Anthony L. Newsome

Use of Polymerase Chain Reaction to Diagnose the Fifth Reported US Case of Autochthonous Transmission of Trypanosoma cruzi, in Tennessee, 1998

In July 1998, the mother of an 18-month-old boy in rural Tennessee found a triatomine bug in his crib, which she saved because it resembled a bug shown on a television program about insects that prey on mammals. The gut contents of the Triatoma sanguisuga were found, by light microscopy and polymerase chain reaction (PCR), to be infected with Trypanosoma cruzi; PCR products hybridized with T. cruzi-specific oligonucleotide probes. Whole-blood specimens obtained from the child in July and August were negative by buffy-coat examination and hemoculture but positive by PCR and DNA hybridization, suggesting that he had low-level parasitemia. Specimens obtained after treatment with benznidazole were negative. He did not develop anti-T. cruzi antibody; 19 relatives and neighbors also were seronegative. Two of 3 raccoons trapped in the vicinity had positive hemocultures for T. cruzi. The childs case of T. cruzi infection-the fifth reported US autochthonous case-would have been missed without his mothers attentiveness and the availability of sensitive molecular techniques.

Disinfection of football protective equipment using chlorine dioxide produced by the ICA TriNova system.

BackroundCommunity-associated methicillin-resistant Staphylococcus aureus outbreaks have occurred in individuals engaged in athletic activities such as wrestling and football. Potential disease reduction interventions include the reduction or elimination of bacteria on common use items such as equipment. Chlorine dioxide has a long history of use as a disinfectant. The purpose of this investigation was to evaluate the ability of novel portable chlorine dioxide generation devices to eliminate bacteria contamination of helmets and pads used by individuals engaged in football.MethodsIn field studies, the number of bacteria associated with heavily used football helmets and shoulder pads was determined before and after overnight treatment with chlorine dioxide gas. Bacteria were recovered using cotton swabs and plated onto trypticase soy agar plates. In laboratory studies, Staphylococcus aureus was applied directly to pads. The penetration of bacteria into the pads was determined by inoculating agar plates with portions of the pads taken from the different layers of padding. The ability to eliminate bacteria on the pad surface and underlying foam layers after treatment with chlorine dioxide was also determined.ResultsRates of recovery of bacteria after treatment clearly demonstrated that chlorine dioxide significantly (p < 0.001) reduce and eliminated bacteria found on the surface of pads. For example, the soft surface of shoulder pads from a university averaged 2.7 × 103 recoverable bacteria colonies before chlorine dioxide treatment and 1.3 × 102 recoverable colonies after treatment. In addition, the gas was capable of penetrating the mesh surface layer and killing bacteria in the underlying foam pad layers. Here, 7 × 103 to 4.5 × 103 laboratory applied S. aureus colonies were recovered from underlying layers before treatment and 0 colonies were present after treatment. Both naturally occurring bacteria and S. aureus were susceptible to the treatment process.ConclusionResults of this study have shown that chlorine dioxide can easily and safely be used to eliminate bacteria contamination of protective pads used by football players. This could serve to reduce exposure to potential pathogens such as the methicillin-resistant Staphylococcus aureus among this group of individuals.

The potential of in situ hybridization and an immunogold assay to identify Legionella associations with other microorganisms

Based on in vitro studies, bacteria in the genus Legionella are believed to multiply within protozoa such as amoebae in aquatic environments. Current methods used for detection of Legionella species, however, are not designed to show this relationship. Thus the natural intimate association of Legionella with other microorganisms remains to be clearly documented and the extent to which protozoa might be infected with Legionella species remains undefined. In this report we describe methods based on the use of Legionella specific reagents that would prove useful in describing its associations with other microorganisms. An immunogold and in situ hybridization technique have the potential to demonstrate the natural occurrence of Legionella species in free-living amoebae. In preliminary observations, however, bacteria reactive with Legionella specific reagents were often not intimately associated with amoebae. Bacteria occurred as free single cells, as cell aggregates, in proximity to other cells and debris, and only occasionally in close proximity to amoebae. Although some Legionella species replicate within amoebae, these preliminary observations suggest the bacteria may be encountered most frequently as extracellular microorganisms, either free-floating or in association with other structures or microorganisms. The future use of these techniques will aid in the elucidation of any naturally occurring relationships between Legionella species and other microorganisms.