Intraoperative Pancreatic Cancer Detection using Tumor-Specific Multimodality Molecular Imaging

Tummers, Willemieke S.; Miller, Sarah E.; Teraphongphom, Nutte; Gomez, Adam J.; Steinberg, Idan; Huland, David M.; Hong, Steve; Kothapalli, Sri Rajasekhar; Hasan, Alifia; Ertsey, Robert; Bonsing, Bert A.; Vahrmeijer, Alexander L.; Swijnenburg, Rutger-Jan; Longacre, Teri A.; Fisher, George A.; Gambhir, Sanjiv S.; Poultsides, George A.

doi:10.1245/s10434-018-6453-2

Cited by 135 publications

(119 citation statements)

References 28 publications

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“…As this is the first in-human study using this technology, it was important to establish a baseline of non-specific fluorescence uptake in non-tumor tissue. This methodology has previously been demonstrated in prior publications in a variety of tumor types [16, 17]. A histologically proven tumor specimen that was fluorescent was considered a true-positive; a histologically normal specimen that was fluorescent was a false-positive; a histologically normal specimen that was non-fluorescent was a true-negative; and a histologically positive tumor that was non-fluorescent was a false-negative.…”

Section: Methodsmentioning

confidence: 94%

First-in-human intraoperative near-infrared fluorescence imaging of glioblastoma using cetuximab-IRDye800

et al. 2018

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Introduction Maximizing extent of surgical resection with the least morbidity remains critical for survival in glioblastoma patients, and we hypothesize that it can be improved by enhancements in intraoperative tumor detection. In a clinical study, we determined if therapeutic antibodies could be repurposed for intraoperative imaging during resection. Methods Fluorescently labeled cetuximab-IRDye800 was systemically administered to three patients 2 days prior to surgery. Near-infrared fluorescence imaging of tumor and histologically negative peri-tumoral tissue was performed intraoperatively and ex vivo. Fluorescence was measured as mean fluorescence intensity (MFI), and tumor-to-background ratios (TBRs) were calculated by comparing MFIs of tumor and histologically uninvolved tissue. Results The mean TBR was significantly higher in tumor tissue of contrast-enhancing (CE) tumors on preoperative imaging (4.0 ± 0.5) compared to non-CE tumors (1.2 ± 0.3; p = 0.02). The TBR was higher at a 100 mg dose than at 50 mg (4.3 vs. 3.6). The smallest detectable tumor volume in a closed-field setting was 70 mg with 50 mg of dye and 10 mg with 100 mg. On sections of paraffin embedded tissues, fluorescence positively correlated with histological evidence of tumor. Sensitivity and specificity of tumor fluorescence for viable tumor detection was calculated and fluorescence was found to be highly sensitive (73.0% for 50 mg dose, 98.2% for 100 mg dose) and specific (66.3% for 50 mg dose, 69.8% for 100 mg dose) for viable tumor tissue in CE tumors while normal peri-tumoral tissue showed minimal fluorescence. Conclusion This first-in-human study demonstrates the feasibility and safety of antibody based imaging for CE glioblastomas.

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Section: Methodsmentioning

confidence: 94%

First-in-human intraoperative near-infrared fluorescence imaging of glioblastoma using cetuximab-IRDye800

et al. 2018

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“…In the future, the proposed TUT could be integrated in conventional optical-microscopy techniques to allow multimodal microscopy that is capable of both ultrasound stimulation and sensing. Eventually, the TUT technology could be further scaled to develop miniaturized photoacoustic endomicroscopy and microendoscopy devices for space-constrained point-of-care clinical applications, e.g., prostate and pancreas needle biopsies [35][36][37].…”

Section: Discussionmentioning

confidence: 99%

Optical-Resolution Photoacoustic Microscopy Using Transparent Ultrasound Transducer

Chen

Agrawal

Dangi

et al. 2019

Sensors

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The opacity of conventional ultrasound transducers can impede the miniaturization and workflow of current photoacoustic systems. In particular, optical-resolution photoacoustic microscopy (OR-PAM) requires the coaxial alignment of optical illumination and acoustic-detection paths through complex beam combiners and a thick coupling medium. To overcome these hurdles, we developed a novel OR-PAM method on the basis of our recently reported transparent lithium niobate (LiNbO 3 ) ultrasound transducer (Dangi et al., Optics Letters, 2019), which was centered at 13 MHz ultrasound frequency with 60% photoacoustic bandwidth. To test the feasibility of wearable OR-PAM, optical-only raster scanning of focused light through a transducer was performed while the transducer was fixed above the imaging subject. Imaging experiments on resolution targets and carbon fibers demonstrated a lateral resolution of 8.5 µm. Further, we demonstrated vasculature mapping using chicken embryos and melanoma depth profiling using tissue phantoms. In conclusion, the proposed OR-PAM system using a low-cost transparent LiNbO 3 window transducer has a promising future in wearable and high-throughput imaging applications, e.g., integration with conventional optical microscopy to enable a multimodal microscopy platform capable of ultrasound stimulation.

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“…[115][116][117][118][119][120] Moreover, OTL38, an NIRF agent binding with folate receptor-α has entered Phase III clinical trial stage for patients with ovarian cancer [121] and Phase II clinical trial stage for patients with pulmonary adenocarcinomas. Rosenthal and co-workers devoted a considerable amount of efforts in researching tumor-specific fluorescent probes by conjugating antibodies (e.g., panitumumab, cetuximab, etc.)…”

Section: Fluorescence Imagingmentioning

confidence: 99%

Advanced Nanotechnology Leading the Way to Multimodal Imaging‐Guided Precision Surgical Therapy

et al. 2019

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Surgical resection is the primary and most effective treatment for most patients with solid tumors. However, patients suffer from postoperative recurrence and metastasis. In the past years, emerging nanotechnology has led the way to minimally invasive, precision and intelligent oncological surgery after the rapid development of minimally invasive surgical technology. Advanced nanotechnology in the construction of nanomaterials (NMs) for precision imaging-guided surgery (IGS) as well as surgery-assisted synergistic therapy is summarized, thereby unlocking the advantages of nanotechnology in multimodal IGS-assisted precision synergistic cancer therapy. First, mechanisms and principles of NMs to surgical targets are briefly introduced. Multimodal imaging based on molecular imaging technologies provides a practical method to achieve intraoperative visualization with high resolution and deep tissue penetration. Moreover, multifunctional NMs synergize surgery with adjuvant therapy (e.g., chemotherapy, immunotherapy, phototherapy) to eliminate residual lesions. Finally, key issues in the development of ideal theranostic NMs associated with surgical applications and challenges of clinical transformation are discussed to push forward further development of NMs for multimodal IGS-assisted precision synergistic cancer therapy.

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Intraoperative Pancreatic Cancer Detection using Tumor-Specific Multimodality Molecular Imaging

Cited by 135 publications

References 28 publications

First-in-human intraoperative near-infrared fluorescence imaging of glioblastoma using cetuximab-IRDye800

First-in-human intraoperative near-infrared fluorescence imaging of glioblastoma using cetuximab-IRDye800

Optical-Resolution Photoacoustic Microscopy Using Transparent Ultrasound Transducer

Advanced Nanotechnology Leading the Way to Multimodal Imaging‐Guided Precision Surgical Therapy

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