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Journal Article

Animals; Bacteroides fragilis; Diagnostic Imaging; Disease Progression; Escherichia coli; Luciferases, Bacterial; Luminescent Agents; Male; Peritoneal Lavage; Peritonitis; Rats; Rats, Wistar; Xen14

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

IntegriSense, Animals; Carcinoma, Squamous Cell/*pathology/surgery; Fluorescent Dyes/*diagnostic use; Humans; Integrin alphaVbeta3/*metabolism; Mice; Mice, Inbred BALB C; Mouth Neoplasms/*pathology/surgery; Spectroscopy, Near-Infrared; *Surgery, Computer-Assisted

BACKGROUND AND OBJECTIVES: Near-infrared (NIR) fluorescence optical imaging is a promising technique to assess the tumor margins during cancer surgery. This technique requires targeting by specific fluorescence agents to differentiate tumor from normal surrounding tissue. We assessed the feasibility of cancer detection using NIR fluorescence agents that target either alphavbeta3 integrins or the enhanced permeability and retention (EPR) effect in an orthotopic mouse model of oral cancer. METHODS: Binding of the integrin-targeted agent to tumor cells was assessed in vitro. Oral cancer was induced in 6 BALB/c nu/nu mice by submucosal inoculation of human OSC19-luc cells into the tongue. Tumor growth was followed with bioluminescence imaging. A combination of agents targeting integrins or EPR effect was injected followed by fluorescence imaging in vivo and ex vivo after resection of the tongues. RESULTS: Oral cancer was clearly demarcated in vitro; in vivo; and on histological analysis with sufficient tumor-to-background ratios of the contrast agents. CONCLUSION: This study demonstrates the feasibility of optical imaging of oral squamous cell carcinoma based on targeting of alphavbeta3 integrins and the EPR effect. Once these NIR fluorescence agents become available for clinical testing, optical image-guided surgery could reduce residual disease after oral cancer surgery.

Journal Article

Xen31, Xen 31, MRSA, S. aureus, IVIS, Bioluminescence, Administration, Cutaneous; Animals; Disease Models, Animal; Female; *Methicillin-Resistant Staphylococcus aureus; Mice; Mice, Inbred BALB C; Photobleaching; *Photochemotherapy; Polyethyleneimine/administration & dosage; Porphyrins/*administration & dosage; Radiation-Sensitizing Agents/*administration & dosage; Staphylococcal Skin Infections/etiology/pathology/*therapy; Wound Infection/microbiology/pathology/*therapy

BACKGROUND AND OBJECTIVE: Methicillin-resistant Staphylococcus aureus (MRSA) skin infections are now known to be a common and important problem in the Unites States. The objective of this study was to investigate the efficacy of photodynamic therapy (PDT) for the treatment of MRSA infection in skin abrasion wounds using a mouse model. STUDY DESIGN/MATERIALS AND METHODS: A mouse model of skin abrasion wound infected with MRSA was developed. Bioluminescent strain of MRSA, a derivative of ATCC 33591, was used to allow the real-time monitoring of the extent of infection in mouse wounds. PDT was performed with the combination of a polyethylenimine (PEI)-ce6 photosensitizer (PS) and non-coherent red light. In vivo fluorescence imaging was carried out to evaluate the effect of photobleaching of PS during PDT. RESULTS: In vivo fluorescence imaging of conjugate PEI-ce6 applied in mice indicated the photobleaching effect of the PS during PDT. PDT induced on average 2.7 log(10) of inactivation of MRSA as judged by loss of bioluminescence in mouse skin abrasion wounds and accelerated the wound healing on average by 8.6 days in comparison to the untreated infected wounds. Photobleaching of PS in the wound was overcome by adding the PS solution in aliquots. CONCLUSION: PDT may represent an alternative approach for the treatment of MRSA skin infections.

Journal Article

In-stent restenosis; Mouse; Stent; Animal model; in vivo imaging; MMPSense FAST; FMT

Background and aims: In-stent restenosis (ISR) is the major complication that occurs after percutaneous coronary interventions to facilitate coronary revascularization. Herein we described a simple and cost-effective model, which reproduces important features of ISR in the mouse.

Methods and results: Microvascular bare metal stents were successfully implanted in the abdominal aorta of atherosclerotic ApoE-null mice. Patency of implanted stents was interrogated using ultrasound biomicroscopy. Aortas were harvested at different time points after implantation and processed for histopathological analysis. Thrombus formation was histologically detected after 1 day. Leukocyte adherence and infiltration were evident after 7 days and decreased thereafter. Neointimal formation, neointimal thickness and luminal stenosis simultaneously increased up to 28 days after stent implantation. Using multichannel fluorescence molecular tomography (FMT) for spatiotemporal resolution of MMP activities, we observed that MMP activity in the stented aorta of Apo-E null mice was 2-fold higher than that of wild-type mice. Finally, we compared neointimal formation in response to stenting in two genetically different mouse strains. In-stent neointimas in FVB/NJ mice were 2-fold thicker than in C57BL/6J mice (p=0.002).

Conclusion: We have developed a model that can take advantage of the multiple genetic resources available for the mouse to study the mechanisms of in-stent restenosis.

Journal Article

Xen10, Xen 10, Streptococcus pnuemoniae Xen10, IVIS,

Background & objectives: In vivo imaging system has contributed significantly to the understanding of bacterial infection and efficacy of drugs in animal model. We report five rapid, reproducible, and non invasive murine pulmonary infection, skin and soft tissue infection, sepsis, and meningitis models using Xenogen bioluminescent strains and specialized in vivo imaging system (IVIS). Methods: The progression of bacterial infection in different target organs was evaluated by the photon intensity and target organ bacterial counts. Genetically engineered bioluminescent bacterial strains viz. Staphylococcus aureus Xen 8.1, 29 and 31; Streptococcus pneumoniae Xen 9 and 10 and Pseudomonas aeruginosa Xen-5 were used to induce different target organs infection and were validated with commercially available antibiotics. Results: The lower limit of detection of colony forming unit (cfu) was 1.7-log10 whereas the lower limit of detection of relative light unit (RLU) was 4.2-log10 . Recovery of live bacteria from different target organs showed that the bioluminescent signal correlated to the live bacterial count. Interpretation & conclusions: This study demonstrated the real time monitoring and non-invasive analysis of progression of infection and pharmacological efficacy of drugs. These models may be useful for pre-clinical discovery of new antibiotics.