Bioluminescent Imaging (bioluminescent + imaging)

Distribution by Scientific Domains
Medical Sciences80%

Selected Abstracts

Bioluminescent imaging of reporter gene expression in the lungs of wildtype and model mice following the administration of PEG-stabilized DNA nanoparticles

MICROSCOPY RESEARCH AND TECHNIQUE, Issue 9 2010
Assem G. Ziady
Abstract DNA nanoparticles (DNPs) formed by compacting DNA with polyethyleneglycolylated poly- L -lysine are a nonviral vector shown to be safe and efficacious in animals and humans. To extend our capabilities of assessing the efficacy and duration of expression achieved by DNPs, we tested the utility of bioluminescent imaging (BLI) of transgene expression in wildtype and cystic fibrosis (CF) mouse models. We tested the effect of route of administration, mouse coat color, anesthesia, dose, and promoter sequence on the level and duration of expression. Furthermore, we investigated the correlation between imaging and direct analysis of luciferase expression in lung homogenates. We found that intratracheal instillation, and the use of deep and prolonged anesthesia with avertin produced significantly higher expression compared with intranasal administration, and the use of lighter anesthesia with isoflurane. Although similar expression was observed for both dark and light coat animals, imaging signal intensity was attenuated in mice with dark fur. Furthermore, good correlation between imaging and direct homogenate analysis was observed for single dose (r = 0.96), and dose response studies in wildtype (r = 0.82) and CF mice (r = 0.87). Finally, we used imaging to track gene expression over a 56-day time course. We found that the human ubiquitin B promoter gives stable transgene expression up to 49 days following nanoparticle administration, while expression with the cytomegalovirus promoter diminished after 2 days and returned to background levels by day 14. Taken together, our results demonstrate that BLI is an effective and useful modality for measuring gene expression conferred by DNPs in the lung. Microsc. Res. Tech. 73:918,928, 2010. © 2010 Wiley-Liss, Inc. [source]

Human-in-mouse modeling of primary head and neck squamous cell carcinoma,

THE LARYNGOSCOPE, Issue 12 2009
Jonathan H. Law MD
Abstract Objectives/Hypothesis: To develop a reliable modeling system for head and neck squamous cell carcinoma (HNSCC). Study Design: Laboratory-based translational study. Methods: HNSCC tissue was obtained from patients at biopsy/resection, cultured, and implanted into mice. In vivo, tumor growth, and survival was monitored by bioluminescence imaging. Histology and immunohistochemistry (IHC) were used to confirm HNSCC and human origin. Results: Short-term culture techniques were optimized allowing survival of primary HNSCC cells more than 7 days in 76% of tumors. The size of the tumor biopsy collected did not correlate with the success of short-term culture or xenograft establishment. Xenograft modeling was attempted in primary HNSCCs from 12 patients with a success rate of 92%. Immunostaining confirmed human origin of epithelial tumor cells within the modeled tumor. Bioluminescence and Ki67 IHC suggested tumor proliferation within the model. Luciferase expression was maintained for as long as 100 days in modeled tumors. Conclusions: The techniques developed for short-term primary tumor culture followed by xenograft modeling provide a low-cost and tractable model for evaluation of HNSCC response to standard and novel therapies. The high success rate of human-in-mouse tumor formation from primary HNSCC suggests that selection pressures for tumor growth in this model may be less than those observed for establishment of cell lines. Bioluminescent imaging provides a useful tool for evaluating tumor growth and could be expanded to measure response of the modeled tumor to therapy. This model could be adapted for xenograft modeled growth of other primary tumor types. Laryngoscope, 2009 [source]

Quantitative mouse model of implant-associated osteomyelitis and the kinetics of microbial growth, osteolysis, and humoral immunity,

JOURNAL OF ORTHOPAEDIC RESEARCH, Issue 1 2008
Dan Li
Abstract Although osteomyelitis (OM) remains a serious problem in orthopedics, progress has been limited by the absence of an in vivo model that can quantify the bacterial load, metabolic activity of the bacteria over time, immunity, and osteolysis. To overcome these obstacles, we developed a murine model of implant-associated OM in which a stainless steel pin is coated with Staphylococcus aureus and implanted transcortically through the tibial metaphysis. X-ray and micro-CT demonstrated concomitant osteolysis and reactive bone formation, which was evident by day 7. Histology confirmed all the hallmarks of implant-associated OM, namely: osteolysis, sequestrum formation, and involucrum of Gram-positive bacteria inside a biofilm within necrotic bone. Serology revealed that mice mount a protective humoral response that commences with an IgM response after 1 week, and converts to a specific IgG2b response against specific S. aureus proteins by day 11 postinfection. Real-time quantitative PCR (RTQ-PCR) for the S. aureus specific nuc gene determined that the peak bacterial load occurs 11 days postinfection. This coincidence of decreasing bacterial load with the generation of specific antibodies is suggestive of protective humoral immunity. Longitudinal in vivo bioluminescent imaging (BLI) of luxA-E transformed S. aureus (Xen29) combined with nuc RTQ-PCR demonstrated the exponential growth phase of the bacteria immediately following infection that peaks on day 4, and is followed by the biofilm growth phase at a significantly lower metabolic rate (p,<,0.05). Collectively, these studies demonstrate the first quantitative model of implant-associated OM that defines the kinetics of microbial growth, osteolysis, and humoral immunity following infection. © 2007 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J. Orthop Res 26:96,105, 2008 [source]

Bioluminescent imaging of reporter gene expression in the lungs of wildtype and model mice following the administration of PEG-stabilized DNA nanoparticles

MICROSCOPY RESEARCH AND TECHNIQUE, Issue 9 2010
Assem G. Ziady
Abstract DNA nanoparticles (DNPs) formed by compacting DNA with polyethyleneglycolylated poly- L -lysine are a nonviral vector shown to be safe and efficacious in animals and humans. To extend our capabilities of assessing the efficacy and duration of expression achieved by DNPs, we tested the utility of bioluminescent imaging (BLI) of transgene expression in wildtype and cystic fibrosis (CF) mouse models. We tested the effect of route of administration, mouse coat color, anesthesia, dose, and promoter sequence on the level and duration of expression. Furthermore, we investigated the correlation between imaging and direct analysis of luciferase expression in lung homogenates. We found that intratracheal instillation, and the use of deep and prolonged anesthesia with avertin produced significantly higher expression compared with intranasal administration, and the use of lighter anesthesia with isoflurane. Although similar expression was observed for both dark and light coat animals, imaging signal intensity was attenuated in mice with dark fur. Furthermore, good correlation between imaging and direct homogenate analysis was observed for single dose (r = 0.96), and dose response studies in wildtype (r = 0.82) and CF mice (r = 0.87). Finally, we used imaging to track gene expression over a 56-day time course. We found that the human ubiquitin B promoter gives stable transgene expression up to 49 days following nanoparticle administration, while expression with the cytomegalovirus promoter diminished after 2 days and returned to background levels by day 14. Taken together, our results demonstrate that BLI is an effective and useful modality for measuring gene expression conferred by DNPs in the lung. Microsc. Res. Tech. 73:918,928, 2010. © 2010 Wiley-Liss, Inc. [source]

In vivo real-time imaging of TGF-,-induced transcriptional activation of the RANK ligand gene promoter in intraosseous prostate cancer

THE PROSTATE, Issue 4 2004
Jian Zhang
Abstract BACKGROUND Current animal models of prostate cancer (CaP) bone metastasis do not allow measurement of either tumor growth in bone over time or activation of gene promoters in intraosseous tumors. To develop these methods, we used bioluminescent imaging (BLI) to determine if expression of receptor activator of NF-,B ligand (RANKL), a pro-osteoclastogenic factor that promotes CaP bone metastases, is modulated by the bone matrix protein transforming growth factor-, (TGF-,) in vivo. METHODS C4-2B human CaP cells were treated with TGF-, in vitro and RANKL mRNA and protein production were measured by polymerase chain reaction (PCR) and ELISA, respectively. Then C4-2B cells stably transfected with the RANKL promoter driving luciferase (lux) were injected intra-tibially into severe combined immundeficient (SCID) mice. Tumors were subjected to BLI every 2 weeks for 6 weeks and serum prostate specific antigen (PSA) was measured using ELISA. Vehicle (V), 1,25 dihydroxyvitamin D (VitD), or TGF-, was administered to mice with established tumors and BLI to measure RANKL promoter activity was performed. Tumors were then subjected to immunohistochemistry for lux and assayed for RANKL mRNA levels. RESULTS TGF-, induced RANKL protein and mRNA expression and activated the RANKL promoter activity in a dose-dependent manner in vitro. BLI demonstrated an increase in intraosseous tumor size over time, which correlated with serum PSA levels. Administration of TGF-, and VitD to mice with established intraosseous tumors increased lux activity compared to V. Intratibial tumor RANKL mRNA expression paralleled the increased promoter activity. Immunohistochemistry confirmed the presence of lux in the intraosseous tumors. CONCLUSIONS These results demonstrate the ability to measure intraosseous tumor growth over time and gene promoter activation in an established intraosseous tumor in vivo and also demonstrate that TGF-, induces activates the RANKL promoter. These results provide a novel method to explore the biology of CaP bone metastases. © 2004 Wiley-Liss, Inc. [source]