Postoperative Wound Infection Clinical Trial
Official title:
Rapid Identification of Key Pathogens in Wound Infection by Molecular Means
The military is subject to traumatic wounds of various types and severity. Such wounds are
predisposed to infection because they 1) tend to be extensive and deep, 2) may affect areas
of normal carriage of potentially pathogenic bacteria in the gastrointestinal tract, upper
respiratory tract, and the female genital tract, 3) typically produce tissue damage, 4) may
introduce foreign bodies, 5) may interfere with local blood supply, 6) tend to produce
ischemia, edema and hemorrhage, 7) may be complicated by fractures or burns and 8) may lead
to shock and overwhelming of the body's systemic defenses. It will not always be possible in
the military setting to cleanse and debride the wound promptly and effectively or to
promptly provide surgery in the event of damage to vital structures. In the active military
setting, the probability of wound infection following trauma is relatively high. In the
absence of rapid identification of infecting flora and provision of information on
antimicrobial susceptibility, clinicians must resort to empiric therapy rather than a
tailored therapy. There is a tendency to use one of the top available agents that would
likely be active against the vast majority of bacteria. This leads to increases in
antimicrobial resistance, an important problem.
The investigators hypothesize that the use of molecular biology techniques will provide
identification of the microorganisms responsible for wound infection more rapidly and
accurately. The investigators will evaluate real-time PCR (polymerase chain reaction)
technique under this proposal. This procedure can be applied directly to material from the
wound without need for first growing the organisms. It can be used to define the total flora
of the wound within five hours. The investigators will first develop primers and probes that
will detect the various bacteria anticipated in a given wound in a certain location. These
primers and probes will be used in real-time PCR for rapid and accurate identification of
the wound flora. The information obtained with real-time PCR is quantitative so that one may
judge the relative importance of different isolates. The investigators will also use another
molecular approach, 16S rRNA gene cloning, and conventional cultures; these will provide
further information about the flora of various wounds. Definitive identification of
anaerobes can be provided quickly and that, along with information on usual antimicrobial
susceptibility patterns, can be life-saving or shorten the course of the infection
considerably.
Background: Wound infections are typically mixed, with both anaerobic and non-anaerobic
bacteria present and there are usually more anaerobes than aerobes (for example, in
perforated or gangrenous appendicitis, we have found an average of 9 anaerobes and 3
aerobes). Many clinical laboratories do limited anaerobic bacteriology, using commercial
kits based on inadequate phenotypic characteristics and inaccurate taxonomy. As a result,
physicians and surgeons must treat wound infections empirically and tend to use drugs active
against the most resistant anaerobes which leads to increased resistance to antimicrobials.
Molecular techniques now available permit accurate and rapid characterization of
microorganisms, both aerobic and anaerobic.
Objective/Hypothesis: The use of molecular biology techniques will provide identification of
the microorganisms responsible for wound infection both more rapidly and more accurately.
The current conventional method of culture and identification by phenotypic testing is slow
and inaccurate.
Specific Aims: 1) Develop a rapid identification method, to include quantitation, for
important wound pathogens, 2) Analyze bacterial flora of wound infection by molecular means
and by conventional culturing; both tissue biopsies and pus will be studied by both
methodologies, 3) Determine the incidence and significance of the so-called "uncultivable"
flora.
Study Design: We will study 50 postoperative and traumatic wound infections and 50 closed
soft tissue abscesses in intravenous drug abusers annually, from a general surgical service
at Olive View County Hospital, affiliated with UCLA and the VA Medical Center West Los
Angeles, in collaboration with Dr. Robert Bennion. Whenever possible, we will obtain tissue
biopsies from the active edge of the wound for processing, along with pus from the wound.
We will develop species-specific primers/probes for organisms that are encountered in
different types of wound infections based on information about the flora of wound infection
obtained from previous studies by our group and others and supplemented with primers/probes
made from cultural isolates not previously encountered. The primers and probes will be used
in a high-throughput procedure (real-time PCR) that permits rapid identification and
quantitation of organisms. The entire procedure, including both DNA extraction and real-time
PCR, can be completed within 5 hours for one sample. Multiple samples can be done
concurrently. While it may be necessary to start therapy empirically, it will be possible to
change to more appropriate antimicrobial agents when the bacteriologic data becomes
available in 5 hours. Concurrently, we will utilize another molecular approach, 16S rRNA
gene cloning, to analyze the total flora of the sample. We will first amplify 16S rRNA genes
using universal (all bacteria) primers by PCR of DNA extracted from the sample. Then, a
clone library will be constructed in E. coli and all clones will be studied by 16S rDNA
sequencing of ~1500 base pairs. This permits detection of organisms called "uncultivable",
as well as organisms that can be cultured successfully. Any "uncultivable" organisms that
are encountered frequently may be important; therefore, we will develop primers and probes
for their rapid identification and we will use a variety of techniques to attempt to
cultivate these (we have done this successfully in a few cases already). At the same time as
the molecular approaches are being done, we will use conventional cultural processing. The
cultural approach will provide organisms for additional study (especially for antimicrobial
susceptibility testing) and will serve as the current standard for comparison with the newer
molecular approaches. Culture will be done semiquantitatively and identification will be
done by 16S rDNA sequencing supplemented by phenotypic testing as indicated. The cultural
approach typically takes several days to isolate the organisms in pure culture.
The two molecular approaches will be compared with the conventional cultural approach in
terms of organisms detected; each specimen will be studied by all techniques, for
comparative purposes.
Relevance: The speed of the various identification schemes indicated above shows clearly
that we would be able to provide accurate, quantitative identification (more accurate than
by the conventional cultural approach) a great deal sooner than has been possible in the
past. This should lead to much earlier application of the most appropriate therapy and
minimize empiric use of our most powerful agents. This is likely to result in improved
clinical outcome, less chance for antimicrobial resistance, and cost savings as well. It
will provide us with a much more accurate picture of the infecting flora of various surgical
wounds and the antimicrobial susceptibility pattern of these organisms. We will learn
whether, as in burn wound infections, quantitative study of tissue biopsies will provide a
better picture of the true infecting flora than conventional wound cultures. We will learn
whether "uncultivable" bacteria (which actually make up the greatest percentage of the
indigenous flora of the bowel and the upper respiratory tract) are important clinically or
not. Finally, we will develop a more complete set of primers/probes to improve the molecular
approach.
;
Observational Model: Case-Only, Time Perspective: Prospective
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