Evaluation of Gallium Citrate Formulations against a Multidrug-Resistant Strain of Klebsiella pneumoniae in a Murine Wound Model of Infection.

Skin and soft tissue infections (SSTIs) are a common occurrence in health care facilities with a heightened risk for immunocompromised patients. Klebsiella pneumoniae has been increasingly implicated as the bacterial agent responsible for SSTIs, and treatment can be challenging as more strains become multidrug resistant (MDR). Therefore, new treatments are needed to counter this bacterial pathogen. Gallium complexes exhibit antimicrobial activity and are currently being evaluated as potential treatment for bacterial infections. In this study, we tested a topical formulation containing gallium citrate (GaCi) for the treatment of wounds infected with K. pneumoniae. First, the MIC against K. pneumoniae ranged from 0.125 to 2.0 µg/ml GaCi. After this in vitro efficacy was established, two topical formulations with GaCi (0.1% [wt/vol] and 0.3% [wt/vol]) were tested in a murine wound model of MDR K. pneumoniae infection. Gross pathology and histopathology revealed K. pneumoniae-infected wounds appeared to close faster with GaCi treatment and were accompanied by reduced inflammation compared to those of untreated controls. Similarly, quantitative indications of infection remediation, such as reduced weight loss and wound area, suggested that treatment improved outcomes compared to those of untreated controls. Bacterial burdens were measured 1 and 3 days following inoculation, and a 0.5 to 1.5 log reduction of CFU was observed. Lastly, upon scanning electron microscopy analysis, GaCi treatment appeared to prevent biofilm formation on dressings compared to those of untreated controls. These results suggest that with more preclinical testing, a topical application of GaCi may be a promising alternative treatment strategy for K. pneumoniae SSTI.

Modulating Acinetobacter baumannii biofilm development with molecules containing 3,4,5-trimethoxy-N,N',N'-trimethylbenzohydrazide moiety.

In recent years, Acinetobacter baumannii has emerged as a major cause of nosocomial infections, including infections of implanted medical devices. The treatment of infections caused by A. baumannii has been severely hampered due to their frequent resistance to currently available antibiotics, and most importantly the ability of A. baumannii to form biofilms, which plays a significant role in both persistence and antibiotic resistance. The inherent resistance of A. baumannii biofilms to host defenses and antimicrobial agents necessitates the search for novel approaches to deter biofilm formation. Here, we report our findings on nine compounds identified from structure-activity relationship (SAR) studies on an antibiofilm compound LP3134 that was reported earlier by Biofouling2014, 30, 17. Compounds were evaluated for antibiofilm and anti-adherence activities against A. baumannii. The ability of the compounds to prevent biofilm development on urinary catheters was studied. Growth curve experiments indicated that compounds did not affect the planktonic growth of A. baumannii. All compounds inhibited A. baumannii biofilm development as well as impacting early adhesion on abiotic surfaces. Seven compounds were able to deter biofilm development on silicone catheters. Due to the continued rise of emerging multidrug-resistant A. baumannii, results from this study provide foundation for further development of these molecules to treat A. baumannii infections in wounds and medical devices.

Real-time Leishmania genus master mix: a platform compatibility and stability study.

Performing diagnostics and vector-pathogen surveillance in austere environments is challenging. On-site diagnostic/detection mitigates vector-borne disease complications during military or humanitarian deployments to disease endemic locals. The mobile molecular diagnostic platform, Joint Biological Agent Identification and Diagnostic System (JBAIDS; BioFire Diagnostics Inc., Salt Lake City, UT, USA), rapidly identifies biothreat pathogens. Although ideal for remote diagnostics, the platform was validated for specific pathogens of insignificant epidemiological consequence. Recognizing the JBAIDS's remote diagnostic/detection versatility, we tested a Leishmania genus real-time PCR master mix validated for use on the SmartCycler® (Cepheid, Sunnyvale, CA, USA) for concomitant use on the JBAIDS. We evaluated assay sensitivity, precision, and specificity of one or more Leishmania spp. on the JBAIDS and found that the JBAIDS produces superior detection sensitivity and specificity compared to the SmartCycler®. We also examined the storage stability of a bulk lot preparation of the Leishmania genus real-time PCR master mix on the SmartCycler® to ensure that long periods of frozen storage that would translate to a field environment with the JBAIDS were not detrimental to the reagent. We found that the bulk master mix maintains its stability over a 13-month time period. Overall, these studies confirm JBAIDS's versatility and demonstrate a streamlined assay development approach where reagents are compatible with both platforms.

Training initiatives within the AFHSC-Global Emerging Infections Surveillance and Response System: support for IHR (2005).

Training is a key component of building capacity for public health surveillance and response, but has often been difficult to quantify. During fiscal 2009, the Armed Forces Health Surveillance Center, Division of Global Emerging Infections Surveillance and Response System (AFHSC-GEIS) supported 18 partner organizations in conducting 123 training initiatives in 40 countries for 3,130 U.S. military, civilian and host-country personnel. The training assisted with supporting compliance with International Health Regulations, IHR (2005). Training activities in pandemic preparedness, outbreak investigation and response, emerging infectious disease (EID) surveillance and pathogen diagnostic techniques were expanded significantly. By engaging local health and other government officials and civilian institutions, the U.S. military's role as a key stakeholder in global public health has been strengthened and has contributed to EID-related surveillance, research and capacity-building initiatives specified elsewhere in this issue. Public health and emerging infections surveillance training accomplished by AFHSC-GEIS and its Department of Defense (DoD) partners during fiscal 2009 will be tabulated and described.

Malaria and other vector-borne infection surveillance in the U.S. Department of Defense Armed Forces Health Surveillance Center-Global Emerging Infections Surveillance program: review of 2009 accomplishments.

Vector-borne infections (VBI) are defined as infectious diseases transmitted by the bite or mechanical transfer of arthropod vectors. They constitute a significant proportion of the global infectious disease burden. United States (U.S.) Department of Defense (DoD) personnel are especially vulnerable to VBIs due to occupational contact with arthropod vectors, immunological naiveté to previously unencountered pathogens, and limited diagnostic and treatment options available in the austere and unstable environments sometimes associated with military operations. In addition to the risk uniquely encountered by military populations, other factors have driven the worldwide emergence of VBIs. Unprecedented levels of global travel, tourism and trade, and blurred lines of demarcation between zoonotic VBI reservoirs and human populations increase vector exposure. Urban growth in previously undeveloped regions and perturbations in global weather patterns also contribute to the rise of VBIs. The Armed Forces Health Surveillance Center-Global Emerging Infections Surveillance and Response System (AFHSC-GEIS) and its partners at DoD overseas laboratories form a network to better characterize the nature, emergence and growth of VBIs globally. In 2009 the network tested 19,730 specimens from 25 sites for Plasmodium species and malaria drug resistance phenotypes and nearly another 10,000 samples to determine the etiologies of non-Plasmodium species VBIs from regions spanning from Oceania to Africa, South America, and northeast, south and Southeast Asia. This review describes recent VBI-related epidemiological studies conducted by AFHSC-GEIS partner laboratories within the OCONUS DoD laboratory network emphasizing their impact on human populations.

West Nile virus/dengue type 4 virus chimeras that are reduced in neurovirulence and peripheral virulence without loss of immunogenicity or protective efficacy.

A candidate live attenuated vaccine strain was constructed for West Nile virus (WN), a neurotropic flavivirus that has recently emerged in the U.S. Considerable attenuation for mice was achieved by chimerization with dengue virus type 4 (DEN4). The genes for the structural premembrane and envelope proteins of DEN4 present in an infectious cDNA clone were replaced by the corresponding genes of WN strain NY99. Two of 18 cDNA clones of a WN/DEN4 chimera yielded full-length RNA transcripts that were infectious when transfected into susceptible cells. The two infectious clones shared a motif in the transmembrane signal domain located immediately downstream of the NS2B-NS3 protease cleavage site that separates the DEN4 capsid protein and the WN premembrane protein of the chimera. This motif, Asp and Thr at a position 3 and 6 amino acids downstream of the cleavage site, respectively, was not present in the 16 noninfectious cDNA clones. The WN/DEN4 chimera was highly attenuated in mice compared with its WN parent; the chimera was at least 28,500 times less neurovirulent in suckling mice inoculated intracerebrally and at least 10,000 times less virulent in adult mice inoculated intraperitoneally. Nonetheless, the WN/DEN4 chimera and a deletion mutant derived from it were immunogenic and provided complete protection against lethal WN challenge. These observations provide the basis for pursuing the development of a live attenuated WN vaccine.