Mary A. Hall

Imaging prostate cancer lymph node metastases with a multimodality contrast agent

Methods to detect lymph node (LN) metastases in prostate cancer (PCa) are limited. Pelvic LN dissection is commonly performed during prostatectomy, but often followed by morbid complications. More refined methods for detecting LN invasion are needed.

Comparison of mAbs Targeting Epithelial Cell Adhesion Molecule for the Detection of Prostate Cancer Lymph Node Metastases with Multimodal Contrast Agents: Quantitative Small-Animal PET/CT and NIRF

The proliferation of most carcinomas is associated with an overexpression of epithelial cell adhesion molecule (EpCAM), a 40-kDa type I transmembrane protein found on epithelial cells yet absent from other cell types. The absence of EpCAM in normal lymphatics makes it an attractive marker for studying lymph node (LN) metastases of carcinomas to improve LN staging accuracy. Herein, we developed and quantitatively compared dual-labeled monoclonal antibodies (mAbs) of varying affinities against EpCAM for both noninvasive and intraoperative detection of metastatic LNs in prostate cancer. Methods: A panel of hybridoma-derived anti-EpCAM mAbs was generated and screened. Two high-affinity candidate mAbs with specificity for nonoverlapping epitopes on the EpCAM extracellular domain were chosen for further evaluation. After conjugation with DOTA for 64Cu radiolabeling and IRDye 800CW as a fluorophore, dual-labeled specific or isotype control mAb was administered intravenously to male nu/nu mice at 10–12 wk after orthotopic implantation of DsRed-expressing PC3 cells. Within 18–24 h, noninvasive small-animal PET/CT and in vivo, in situ, and ex vivo DsRed reporter gene and near-infrared fluorescence (NIRF) imaging were performed to detect primary tumors and metastatic LNs. Using DsRed fluorescence as the true indicator of cancer-positive tissue, we performed receiver operating characteristic curve analyses of percentage injected dose per gram measured from quantitative small-animal PET/CT and fluorescence intensity measured from semiquantitative NIRF imaging for each LN examined to compare mAb sensitivity and specificity. Results: mAbs 7 and 153 generated in-house were found to have higher affinity than commercial mAb 9601. Accuracy, as a function of sensitivity and specificity, for the detection of cancer-positive LNs during in vivo small-animal PET/CT was highest for mAbs 7 (87.0%) and 153 (78.0%) and significantly greater (P < 0.001) than random chance (50.0%). Rates for mAb 9601 (60.7%) and control mAb 69 (27.0%) were not significantly different from chance. Similarly, mAb 7 had significant detection accuracy by NIRF imaging (96.0%, P < 0.001). Conclusion: mAbs 7 and 153 are attractive, high-affinity candidates for further multimodal imaging agent optimization aimed at enhancing sensitivity and specificity for detection of metastatic LNs in prostate cancer. Fully quantitative NIRF imaging is needed for comprehensive analyses of NIRF-labeled agent accuracy for intraoperative guidance.

Multimodal Chelation Platform for Near-Infrared Fluorescence/Nuclear Imaging

Dual-labeled compounds containing nuclear and near-infrared fluorescence contrast have the potential to molecularly guide surgical resection of cancer by extending whole-body diagnostic imaging findings into the surgical suite. To simplify the dual labeling process for antibody-based agents, we designed a multimodality chelation (MMC) scaffold which combined a radiometal chelating agent and fluorescent dye into a single moiety. Three dye-derivatized MMC compounds were synthesized and radiolabeled. The IRDye 800CW conjugate, 4, had favorable optical properties and showed rapid clearance in vivo. Using 4, an epithelial cell adhesion molecule (EpCAM) targeting MMC-immunoconjugate was prepared and dual-labeled with (64)Cu. In vitro binding activity was confirmed after MMC conjugation. Multimodal imaging studies showed higher tumor accumulation of (64)Cu-7 compared to nontargeted (64)Cu-4 in a prostate cancer model. Further evaluation in different EpCAM-expressing cell lines is warranted as well as application of the MMC dual labeling approach with other monoclonal antibodies.

Detection of lymphangiogenesis by near-infrared fluorescence imaging and responses to VEGF-C during healing in a mouse full-dermis thickness wound model

Noninvasive, longitudinal near‐infrared fluorescence (NIRF) imaging was used to detect and quantify lymphangiogenesis following a full‐dermis thickness incision in the presence and absence of locally administered vascular endothelial growth factor‐C (VEGF‐C), a well‐known regulator of lymphangiogenesis. Peripheral cytokines/chemokines were also measured in treated and sham‐injected animals. Lymphangiogenesis was detected via NIRF imaging by day 7–8 and confirmed by intravital microscopy, while angiogenesis was observed by day 2–3 postincision (PI). All lymph vessel parameters quantified were significantly greater on wounded vs. nonwounded sides of mice. Lymph vessel parameters appeared larger on wounded sides of VEGF‐C– relative to NaCl‐treated mice, although differences were not significant. Interleukin‐1α and interleukin‐22 were significantly elevated at day 7 PI relative to respective preincision levels in VEGF‐C‐treated mice, and decreased by day 21 PI to levels nearing those measured preincision. For the majority of cytokines/chemokines measured, mean responses were significantly greater in VEGF‐C– vs. NaCl‐treated animals. Local VEGF‐C administration may stimulate lymphangiogenesis during tissue repair and regeneration via mediating systemic cytokine/chemokine levels. NIRF imaging can be utilized to detect lymphangiogenesis during wound healing, and offers a promising platform to complement current methods for monitoring wound status and studying the effects of growth factors on healing.

Quantifying multimodal contrast agent biological activity using near-infrared flow cytometry

Prior to imaging agent use in preclinical studies and clinical diagnostics, biological activity must be validated. The Lindmo assay has been used conventionally to quantify radiolabeled antibody (Ab) immunoreactivity, although published findings suggest it does not provide consistently accurate results. We developed and tested a near-infrared (NIR) flow cytometry (FC) method for quantifying biological activity of a dual-labeled Ab for use as a multimodal contrast agent in small animal and human positron emission tomography and NIR fluorescence imaging. Antibody specific for epithelial cell adhesion molecule was conjugated to DOTA-NHS-ester, labeled with IRDye 800CW and further labeled with (64)Cu or nonradioactive Cu prior to reacting with human prostate cancer cells for testing by the Lindmo or FC method, respectively. Immunoreactivity of the dual-labeled agent was found to be 76.4 ± 15.7% by the Lindmo assay. When tested with and without Cu labeling using NIR FC, the biological activity was found to be 73.1 ± 7.7 and 79.4 ± 8.1%, respectively. No significant differences were found between these activity levels (p > 0.05), supporting NIR FC as an alternative method for measuring immunoreactivity and demonstrating that Cu labeling does not significantly affect the agents ability to bind to its target. Biological activity was significantly reduced when the NIR dye-to-protein ratio was increased 3- to 4-fold in agent preparations when tested by FC and the Lindmo assay. In summary, NIR FC is an alternative with similar specificity and sensitivity, and greater reproducibility relative to the Lindmo assay for quantifying biological activity of NIR fluorophore-labeled, multimodal imaging agents.

Far-red fluorescence gene reporter tomography for determination of placement and viability of cell-based gene therapies.

Non-invasive injectable cellular therapeutic strategies based on sustained delivery of physiological levels of BMP-2 for spinal fusion are emerging as promising alternatives, which could provide sufficient fusion without the associated surgical risks. However, these injectable therapies are dependent on bone formation occurring only at the specific target region. In this study, we developed and deployed fluorescence gene reporter tomography (FGRT) to provide information on in vivo cell localization and viability. This information is sought to confirm the ideal placement of the materials with respect to the area where early bone reaction is required, ultimately providing three dimensional data about the future fusion. However, because almost all conventional fluorescence gene reporters require visible excitation wavelengths, current in vivo imaging of fluorescent proteins is limited by high tissue absorption and confounding autofluorescence. We previously administered fibroblasts engineered to produce BMP-2, but is difficult to determine 3-D information of placement prior to bone formation. Herein we used the far-red fluorescence gene reporter, IFP1.4 to report the position and viability of fibroblasts and developed 3-D tomography to provide placement information. A custom small animal, far-red fluorescence tomography system integrated into a commercial CT scanner was used to assess IFP1.4 fluorescence and to demark 3-D placement of encapsulated fibroblasts with respect to the vertebrae and early bone formation as assessed from CT. The results from three experiments showed that the placement of the materials within the spine could be detected. This work shows that in vivo fluorescence gene reporter tomography of cell-based gene therapy is feasible and could help guide cell-based therapies in preclinical models.

Pre-clinical Validation of Near-Infrared Molecular Imaging Agents and Devices for Intraoperative Guidance

Using a custom-made antibody to target the overexpression of epithelial adhesion molecule (EpCAM), a far-red fluorescent gene reporter, a solid phantom, and a military grade intensified image intensifier, we quantified the performance of near-infrared fluorescence imaging for intraoperative margin detection.

Advancing the Translation of Optical Imaging Agents Through Dual Labeling

Nuclear and near-infrared fluorescence (NIRF) imaging provide non-invasive monitoring of disease. Merging the respective contrast agents through dual labeling could facilitate NIRF validation using proven nuclear imaging methodology while expanding the utility of diagnostic radiotracers.