Citation Details

Journal Article

Xen14, Xen 14, E. coli Xen14, IVIS, Animals; Anti-Infective Agents/*pharmacology/therapeutic use; Bacteria/*drug effects/pathogenicity; Bacterial Infections/drug therapy/*etiology; Biocompatible Materials/*adverse effects/chemistry; Biofilms; Coated Materials, Biocompatible/chemistry; Fluorescent Dyes/chemistry/metabolism; Humans; Image Enhancement/methods; Light; Luminescent Measurements/instrumentation/*methods; Luminescent Proteins/metabolism; Microscopy, Fluorescence/instrumentation/*methods; Prosthesis-Related Infections/drug therapy/microbiology; Sensitivity and Specificity

This review presents the current state of Bioluminescence and Fluorescent Imaging technologies (BLI and FLI) as applied to Biomaterial-Associated Infections (BAI). BLI offers the opportunity to observe the in vivo course of BAI in small animals without the need to sacrifice animals at different time points after the onset of infection. BLI is highly dependent on the bacterial cell metabolism which makes BLI a strong reporter of viable bacterial presence. Fluorescent sources are generally more stable than bioluminescent ones and specifically targeted, which renders the combination of BLI and FLI a promising tool for imaging BAI. The sensitivity and spatial resolution of both imaging tools are, however, dependent on the imaging system used and the tissue characteristics, which makes the interpretation of images, in terms of the location and shape of the illuminating source, difficult. Tomographic reconstruction of the luminescent source is possible in the most modern instruments, enabling exact localization of a colonized implant material, spreading of infecting organisms in surrounding tissue and immunological tissue reactions. BLI studies on BAI have successfully distinguished between different biomaterials with respect to the development and clearance of BAI in vivo, simultaneously reducing animal use and experimental variation. It is anticipated that bio-optical imaging will become an indispensable technology for the in vivo evaluation of antimicrobial coatings.

Journal Article

Xen14, Xen 14, E. coli Xen14, IVIS, Animals; Cattle; Escherichia coli/*cytology/isolation & purification/physiology; Female; Genitalia, Female/*microbiology; Optical Phenomena; *Photons

The objectives of this study were to (1) characterize the photonic properties of Escherichia coli-Xen14 and (2) conduct photonic imaging of E. coli-Xen14 within bovine reproductive tract segments (RTS) ex vivo (Bos indicus). E. coli-Xen14 was grown for 24h in Luria Bertani medium (LB), with or without kanamycin (KAN). Every 24h, for an 8-d interval, inoculums were imaged and photonic emissions (PE) collected. Inoculums were subcultured and plated daily to determine the colony forming units (CFU) and ratio of photon emitters to nonemitters. In the second objective, abattoir-derived bovine reproductive tracts (n=9) were separated into posterior and anterior vagina, cervix, uterine body, and uterine horns. Two concentrations (3.2x10(8) and 3.2x10(6) CFU/200microL for relative [High] and [Low], respectively) of E. coli-Xen14 were placed in translucent tubes for detection of PE through RTS. The CFU did not differ (P=0.31) over time with or without KAN presence; they remained stable with 99.93% and 99.98% photon emitters, respectively. However, PE were lower (P<0.0001) in cultures containing KAN than in those containing no KAN (629.8+/-117.7 vs. 3012.0+/-423.5 relative lights units per second [RLU/sec], respectively). On average, the percentage of PE between RTS, for both concentrations, was higher (P<0.05) in the uterine body. In summary, E. coli-Xen14 remained stable with respect to the proportions of photon emitters with or without KAN (used to selectively culture E. coli-Xen14). However, KAN presence suppressed photonic activity. The ability to detect PE through various segments of the reproductive tract demonstrated the feasibility of monitoring the presence of E. coli-Xen14 in the bovine reproductive tract ex vivo.

Journal Article

Xen14, Xen 14, E. coli Xen14, IVIS, Animals; Bacteroides fragilis/*isolation & purification; Diagnostic Imaging/methods; Disease Progression; Escherichia coli/*isolation & purification; Luciferases, Bacterial/*diagnostic use; Luminescent Agents/*diagnostic use; Male; Peritoneal Lavage; Peritonitis/*microbiology/pathology/therapy; Rats; Rats, Wistar

BACKGROUND: Bacterial peritonitis is a life-threatening abdominal infection associated with high morbidity and mortality. The rat is a popular animal model for studying peritonitis and its treatment, but longitudinal monitoring of the progression of peritonitis in live animals has been impossible until now and thus required a large number of animals. Our objective was to develop a noninvasive in vivo imaging technique to monitor the spatiotemporal spread of bacterial peritonitis. METHODS: Peritonitis was induced in 8 immunocompetent male Wistar rats by placing fibrin clots containing 5x10(8) cells of both Bacteroides fragilis (American Type Tissue Culture [ATCC)] 25,285 and bioluminescent Escherichia coli Xen14. After 1 or 2 days, infected clots were removed and open abdomen lavage was performed. In vivo bioluminescent imaging was used to monitor the spread of peritonitis. RESULTS: Bioluminescent in vivo imaging showed an increase in the area of spread, and the number of E. coli tripled into the rat's abdominal cavity on day 1 after clot insertion; however, on day 2, encapsulation of the clot confined bacterial spread. Bioluminescent E. coli respread over the peritoneal cavity after lavage; within 10 days, however, in vivo imaging showed a decrease of 3-4 orders of magnitude in bacterial load. CONCLUSION: Bioluminescent in vivo imaging can be effectively used to monitor the spatiotemporal behavior of the peritonitis during 3 different stages of the disease process: initiation, treatment, and follow-up. Imaging allows researchers to repeatedly image the same animal, thereby reducing variability and providing greater confidence in determining treatment efficacies for therapeutic interventions using a small number of animals.

Journal Article

IVIS, Xenogen, Xen10

Marginal zone macrophages in the murine spleen play an important role in the capture of blood-borne pathogens and are viewed as an essential component of host defense against the development of pneumococcal sepsis. However, we and others have previously described the loss of marginal zone macrophages associated with the splenomegaly that follows a variety of viral and protozoal infections; this finding raises the question of whether these infected mice would become more susceptible to secondary pneumococcal infection. Contrary to expectations, we found that mice lacking marginal zone macrophages resulting from Leishmania donovani infection have increased resistance to Streptococcus pneumoniae type 3 and do not develop sepsis. Using biophotonic imaging, we observed that pneumococci are rapidly trapped in the spleens of L. donovani-infected mice. By selective depletion studies using clodronate liposomes, depleting monoclonal antibodies specific for Ly6C/G and Ly6G, and CD11c-DTR mice, we show that the enhanced early resistance in L. donovani-infected mice is entirely due to the activity of SIGNR1? red pulp macrophages. Our data demonstrate, therefore, that the normal requirement for SIGNR1+ marginal zone macrophages to protect against a primary pneumococcal infection can, under conditions of splenomegaly, be readily compensated for by activated red pulp macrophages.

Journal Article

MMPSense, IVIS, Aged; Carotid Artery Diseases/diagnosis/enzymology/*pathology; Diagnostic Imaging/methods; Female; Humans; Matrix Metalloproteinase 9/analysis; Matrix Metalloproteinases/*analysis; Spectroscopy, Near-Infrared/*methods; Tissue Distribution

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