxycycline (as monotherapies) when compared to the combination therapy. There was evidence for improved bacterial control in the groups treated with finafloxacin (as monotherapies or in combination with doxycycline) when compared to mice treated with doxycycline. Survival comparisons of finafloxacin and doxycycline (as monotherapies) or in combination initiated at 36 h post-infection indicated that finafloxacin was superior to doxycycline. Doxycycline was also unable to control the levels of bacteria within tissues to the extent that doxycycline and finafloxacin used in combination or finafloxacin (as a sole therapy) could. In summary, finafloxacin is a promising therapy for use in the event of exposure to B. pseudomallei.

Finafloxacin, a Novel Fluoroquinolone, Reduces the Clinical Signs of Infection and Pathology in a Mouse Model of Q Fever.

Finafloxacin is a novel fluoroquinolone with optimal antibacterial activity in low pH environments, therefore offering a therapeutic advantage over some traditional antibiotics, in treating bacterial infections associated with acidic foci. Coxiella burnetii, the causative agent of Q fever, is a bacterium which resides and replicates in acidic intracellular parasitic vacuoles. The efficacy of finafloxacin was evaluated in vivo using the A/J mouse model of inhalational Q fever and was compared to doxycycline, the standard treatment for this infection and ciprofloxacin, a comparator fluoroquinolone. Finafloxacin reduced the severity of the clinical signs of infection and weight loss associated with Q fever, but did not reduce the level of bacterial colonization in tissues compared to doxycycline or ciprofloxacin. However, histopathological analysis suggested that treatment with finafloxacin reduced tissue damage associated with C. burnetii infection. In addition, we report for the first time, the use of viable counts on axenic media to evaluate antibiotic efficacy in vivo.

Butyrylcholinesterase, a stereospecific in vivo bioscavenger against nerve agent intoxication.

Human butyrylcholinesterase (E.C. 3.1.1.8) purified from blood plasma has previously been shown to provide protection against up to five and a half times the median lethal dose of an organophosphorus nerve agent in several animal models. In this study the stoichiometric nature of the protection afforded by human butyrylcholinesterase against organophosphorus nerve agents was investigated in guinea pigs. Animals were administered human butyrylcholinesterase (26.15 mg/kg ≡ 308 nmol/kg) by the intravascular or intramuscular route. Animals were subsequently dosed with either soman or VX in accordance with a stage-wise adaptive dose design to estimate the modified median lethal dose in treated animals. Human butyrylcholinesterase (308 nmol/kg) increased the median lethal dose of soman from 154 nmol/kg to 770 nmol/kg. Comparing the molar ratio of agent molecules to enzyme active sites yielded a stoichiometric protective ratio of 2:1 for soman, likely related to the similar stereoselectivity the enzyme has compared to the toxic target, acetylcholinesterase. In contrast, human butyrylcholinesterase (308 nmol/kg) increased the median lethal dose of VX from 30 nmol/kg to 312 nmol/kg, resulting in a stoichiometric protective ratio of only 1:1, suggesting a lack of stereoselectivity for this agent.

Inhaled Liposomal Ciprofloxacin Protects against a Lethal Infection in a Murine Model of Pneumonic Plague.

Inhalation of Yersinia pestis can lead to pneumonic plague, which without treatment is inevitably fatal. Two novel formulations of liposome-encapsulated ciprofloxacin, 'ciprofloxacin for inhalation' (CFI, Lipoquin®) and 'dual release ciprofloxacin for inhalation' (DRCFI, Pulmaquin®) containing CFI and ciprofloxacin solution, are in development. These were evaluated as potential therapies for infection with Y. pestis. In a murine model of pneumonic plague, human-like doses of aerosolized CFI, aerosolized DRCFI or intraperitoneal (i.p.) ciprofloxacin were administered at 24 h (representing prophylaxis) or 42 h (representing treatment) post-challenge. All three therapies provided a high level of protection when administered 24 h post-challenge. A single dose of CFI, but not DRCFI, significantly improved survival compared to a single dose of ciprofloxacin. Furthermore, single doses of CFI and DRCFI reduced bacterial burden in lungs and spleens to below the detectable limit at 60 h post-challenge. When therapy was delayed until 42 h post-challenge, a single dose of CFI or DRCFI offered minimal protection. However, single doses of CFI or DRCFI were able to significantly reduce the bacterial burden in the spleen compared to empty liposomes. A three-day treatment regimen of ciprofloxacin, CFI, or DRCFI resulted in high levels of protection (90-100% survival). This study suggests that CFI and DRCFI may be useful therapies for Y. pestis infection, both as prophylaxis and for the treatment of plague.

The potential role of bioscavenger in the medical management of nerve-agent poisoned casualties.

The provision of effective Medical Countermeasures (MedCM) for all agents and routes of exposure is a strategic goal of defence research and development. In the case of military autoinjector-based therapies for nerve agent poisoning, current treatment effectiveness is limited by the oxime reactivator being effective against only certain agents, by rapid clearance times of the drugs and because the doses may not be optimal for treatment of severe poisoning. Prolonged poisoning by nerve agents entering the body through the skin is also challenging. Since casualty handling timelines have reduced significantly in recent years, it may be sufficient for first aid therapy to provide protection for only a few hours until further medical treatment is available. Therefore, the traditional evaluation of first aid therapy in animal models of survival at 24 h may not be appropriate. At various echelons of medical care, further therapeutic interventions are possible. The current basis for the medical management of nerve-agent poisoned casualties is derived mainly from clinical experience with pesticide poisoning. Adjunct therapy with a bioscavenger (such as human butyrylcholinesterase (huBChE)), could have utility as a delayed intervention by reducing the toxic load. It has previously been demonstrated that huBChE is an effective post-exposure therapy against percutaneous VX poisoning. It is recommended that the scope of animal models of nerve agent MedCM are extended to cover evaluation of both first aid MedCM over significantly reduced timescales, and subsequent supportive therapeutic and medical management strategies over longer timescales. In addition to bioscavengers, these strategies could include repeated combined and individual therapy drugs to alleviate symptoms, other classes of drugs or ventilatory support. Crown Copyright © [2016] Published by Elsevier Ireland Ltd. This is an open access article under the Open Government Licence (OGL) (http://www.nationalarchives.gov.uk/doc/open-government-licence/version/3/).

Liposome encapsulation of ciprofloxacin improves protection against highly virulent Francisella tularensis strain Schu S4.

Liposome-encapsulated ciprofloxacin for inhalation (CFI) was investigated as a putative postexposure therapeutic for two strains of Francisella tularensis. The efficacies of oral ciprofloxacin and intranasally instilled CFI could not be distinguished in a mouse model of infection with the F. tularensis live vaccine strain (LVS), where a single dose of either formulation offered full protection against a lethal challenge. However, mouse studies with the more virulent Schu S4 strain of F. tularensis demonstrated that a higher level of protection against a lethal aerosol infection is provided by CFI than by oral ciprofloxacin. In addition, using this infection model, it was possible to discriminate the efficacy of intranasally instilled CFI from that of aerosolized CFI, with aerosolized CFI providing full protection after just a single dose. The improved efficacy of CFI compared to oral ciprofloxacin is likely due to the high sustained concentrations of ciprofloxacin in the lung. In summary, CFI may be a promising therapy, perhaps enabling the prophylactic regimen to be shortened, for use in the event of a deliberate release of F. tularensis. The prophylactic efficacy of CFI against other biological warfare (BW) threat agents also warrants investigation.

Trimethoprim/sulfamethoxazole (co-trimoxazole) prophylaxis is effective against acute murine inhalational melioidosis and glanders.

Burkholderia pseudomallei is the causative agent of the disease melioidosis, which is prevalent in tropical countries and is intractable to a number of antibiotics. In this study, the antibiotic co-trimoxazole (trimethoprim/sulfamethoxazole) was assessed for the post-exposure prophylaxis of experimental infection in mice with B. pseudomallei and its close phylogenetic relative Burkholderia mallei, the causative agent of glanders. Co-trimoxazole was effective against an inhalational infection with B. pseudomallei or B. mallei. However, oral co-trimoxazole delivered twice daily did not eradicate infection when administered from 6h post exposure for 14 days or 21 days, since infected and antibiotic-treated mice succumbed to infection following relapse or immunosuppression. These data highlight the utility of co-trimoxazole for prophylaxis both of B. pseudomallei and B. mallei and the need for new approaches for the treatment of persistent bacterial infection.

Galleria mellonella as a model system to test the pharmacokinetics and efficacy of antibiotics against Burkholderia pseudomallei.

Mammalian models of infection are paramount to elucidating the mechanisms of bacterial pathogenesis and are also used for evaluating the efficacy of novel antimicrobials before the commencement of human trials. In this study, Galleria mellonella was used to determine the efficacy of antibiotics towards a Burkholderia thailandensis infection in G. mellonella larvae. Kanamycin, imipenem, ceftazidime, doxycycline and ciprofloxacin could all provide some protection when given 1 h before challenge with B. thailandensis; however, at 2 h or 6 h post challenge, imipenem and kanamycin were unable to rescue larvae. The most effective antibiotic for the prevention or treatment of disease was ceftazidime. Pharmacokinetic properties of a single dose of these antibiotics in G. mellonella larvae were also determined, and it was demonstrated that this model is useful for approximating the antibiotic response in humans. The G. mellonella model was used to screen a panel of novel antimicrobials for activity towards B. thailandensis and Burkholderia pseudomallei, and three novel compounds with antibiotic activity were identified. These results support the hypothesis that G. mellonella can be used to screen antimicrobial efficacy. This is the first study to determine the pharmacokinetic parameters of clinically relevant antibiotics in this model system.

Human plasma-derived BuChE as a stoichiometric bioscavenger for treatment of nerve agent poisoning.

Potent organophosphorous (OP) agents, such as VX, are hazardous by absorption through the skin and are resistant to conventional pharmacological antidotal treatments. The residence time of a stoichiometric bioscavenger, human butyrylcholinesterase (huBuChE), in the plasma more closely matches that of VX than do the residence times of conventional therapy drugs (oxime, anti-muscarinic, anticonvulsant). Intramuscular (i.m.) huBuChE afforded almost complete protection when administered prior to the onset of observable cholinergic signs of VX poisoning, but once signs of poisoning became evident the efficacy of i.m. huBuChE decreased. A combination of nerve agent therapy drugs (oxime, anti-muscarinic, anticonvulsant) with huBuChE (i.m.) protected 100% (8/8) of guinea-pigs from a lethal dose of VX (0.74 mg/kg) to 48 h, even when administered on signs of poisoning. Survival was presumed to be due to immediate alleviation of the cholinergic crisis by the conventional pharmacological treatment drugs, in conjunction with bioscavenger that prevented further absorbed agent reaching the AChE targets. Evidence to support this proposed mechanism of action was obtained from PKPD experiments in which multiple blood samples and microdialysate samples were collected from individual conscious ambulatory animals. Plasma concentrations of intramuscularly-administered atropine, diazepam and HI-6 reached a peak within 15 min and were eliminated rapidly within 4h. Plasma concentrations of huBuChE administered by the i.m. route took approximately 24h to reach a peak, but were well-maintained over the subsequent 7days. Thus, the pharmacological therapy rapidly treated the initial signs of poisoning, whilst the bioscavenger provided prolonged protection by neutralising further nerve agent entering the bloodstream and preventing it from reaching the target organs.

VX Penetration Following Percutaneous Poisoning: A Dermal Microdialysis Study in the Guinea Pig.

ABSTRACT VX, a potent organophosphorus compound, acts primarily by irreversibly inhibiting acetylcholinesterase resulting in an accumulation of acetylcholine, which produces the characteristic signs of nerve agent poisoning. VX is a low-volatility agent, and therefore the most likely route of absorption into the body is via the skin. This study demonstrates for the first time that it is possible to follow the time course of percutaneous VX penetration using the technique of dermal microdialysis and that VX is absorbed through the skin of the anesthetized guinea pig in a concentration-dependent manner. A linear microdialysis probe (5-kDa cut-off) was implanted in the dermis of the back of the guinea pig and perfused (5 muL/min) with physiological Ringer's solution. VX (296 or 592 mug/kg) was applied (33 muL/kg) over the site of the microdialysis probe and dialysate samples collected for up to 6 h. The VX dialysate concentration was measured by liquid chromatography-tandem mass spectrometry (LC-MS-MS). Quantitation was performed over the range 0.1 to 100 ng/mL and the calibration was linear. VX was detected within 15 min, reaching a peak at 30 min following both VX doses. After this time the VX concentration decreased. There was a clear dose-dependent recovery of VX in the dialysate and the total amount recovered was statistically significant between the two doses. This study has clearly shown that microdialysis can be used to follow the time course of the percutaneous absorption of VX in the anesthetized guinea pig and will be used in future studies to develop improved medical countermeasures. Crown Copyright (c) 2007 Dstl.