Journal Article

Animals; Biological Markers; Bioware; Diagnostic Imaging; Image Processing, Computer-Assisted; Luminescent Measurements; Luminescent Proteins; Molecular Probes; Optical Devices; Optical Phenomena; PC-3M-luc; Reproducibility of Results

There has recently been an explosion in the availability of new technologies to noninvasively detect biological processes in preclinical models. One such modality, optical imaging, comprises using bioluminescent and fluorescent reporters and probes to repetitively interrogate molecular events and monitor disease progression in animal models. This review includes an overview of optical imaging technologies (e.g., hardware, reporters, probes) available for small animal imaging and their application in monitoring disease progression, therapeutic efficacy, and molecular processes such as proliferation, apoptosis, and angiogenesis. Also discussed are some of the challenges associated with in vivo optical imaging and the necessary controls and biological correlates one must include in experimental design and interpretation for successful preclinical studies.

Journal Article

A549-luc-C8; Animals; Bioware; Cell Line, Tumor; Colonic Neoplasms; Fluorouracil; HT-29-luc-D6 cells; Humans; Image Interpretation, Computer-Assisted; Longitudinal Studies; Luciferases; Luminescent Measurements; Lung Neoplasms; Lymphatic Metastasis; Male; Mice; Mice, SCID; Mitomycin; Models, Biological; Neoplasm Transplantation; PC-3M-luc; Prostatic Neoplasms

Bioluminescent imaging (BLI) permits sensitive in vivo detection and quantification of cells specifically engineered to emit visible light. Three stable human tumor cell lines engineered to express luciferase were assessed for their tumorigenicity in subcutaneous, intravenous and spontaneous metastasis models. Bioluminescent PC-3M-luc-C6 human prostate cancer cells were implanted subcutaneously into SCID-beige mice and were monitored for tumor growth and response to 5-FU and mitomycin C treatments. Progressive tumor development and inhibition/regression following drug treatment were observed and quantified in vivo using BLI. Imaging data correlated to standard external caliper measurements of tumor volume, but bioluminescent data permitted earlier detection of tumor growth. In a lung colonization model, bioluminescent A549-luc-C8 human lung cancer cells were injected intravenously and lung metastases were monitored in vivo by whole animal imaging. Anesthetized mice were imaged weekly allowing a temporal assessment of in vivo lung tumor growth. This longitudinal study design permitted an accurate, real-time evaluation of tumor burden in the same animals over time. End-point bioluminescence measured in vivo correlated to total lung weight at necropsy. For a spontaneous metastatic tumor model, bioluminescent HT-29-luc-D6 human colon cancer cells implanted subcutaneously produced metastases to lung and lymph nodes in SCID-beige mice. Both primary tumors and micrometastases were detected by BLI in vivo. Ex vivo imaging of excised lung lobes and lymph nodes confirmed the in vivo signals and indicated a slightly higher frequency of metastasis in some mice. Levels of bioluminescence from in vivo and ex vivo images corresponded to the frequency and size of metastatic lesions in lungs and lymph nodes as subsequently confirmed by histology. In summary, BLI provided rapid, non-invasive monitoring of tumor growth and regression in animals. Its application to traditional oncology animal models offers quantitative and sensitive analysis of tumor growth and metastasis. The ability to temporally assess tumor development and responses to drug therapies in vivo also improves upon current standard animal models that are based on single end point data.

Journal Article

Animals; Bioware; Contrast Media; Magnetic Resonance Imaging; Mice; Nanotechnology; PC-3M-luc

We have developed and tested a liposomal nanocomplex system, which contains Gd-DTPA as a payload and transferrin on the surface, as a tumor specific targeting MRI contrast agent for studying prostate cancer tumors in mice. In vivo, the probe significantly enhanced the MRI signal. The image contrast between the peripheral region of the tumor and the non-involved muscle was nearly 50% higher two hours after administration of the nanocomplex. The liposomal nanocomplex increased the amount of Gd accumulated in tumors by factor 2.8 compared to that accumulated by using Magnevist alone. Moreover, the heterogeneous MRI image features correlate well with the tumor pathology. The image enhancement patterns can be used for cancer prognosis and non-invasive monitoring of the response to therapy.

Journal Article

Androgens; Animals; Bioware; Cell Transformation, Neoplastic; Disease Models, Animal; Genes, Reporter; Humans; Image Processing, Computer-Assisted; In Situ Hybridization; Luciferases, Firefly; Luminescent Measurements; Male; Mice; Mice, Transgenic; PC-3M-luc; Promoter Regions, Genetic; Prostate; Prostate-Specific Antigen; Prostatic Neoplasms

Several transgenic mouse models of prostate cancer have been developed recently that are able to recapitulate many key biological features of the human condition. It would, therefore, be desirable to employ these models to test the efficacy of new therapeutics before clinical trial; however, the variable onset and non-visible nature of prostate tumor development limit their use for such applications. We now report the generation of a transgenic reporter mouse that should obviate these limitations by enabling noninvasive in vivo bioluminescence imaging of normal and spontaneously transformed prostate tissue in the mouse. We used an 11-kb fragment of the human prostate-specific antigen (PSA) promoter to achieve specific and robust expression of firefly luciferase in the prostate glands of transgenic mice. Ex vivo bioluminescence imaging and in situ hybridization analysis confirmed that luciferase expression was restricted to the epithelium in all four lobes of the prostate. We also show that PSA-Luc mice exhibit decreased but readily detectable levels of in vivo bioluminescence over extended time periods following androgen ablation. These results suggest that this reporter should enable in vivo imaging of both androgen-dependent and androgen-independent prostate tumor models. As proof-of-principle, we show that we could noninvasively image SV40 T antigen-induced prostate tumorigenesis in mice with PSA-Luc. Furthermore, we show that our noninvasive imaging strategy can be successfully used to image tumor response to androgen ablation in transgenic mice and, as a result, that we can rapidly identify individual animals capable of sustaining tumor growth in the absence of androgen.

Journal Article

Animals; Bioware; Cell Differentiation; Chick Embryo; Embryonic Stem Cells; Fluorescent Dyes; Humans; Luciferases; Luminescent Measurements; Mice; Mice, SCID; PC-3M-luc; Software; Stem Cell Transplantation; Teratoma

Research into the behavior, efficacy, and biosafety of stem cells with a view to clinical transplantation requires the development of noninvasive methods for in vivo imaging of cells transplanted into animal models. This is particularly relevant for human embryonic stem cells (hESCs), because transplantation of undifferentiated hESCs leads to tumor formation. The present study aimed to monitor hESCs in real time when injected in vivo. hESCs were stably transfected to express luciferase, and luciferase expression was clearly detected in the undifferentiated and differentiated state. When transfected hESCs were injected into chick embryos, bioluminescence could be detected both ex and in ovo. In the SCID mouse model, undifferentiated hESCs were detectable after injection either into the muscle layer of the peritoneum or the kidney capsule. Tumors became detectable between days 10-30, with approximately a 3 log increase in the luminescence signal by day 75. The growth phase occurred earlier in the kidney capsule and then reached a plateau, whilst tumors in the peritoneal wall grew steadily throughout the period analysed. These results show the widespread utility of bioluminescent for in vivo imaging of hESCs in a variety of model systems for preclinical research into regenerative medicine and cancer biology.