Your search keyword '"intraoperative molecular imaging"' showing total 31 results

1. Real-world localization of cancer in lungs with a commercially available folate receptor-targeted fluorescent agent for intraoperative molecular imaging

Author

Baker, Nicholas, Alicuben, Evan T., Sarkaria, Inderpal S., Ajabshir, Navid, and Levy, Ryan M.

Published

2025

2. Dual-labeled anti-GD2 targeted probe for intraoperative molecular imaging of neuroblastoma

Author

Lauren Taylor Rosenblum, ReidAnn E. Sever, Ryan Gilbert, David Guerrero, Sarah R. Vincze, Dominic M. Menendez, Peggy A. Birikorang, Mikayla R. Rodgers, Ambika Parmar Jaswal, Alexander C. Vanover, Joseph D. Latoche, Angel G. Cortez, Kathryn E. Day, Lesley M. Foley, Chaim T. Sneiderman, Itay Raphael, T. Kevin Hitchens, Jessie R. Nedrow, Gary Kohanbash, W. Barry Edwards, and Marcus M. Malek

Subjects

Intraoperative molecular imaging, Neuroblastoma, GD2, Radio-guided surgery, Fluorescence guided surgery, Monoclonal antibody, Medicine

Abstract

Abstract Background Surgical resection is integral for the treatment of neuroblastoma, the most common extracranial solid malignancy in children. Safely locating and resecting primary tumor and remote deposits of disease remains a significant challenge, resulting in high rates of complications and incomplete surgery, worsening outcomes. Intraoperative molecular imaging (IMI) uses targeted radioactive or fluorescent tracers to identify and visualize tumors intraoperatively. GD2 was selected as an IMI target, as it is highly overexpressed in neuroblastoma and minimally expressed in normal tissue. Methods GD2 expression in neuroblastoma cell lines was measured by flow cytometry. DTPA and IRDye® 800CW were conjugated to anti-GD2 antibody to generate DTPA-αGD2-IR800. Binding affinity (Kd) of the antibody and the non-radiolabeled tracer were then measured by ELISA assay. Human neuroblastoma SK-N-BE(2) cells were surgically injected into the left adrenal gland of 3.5-5-week-old nude mice and the orthotopic xenograft tumors grew for 5 weeks. 111In-αGD2-IR800 or isotype control tracer was administered via tail vein injection. After 4 and 6 days, mice were euthanized and gamma and fluorescence biodistributions were measured using a gamma counter and ImageJ analysis of acquired SPY-PHI fluorescence images of resected organs (including tumor, contralateral adrenal, kidneys, liver, muscle, blood, and others). Organ uptake was compared by one-way ANOVA (with a separate analysis for each tracer/day combination), and if significant, Sidak’s multiple comparison test was used to compare the uptake of each organ to the tumor. Handheld tools were also used to detect and visualize tumor in situ, and to assess for residual disease following non-guided resection. Results 111In-αGD2-IR800 was successfully synthesized with 0.75-2.0 DTPA and 2–3 IRDye® 800CW per antibody and retained adequate antigen-binding (Kd = 2.39 nM for aGD2 vs. 21.31 nM for DTPA-aGD2-IR800). The anti-GD2 tracer demonstrated antigen-specific uptake in mice with human neuroblastoma xenografts (gamma biodistribution tumor-to-blood ratios of 3.87 and 3.88 on days 4 and 6 with anti-GD2 tracer), while isotype control tracer did not accumulate (0.414 and 0.514 on days 4 and 6). Probe accumulation in xenografts was detected and visualized using widely available operative tools (Neoprobe® and SPY-PHI camera) and facilitated detection ofputative residual disease in the resection cavity following unguided resection. Conclusions We have developed a dual-labeled anti-GD2 antibody-based tracer that incorporates In-111 and IRDye® 800CW for radio- and fluorescence-guided surgery, respectively. The tracer adequately binds to GD2, specifically accumulates in GD2-expressing xenograft tumors, and enables tumor visualization with a hand-held NIR camera. These results encourage the development of 111In-αGD2-IR800 for future use in children with neuroblastoma, with the goal of improving patient safety, completeness of resection, and overall patient outcomes.

Published

2024

3. Dual-labeled anti-GD2 targeted probe for intraoperative molecular imaging of neuroblastoma.

Author

Rosenblum, Lauren Taylor, Sever, ReidAnn E., Gilbert, Ryan, Guerrero, David, Vincze, Sarah R., Menendez, Dominic M., Birikorang, Peggy A., Rodgers, Mikayla R., Jaswal, Ambika Parmar, Vanover, Alexander C., Latoche, Joseph D., Cortez, Angel G., Day, Kathryn E., Foley, Lesley M., Sneiderman, Chaim T., Raphael, Itay, Hitchens, T. Kevin, Nedrow, Jessie R., Kohanbash, Gary, and Edwards, W. Barry

Subjects

RADIOACTIVE tracers, MOLECULAR probes, NEUROBLASTOMA, ADRENAL glands, SURGICAL complications, SURGICAL excision, XENOGRAFTS

Abstract

Background: Surgical resection is integral for the treatment of neuroblastoma, the most common extracranial solid malignancy in children. Safely locating and resecting primary tumor and remote deposits of disease remains a significant challenge, resulting in high rates of complications and incomplete surgery, worsening outcomes. Intraoperative molecular imaging (IMI) uses targeted radioactive or fluorescent tracers to identify and visualize tumors intraoperatively. GD2 was selected as an IMI target, as it is highly overexpressed in neuroblastoma and minimally expressed in normal tissue. Methods: GD2 expression in neuroblastoma cell lines was measured by flow cytometry. DTPA and IRDye® 800CW were conjugated to anti-GD2 antibody to generate DTPA-αGD2-IR800. Binding affinity (Kd) of the antibody and the non-radiolabeled tracer were then measured by ELISA assay. Human neuroblastoma SK-N-BE(2) cells were surgically injected into the left adrenal gland of 3.5-5-week-old nude mice and the orthotopic xenograft tumors grew for 5 weeks. 111In-αGD2-IR800 or isotype control tracer was administered via tail vein injection. After 4 and 6 days, mice were euthanized and gamma and fluorescence biodistributions were measured using a gamma counter and ImageJ analysis of acquired SPY-PHI fluorescence images of resected organs (including tumor, contralateral adrenal, kidneys, liver, muscle, blood, and others). Organ uptake was compared by one-way ANOVA (with a separate analysis for each tracer/day combination), and if significant, Sidak's multiple comparison test was used to compare the uptake of each organ to the tumor. Handheld tools were also used to detect and visualize tumor in situ, and to assess for residual disease following non-guided resection. Results: 111In-αGD2-IR800 was successfully synthesized with 0.75-2.0 DTPA and 2–3 IRDye® 800CW per antibody and retained adequate antigen-binding (Kd = 2.39 nM for aGD2 vs. 21.31 nM for DTPA-aGD2-IR800). The anti-GD2 tracer demonstrated antigen-specific uptake in mice with human neuroblastoma xenografts (gamma biodistribution tumor-to-blood ratios of 3.87 and 3.88 on days 4 and 6 with anti-GD2 tracer), while isotype control tracer did not accumulate (0.414 and 0.514 on days 4 and 6). Probe accumulation in xenografts was detected and visualized using widely available operative tools (Neoprobe® and SPY-PHI camera) and facilitated detection ofputative residual disease in the resection cavity following unguided resection. Conclusions: We have developed a dual-labeled anti-GD2 antibody-based tracer that incorporates In-111 and IRDye® 800CW for radio- and fluorescence-guided surgery, respectively. The tracer adequately binds to GD2, specifically accumulates in GD2-expressing xenograft tumors, and enables tumor visualization with a hand-held NIR camera. These results encourage the development of 111In-αGD2-IR800 for future use in children with neuroblastoma, with the goal of improving patient safety, completeness of resection, and overall patient outcomes. [ABSTRACT FROM AUTHOR]

Published

2024

4. Mucins as contrast agent targets for fluorescence-guided surgery of pancreatic cancer.

Author

Muilenburg, Kathryn, Isder, Carly, Radhakrishnan, Prakash, Batra, Surinder, Ly, Quan, Carlson, Mark, Bouvet, Michael, Hollingsworth, Michael, and Mohs, Aaron

Subjects

Biomarkers, Fluorescence, Intraoperative molecular imaging, Mucins, Optical surgical navigation, Humans, Contrast Media, Fluorescence, Mucins, Pancreatic Neoplasms, Surgery, Computer-Assisted, Proteins, Optical Imaging

Abstract

Pancreatic cancer is difficult to resect due to its unique challenges, often leading to incomplete tumor resections. Fluorescence-guided surgery (FGS), also known as intraoperative molecular imaging and optical surgical navigation, is an intraoperative tool that can aid surgeons in complete tumor resection through an increased ability to detect the tumor. To target the tumor, FGS contrast agents rely on biomarkers aberrantly expressed in malignant tissue compared to normal tissue. These biomarkers allow clinicians to identify the tumor and its stage before surgical resection and provide a contrast agent target for intraoperative imaging. Mucins, a family of glycoproteins, are upregulated in malignant tissue compared to normal tissue. Therefore, these proteins may serve as biomarkers for surgical resection. Intraoperative imaging of mucin expression in pancreatic cancer can potentially increase the number of complete resections. While some mucins have been studied for FGS, the potential ability to function as a biomarker target extends to the entire mucin family. Therefore, mucins are attractive proteins to investigate more broadly as FGS biomarkers. This review summarizes the biomarker traits of mucins and their potential use in FGS for pancreatic cancer.

Published

2023

5. Intraoperative molecular imaging: 3rd biennial clinical trials update

Author

Bou-Samra, Patrick, Muhammad, Najib, Chang, Austin, Karsalia, Ritesh, Azari, Feredun, Kennedy, Gregory, Stummer, Walter, Tanyi, Janos, Martin, Linda, Vahrmeijer, Alexander, Smith, Barbara, Rosenthal, Eben, Wagner, Patrick, Rice, David, Lee, Amy, Abdelhafeez, Abdelhafeez, Malek, Marcus M, Kohanbash, Gary, Edwards, Wilson Barry, Henderson, Eric, Skjøth-Rasmussen, Jane, Orosco, Ryan, Gibbs, Summer, Farnam, Richard W, Shankar, Lalitha, Sumer, Baran, Kumar, Anand TN, Marcu, Laura, Li, Lei, Greuv, Victor, Delikatny, Edward J, Lee, John YK, and Singhal, Sunil

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Clinical Trials and Supportive Activities, Clinical Research, Cancer, Humans, Child, Neoplasms, Contrast Media, Molecular Imaging, Coloring Agents, intraoperative molecular imaging, contrast agents, clinically significant events, precision surgery, Optical Physics, Biomedical Engineering, Opthalmology and Optometry, Optics, Ophthalmology and optometry, Biomedical engineering, Atomic, molecular and optical physics

Abstract

SignificanceThis third biennial intraoperative molecular imaging (IMI) conference shows how optical contrast agents have been applied to develop clinically significant endpoints that improve precision cancer surgery.AimNational and international experts on IMI presented ongoing clinical trials in cancer surgery and preclinical work. Previously known dyes (with broader applications), new dyes, novel nonfluorescence-based imaging techniques, pediatric dyes, and normal tissue dyes were discussed.ApproachPrincipal investigators presenting at the Perelman School of Medicine Abramson Cancer Center's third clinical trials update on IMI were selected to discuss their clinical trials and endpoints.ResultsDyes that are FDA-approved or currently under clinical investigation in phase 1, 2, and 3 trials were discussed. Sections on how to move benchwork research to the bedside were also included. There was also a dedicated section for pediatric dyes and nonfluorescence-based dyes that have been newly developed.ConclusionsIMI is a valuable adjunct in precision cancer surgery and has broad applications in multiple subspecialties. It has been reliably used to alter the surgical course of patients and in clinical decision making. There remain gaps in the utilization of IMI in certain subspecialties and potential for developing newer and improved dyes and imaging techniques.

Published

2023

6. New EAU/ASCO guideline recommendations on sentinel node biopsy for penile cancer and remaining challenges from a nuclear medicine perspective.

Author

Vreeburg, Manon T. A., Donswijk, Maarten L., Albersen, Maarten, Parnham, Arie, Ayres, Benjamin, Protzel, Chris, Pettaway, Curtis, Spiess, Philippe E., and Brouwer, Oscar R.

Subjects

*SINGLE-photon emission computed tomography, *PENILE cancer, *CLINICAL medicine, *SENTINEL lymph nodes, *LYMPHADENECTOMY

Abstract

Introduction: The European Association of Urology (EAU) and the American Society of Clinical Oncology (ASCO) recently issued updated guidelines on penile cancer, emphasising dynamic sentinel node biopsy (DSNB) as the preferred method for surgical staging among patients with invasive penile tumours and no palpable inguinal lymphadenopathy. This paper outlines the rationale behind this new recommendation and describes remaining challenges, as well as strategies for promoting DSNB worldwide. Main text: DSNB offers high diagnostic accuracy with the lowest postoperative complications compared to open or minimally invasive inguinal lymph node dissection (ILND), prompting its preference in the new guidelines. Nevertheless, despite its advantages, there are challenges hampering the widespread adoption of DSNB. This includes the false-negative rate associated with DSNB and the potential negative impact on patient outcome. To address this issue, improvements should be made in several areas, including refining the timing and interpretation of the lymphoscintigraphy and the single photon emission computed tomography/computed tomography images. In addition, the quantity of tracer employed and choice of the injection site for the radiopharmaceutical should be optimised. Finally, limiting the removal of nodes without tracer activity during surgery may help minimise complication rates. Conclusion: Over the years, DSNB has evolved significantly, related to the dedicated efforts and innovations in nuclear medicine and subsequent clinical studies validating its efficacy. It is now strongly recommended for surgical staging among selected penile cancer patients. To optimise DSNB further, multidisciplinary collaborative research is required to improve SN identification for better diagnostic accuracy and fewer complications. [ABSTRACT FROM AUTHOR]

Published

2024

7. Setting-up a training programme for intraoperative molecular imaging and sentinel node mapping: how to teach? How to learn?

Author

Valdés Olmos, Renato A., Collarino, Angela, Rietbergen, Daphne D. D., Pereira Arias-Bouda, Lenka, Giammarile, Francesco, and Vidal-Sicart, Sergi

Subjects

*SENTINEL lymph nodes, *COMPUTER-assisted surgery, *COMPUTER software developers, *MULTIDISCIPLINARY practices, *CLINICAL medicine

Abstract

Background: The current expansion of image-guided surgery is closely related to the role played by radio-guided surgery in supporting the sentinel node (SN) procedure during more than three decades. The so-called triple approach (lymphoscintigraphy, gamma probe detection and blue dye) was not only essential in the seminal validation of the SN procedure but also a first collective learning effort based on skill transfer and outcome-related evaluation which laid the fundaments to delineate the field of intraoperative molecular imaging (IMI) based on a similar multimodality approach and multidisciplinary practice. Methods: These elements are also becoming valid in the current incorporation of SPECT/CT and PET/CT to existing and new protocols of IMI procedures and SN mapping concerning other clinical applications. On the other hand, there is a growing tendency to combine novel modern technologies in an allied role with gamma guidance in the operating room following the development of hybrid tracers and multimodal detection approaches. Against this background, learning initiatives are required for professionals working in this area. Results: This objective has led to a group of European practitioners with large experience in SN mapping and IMI applications to give shape to a programme made up out of specific learning modules aimed to be used as a conductive thread in peripherical or centralised training instances concerning the topic. Conclusion: The presented work, written as a tutorial review, is placed in an available prior-art context and is primarily aimed at medical and paramedical practitioners as well as at hardware and software developers. [ABSTRACT FROM AUTHOR]

Published

2024

8. A Phase 2 Multicenter Clinical Trial of Intraoperative Molecular Imaging of Lung Cancer with a pH-Activatable Nanoprobe.

Author

Kennedy, Gregory T., Azari, Feredun S., Chang, Austin, Bou-Samra, Patrick, Desphande, Charuhas, Predina, Jarrod, Delikatny, Edward J., Olson, Madeline, Rice, David C., and Singhal, Sunil

Subjects

*LUNGS, *LUNG cancer, *SURGICAL margin, *CLINICAL trials, *LUNG tumors, *INTRAVENOUS therapy

Abstract

Purpose: Intraoperative molecular imaging (IMI) uses tumor-targeted optical contrast agents to improve identification and clearance of cancer. Recently, a probe has been developed that only fluoresces when activated in an acidic pH, which is common to many malignancies. We report the first multicenter Phase 2 trial of a pH-activatable nanoprobe (pegsitacianine, ONM-100) for IMI of lung cancer. Methods: Patients with suspected or biopsy-confirmed lung cancer scheduled for sublobar resection were administered a single intravenous infusion of pegsitacianine (1 mg/kg) one to three days prior to surgery. Intraoperatively, the patients underwent a white light thoracoscopic evaluation, and then were imaged with an NIR thoracoscope to detect tumor fluorescence. The primary study endpoint was the proportion of patients with a clinically significant event (CSE) which was defined as an intraoperative discovery during IMI that led to a change in the surgical procedure. Possible CSEs included (i) localizing the index lung nodule that could not be located by white light, (ii) identifying a synchronous malignant lesion, or (iii) recognizing a close surgical margin (< = 10 mm). Secondary endpoints were sensitivity, specificity, NPV, and PPV of pegsitacianine in detecting tumor-containing tissue. The safety evaluation was based on adverse event reporting, clinical laboratory parameters, and physical examinations. Results: Twenty patients were confirmed as eligible and administered pegsitacianine. Most of the patients were female (n = 12 [60%]), middle-aged (mean age 63.4 years), and former smokers (n = 13 [65%], 28.6 mean pack years). Mean lesion size was 1.9 cm, and most lesions (n = 17 [85%]) were malignant. The most common histologic subtype was adenocarcinoma (n = 9). By utilizing IMI with pegsitacianine, one patient had a CSE in the detection of a close margin and another had localization of a tumor not detectable by traditional surgical means. Six of 19 (31.6%) malignant lesions fluoresced with mean tumor-to-background ratio (TBR) of 3.00, as compared to TBR of 1.20 for benign lesions (n = 3). Sensitivity and specificity of pegsitacianine-based IMI for detecting malignant tissue was 31.6% and 33.3%, respectively. Positive predictive value (PPV) and negative predictive value (NPV) of pegsitacianine-based IMI was 75% and 7.1%, respectively. Pegsitacianine-based imaging was not effective in differentiating benign and malignant lymph nodes. From a safety perspective, no drug-related serious adverse events occurred. Four patients experienced mild pegsitacianine-related infusion reactions which required discontinuing the study drug with complete resolution of symptoms. Conclusions: Pegsitacianine-based IMI, though well tolerated from a safety perspective, does not consistently label lung tumors during resection and does not provide significant clinical benefit over existing standards of surgical care. The biology of lung tumors may not be as acidic as other solid tumors in the body thereby not activating the probe as predicted. [ABSTRACT FROM AUTHOR]

Published

2024

9. Preoperative predictors of successful tumour localization by intraoperative molecular imaging with pafolacianine in lung cancer to create predictive nomogram.

Author

Bou-Samra, Patrick, Joffe, Jonah, Chang, Austin, Guo, Emily, Segil, Alix, Azari, Feredun, Kennedy, Gregory, Din, Azra, Hwang, Wei-Ting, and Singhal, Sunil

Subjects

*NOMOGRAPHY (Mathematics), *RECEIVER operating characteristic curves, *LUNG cancer, *POSITRON emission tomography, *LUNG diseases

Abstract

Open in new tab Download slide OBJECTIVES Intraoperative molecular imaging (IMI) uses cancer-targeted fluorescent probe to locate nodules. Pafolacianine is a Food and Drug Administration-approved fluorescent probe for lung cancer. However, it has a 8–12% false negative rate for localization. Our goal is to define preoperative predictors of tumour localization by IMI. METHODS We performed a retrospective review of patients who underwent IMI using pafolacianine for lung lesions from June 2015 to August 2019. Candidate predictors including sex, age, body mass index, smoking history, tumour size, distance of tumour from surface, use of neoadjuvant therapy and positron emission tomography avidity were included. The outcome was fluorescence in vivo and comprehensively included those who were true or false positives negatives. Multiple imputation was used to handle the missing data. The final model was evaluated using the area under the receiver operating characteristic curve. RESULTS Three hundred nine patients were included in our study. The mean age was 64 (standard deviation 13) and 68% had a smoking history. The mean distance of the tumours from the pleural surface was 0.4 cm (standard deviation 0.6). Smoking in pack-years and distance from pleura had an odds ratio of 0.99 [95% confidence interval: 0.98–0.99; P  = 0.03] and 0.46 [95% confidence interval: 0.27–0.78; P  = 0.004], respectively. The final model had an area under the receiver operating characteristic curve of 0.68 and was used to create a nomogram that gives a probability of fluorescence in vivo. CONCLUSIONS Primary tumours that are deeper from the pleural surface, especially in patients with a higher pack-years, are associated with a decreased likelihood of intraoperative localization. We identified a nomogram to predict the likelihood of tumour localization with IMI with pafolacianine. [ABSTRACT FROM AUTHOR]

Published

2024

10. Novel intraoperative near-infrared imaging strategy to identify abnormalities in the anterior mediastinum

Author

Sonia Singhal, Feredun Azari, Gabriel C. Caponetti, and Gregory T. Kennedy

Subjects

Mediastinum, Lymph node, Staging, Intraoperative molecular imaging, Surgery, RD1-811, Anesthesiology, RD78.3-87.3

Abstract

Abstract Thoracic surgeons are frequently asked to biopsy suspicious tissues in the anterior mediastinum to discriminate between a reactive versus malignant pathology such as lymph nodes. The most common benign cause of a mediastinal lymph node is a reactive lymph node from a prior infection or inflammatory process such as post-COVID or granulomatous disease. The most common malignant cause is a lymphoproliferative disorder but also metastatic disease from neck, breast and other regional cancers. Biopsies in this location are challenging because they are far from the trachea and the sternum is a barrier to most diagnostic procedures. Thus, a surgical biopsy is frequently required and a common procedure for Thoracic surgeons. Technically, identifying these lesions can be challenging, particularly for small lesions or those in patients with high body mass index. In order to improve contrast between diseased tissue in the anterior mediastinum and surrounding adipose tissue, we have been studying near-infrared imaging during surgery using indocyanine green (ICG) to give contrast to the abnormal tissues and to avoid an unnecessary extended resection. We developed a modified technique to give ICG to a patient during a biopsy in the anterior mediastinum to specifically highlight abnormal tissues. As a proof-of-principle, we present a case of a young woman with a suspicious 2 cm mediastinal lymph node that required surgical biopsy.

Published

2022

11. Prospective validation of tumor folate receptor expression density with the association of pafolacianine fluorescence during intraoperative molecular imaging–guided lung cancer resections.

Author

Azari, Feredun, Zhang, Kevin, Kennedy, Gregory, Bou-Samra, Patrick, Chang, Ashley, Nadeem, Bilal, Chang, Austin, Galandarova, Aysuna, Ibrahimli, Arturan, Karimov, Ziya, Din, Azra, Kucharczuk, John, Doraid, Jarrar, Pechet, Taine, Delikatny, Edward, and Singhal, Sunil

Subjects

*LUNG cancer, *ONCOLOGIC surgery, *FLUORESCENCE, *PATIENT selection, *FOLIC acid, *BENIGN tumors

Abstract

Purpose: Pafolacianine, a folate receptor alpha-targeted NIR tracer, has demonstrated clear efficacy in intraoperative molecular imaging–guided (IMI) lung cancer surgery. However, the selection of patients who would benefit from IMI remains challenging given the variability of fluorescence with patient-associated and histopathologic factors. Our goal in this study was to prospectively evaluate whether preoperative FRα/FRβ staining can predict pafolacianine-based fluorescence during real-time lung cancer resections. Methods: This was a prospective study conducted between 2018 and 2022 that reviewed core biopsy and intraoperative data from patients with suspected lung cancer. A total of 196 patients were deemed eligible, of whom core biopsies were taken from 38 patients and assessed for FRα and FRβ expression by immunohistochemistry (IHC). All patients underwent infusion of pafolacianine 24 h prior to surgery. Intraoperative fluorescence images were captured with the VisionSense bandpass filter–enabled camera. All histopathologic assessments were performed by a board-certified thoracic pathologist. Results: Of the 38 patients, 5 (13.1%) were found to have benign lesions (necrotizing granulomatous inflammation, lymphoid aggregates) and 1 had metastatic non-lung nodule. Thirty (81.5%) had malignant lesions, with the vast majority (23, 77.4%) being lung adenocarcinoma (7 (22.5%) SCC). None of the benign tumors (0/5, 0%) exhibited in vivo fluorescence (mean TBR of 1.72), while 95% of the malignant tumors fluoresced (mean TBR of 3.11 ± 0.31) compared to squamous cell carcinoma (1.89 ± 0.29) of the lung and sarcomatous lung metastasis (2.32 ± 0.09) (p < 0.01). The TBR was significantly higher in the malignant tumors (p = 0.009). The median FRα and FRβ staining intensities were both 1.5 for benign tumors, while the FRα and FRβ staining intensities were 3 and 2 for malignant tumors, respectively. Increased FRα expression was significantly associated with the presence of fluorescence (p = 0.01), Conclusion: This prospective study sought to determine whether preoperative FRα and FRβ expression on core biopsy IHC correlates with intraoperative fluorescence during pafolacianine-guided surgery. These results, although of small sample size, including limited non-adenocarcinoma cohort, suggest that performing FRα IHC on preoperative core biopsies of adenocarcinomas as compared to squamous cell carcinomas could provide low-cost, clinically useful information for optimal patient selection which should be further explored in advanced clinical trials. [ABSTRACT FROM AUTHOR]

Published

2023

12. The current status and future prospects for molecular imaging-guided precision surgery

Author

Imke Boekestijn, Matthias N. van Oosterom, Paolo Dell’Oglio, Floris H. P. van Velden, Martin Pool, Tobias Maurer, Daphne D. D. Rietbergen, Tessa Buckle, and Fijs W. B. van Leeuwen

Subjects

Image-guided therapy, Intraoperative molecular imaging, Surgery, Fluorescence imaging, Multimodal imaging, Digital surgery, Medical physics. Medical radiology. Nuclear medicine, R895-920, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Molecular imaging technologies are increasingly used to diagnose, monitor, and guide treatment of i.e., cancer. In this review, the current status and future prospects of the use of molecular imaging as an instrument to help realize precision surgery is addressed with focus on the main components that form the conceptual basis of intraoperative molecular imaging. Paramount for successful interventions is the relevance and accessibility of surgical targets. In addition, selection of the correct combination of imaging agents and modalities is critical to visualize both microscopic and bulk disease sites with high affinity and specificity. In this context developments within engineering/imaging physics continue to drive the growth of image-guided surgery. Particularly important herein is enhancement of sensitivity through improved contrast and spatial resolution, features that are critical if sites of cancer involvement are not to be overlooked during surgery. By facilitating the connection between surgical planning and surgical execution, digital surgery technologies such as computer-aided visualization nicely complement these technologies. The complexity of image guidance, combined with the plurality of technologies that are becoming available, also drives the need for evaluation mechanisms that can objectively score the impact that technologies exert on the performance of healthcare professionals and outcome improvement for patients.

Published

2022

13. Three-Dimensional Near-Infrared Specimen Mapping Can Identify the Distance from the Tumor to the Surgical Margin During Resection of Pulmonary Ground Glass Opacities.

Author

Kennedy, Gregory T., Azari, Feredun S., Bernstein, Elizabeth, Deshpande, Charuhas, Kucharczuk, John C., Delikatny, Edward J., and Singhal, Sunil

Subjects

*OPACITY (Optics), *SURGICAL excision, *FLUORESCENCE, *LUNGS, TUMOR surgery

Abstract

Background: Lung cancers can recur locally due to inadequate resection margins. Achieving adequate margin distances is challenging in pulmonary ground glass opacities (GGOs) because they are not easily palpable. To improve margin assessment during resection of GGOs, we propose a novel technique, three-dimensional near-infrared specimen mapping (3D-NSM). Methods: Twenty patients with a cT1 GGO were enrolled and received a fluorescent tracer preoperatively. After resection, specimens underwent 3D-NSM in the operating room. Margins were graded as positive or negative based upon fluorescence at the staple line. Images were analyzed using ImageJ to quantify the distance from the tumor edge to the nearest staple line. This margin distance calculated by 3D-NSM was compared to the margin distance reported on final pathology several days postoperatively. Results: 3D-NSM identified 20/20 GGOs with no false positive or false negative diagnoses. Mean fluorescence intensity for lesions was 110.92 arbitrary units (A.U.) (IQR: 77.77–122.03 A.U.) compared to 23.68 A.U. (IQR: 19.60–27.06 A.U.) for background lung parenchyma (p < 0.0001). There were 4 tumor-positive or close margins in the study cohort, and all 4 (100%) were identified by 3D-NSM. 3D-NSM margin distances were nearly identical to margin distances reported on final pathology (R2 = 0.9362). 3D-NSM slightly under-predicted margin distance, and the median difference in margins was 1.9 mm (IQR 0.5–4.3 mm). Conclusions: 3D-NSM rapidly localizes GGOs by fluorescence and detects tumor-positive or close surgical margins. 3D-NSM can accurately quantify the resection margin distance as compared to formal pathology, which allows surgeons to rapidly determine whether sublobar resection margin distances are adequate. [ABSTRACT FROM AUTHOR]

Published

2023

14. Effects of Light-absorbing Carbons in Intraoperative Molecular Imaging–Guided Lung Cancer Resections.

Author

Azari, Feredun, Kennedy, Gregory, Zhang, Kevin, Bernstein, Elizabeth, Chang, Ashley, Nadeem, Bilal, Segil, Alix, Desphande, Charuhas, Delikatny, James, Kucharczuk, John, and Singhal, Sunil

Subjects

*LUNG cancer, *ONCOLOGIC surgery, *LIGHT absorption, *MOLECULAR diagnosis, *INTRAOPERATIVE monitoring

Abstract

Background: One of the novel advancements to enhance the visual aspects of lung cancer identification is intraoperative molecular imaging (IMI), which can reliably detect tumors that would otherwise be missed by standard techniques such as tactile and visual feedback, particularly for sub-centimeter or ground-glass nodules. However, there remains a subset of patients who do not benefit from IMI due to excessive background fluorescence secondary to parenchymal light-absorbing carbon deposition. Our goal was to identify the effects of these carbonaceous materials on the quality of IMI-guided lung cancer resections. Study Design and Methods: Between July 2014 and May 2021, a total of 311 patients were included in the study. Patients underwent infusion of the study drug OTL38 or ICG up to 24 h prior to VATS for lung cancer. Several factors such as age, tumor subtype, PET SUV, smoking, demographics, chronic lung conditions, patient domicile, and anthracosis were analyzed with respect to lung fluorescence during IMI. P values < 0.05 were considered statistically significant. Results: Variables such as age, sex, and race had no statistical correlation to IMI success. However, smoking status and pack year had a statistically significant correlation with background parenchymal fluorescence and lung inflammation (p < 0.05). MFI of background (lung parenchyma) correlated with smoking history (p < 0.05) which led to decreased tumor-to-background ratio (TBR) measurements for all patients with proven malignancy (p < 0.05). Patients with chronic lung disease appear to have increased background parenchymal fluorescence regardless of smoking history (287 vs. 154, p < 0.01). City dwellers compared to other groups appear to be exposed to higher pollutant load and have higher rates of anthracosis, but living location's impact on fluorescence quantification appears to be not statistically significant. Conclusion: Smokers with greater than 10 PPY and those with chronic lung disease appear to have decreased lesion-to-background discrimination, significant anthracosis, and reduced IMI efficacy secondary to light-absorbing carbon deposition. [ABSTRACT FROM AUTHOR]

Published

2023

15. Evaluation of OTL38-Generated Tumor-to-Background Ratio in Intraoperative Molecular Imaging-Guided Lung Cancer Resections.

Author

Azari, Feredun, Kennedy, Gregory, Bernstein, Elizabeth, Delikatny, James, Lee, John Y.K., Kucharczuk, John, Low, Phil S., and Singhal, Sunil

Subjects

*SURGICAL excision, *INTRAOPERATIVE monitoring, *LUNG cancer, *DIAGNOSTIC imaging, *TUMORS

Abstract

Introduction: Cancer surgery has multiple challenges including localizing small lesions, ensuring negative margins, and identifying synchronous cancers. One of the tools proposed to address these issues is intraoperative molecular imaging (IMI). An important consideration in IMI is the quantification of the tumor fluorescence during the procedure and using that data to add clinical value. Currently, the most commonly cited measure of quantification is the tumor-to-background ratio (TBR). Our goal was to evaluate the clinical value of TBR measured with OTL38 NIR tracer during a lung cancer resection. Methods: Intraoperative data was retrospectively reviewed from a prospectively collected 5-year database. Between 2015 and 2020, 279 patients were included in the study. For standardization, all patients underwent infusion of the same targeted molecular optical contrast agent (OTL38) for lung cancer resections; then, the mean fluorescence intensity of the tumors and background tissues were calculated. To evaluate the clinical efficacy of the TBR calculation, the results were correlated with patient, biologic, tumor, and technological factors. Results: For pulmonary surgery, patient factors such as gender, age, smoking history, and time from infusion of OTL38 to surgery did not have any statistical significance in predicting the TBR during surgery. In addition, TBR measurements did not correlate with location of the tumor in the lung (p = 0.123). There was no statistical correlation of preoperative positron emission tomography measurements (standardized uptake value) with intraoperative TBR. However, there was statistically significant negative correlation of in situ TBR measurement and the distance of the lesion from the surface of the organ (p < 0.001). Adenocarcinoma spectrum lesions overall had statistically significant correlation with in situ fluorescence compared to other NSCLC malignancies (p < 0.01) but TBR measurements could not identify histopathologic subtype on univariate analysis (p = 0.089). There was a tendency for in situ fluorescence for moderately and well-differentiated adenocarcinoma spectrum lesions, but this was not statistically significant. When comparing the in situ TBR of benign to malignant nodules in the lung, there was no statistically significant association (p = 0.145). In subset analysis, adenocarcinoma spectrum lesions tend to fluoresce at brighter with OTL38 compared to other histologic subtypes. Conclusion: In our various iterations, the results of our retrospective analysis did not show that TBR measurements during OTL38-guided surgery provide clinically useful information about the nature of the nodule or cancer. The true value of IMI is in the ability for the surgeon to use the fluorescence to guide the surgeon to the tumor and margins, but that sophisticated quantification of the amount of fluorescence may not have clinical utility. [ABSTRACT FROM AUTHOR]

Published

2023

16. Novel intraoperative near-infrared imaging strategy to identify abnormalities in the anterior mediastinum.

Author

Singhal, Sonia, Azari, Feredun, Caponetti, Gabriel C., and Kennedy, Gregory T.

Subjects

MEDIASTINUM, HEAD & neck cancer, LYMPH nodes, INFLAMMATION, BODY mass index, HUMAN abnormalities

Abstract

Thoracic surgeons are frequently asked to biopsy suspicious tissues in the anterior mediastinum to discriminate between a reactive versus malignant pathology such as lymph nodes. The most common benign cause of a mediastinal lymph node is a reactive lymph node from a prior infection or inflammatory process such as post-COVID or granulomatous disease. The most common malignant cause is a lymphoproliferative disorder but also metastatic disease from neck, breast and other regional cancers. Biopsies in this location are challenging because they are far from the trachea and the sternum is a barrier to most diagnostic procedures. Thus, a surgical biopsy is frequently required and a common procedure for Thoracic surgeons. Technically, identifying these lesions can be challenging, particularly for small lesions or those in patients with high body mass index. In order to improve contrast between diseased tissue in the anterior mediastinum and surrounding adipose tissue, we have been studying near-infrared imaging during surgery using indocyanine green (ICG) to give contrast to the abnormal tissues and to avoid an unnecessary extended resection. We developed a modified technique to give ICG to a patient during a biopsy in the anterior mediastinum to specifically highlight abnormal tissues. As a proof-of-principle, we present a case of a young woman with a suspicious 2 cm mediastinal lymph node that required surgical biopsy. [ABSTRACT FROM AUTHOR]

Published

2022

17. Detection properties of indium-111 and IRDye800CW for intraoperative molecular imaging use across tissue phantom models.

Author

Sever RE, Rosenblum LT, Stanley KC, Cortez AG, Menendez DM, Chagantipati B, Nedrow JR, Edwards WB, Malek MM, and Kohanbash G

Subjects

Swine, Animals, Fluorescent Dyes chemistry, Gelatin chemistry, Neoplasms diagnostic imaging, Neoplasms surgery, Optical Imaging methods, Optical Imaging instrumentation, Benzenesulfonates, Phantoms, Imaging, Molecular Imaging methods, Molecular Imaging instrumentation, Indium Radioisotopes, Indoles chemistry

Abstract

Significance: Intraoperative molecular imaging (IMI) enables the detection and visualization of cancer tissue using targeted radioactive or fluorescent tracers. While IMI research has rapidly expanded, including the recent Food and Drug Administration approval of a targeted fluorophore, the limits of detection have not been well-defined., Aim: The ability of widely available handheld intraoperative tools (Neoprobe and SPY-PHI) to measure gamma decay and fluorescence intensity from IMI tracers was assessed while varying characteristics of both the signal source and the intervening tissue or gelatin phantoms., Approach: Gamma decay signal and fluorescence from tracer-bearing tumors (TBTs) and modifiable tumor-like inclusions (TLIs) were measured through increasing thicknesses of porcine tissue and gelatin in custom 3D-printed molds. TBTs buried beneath porcine tissue were used to simulate IMI-guided tumor resection., Results: Gamma decay from TBTs and TLIs was detected through significantly thicker tissue and gelatin than fluorescence, with at least 5% of the maximum signal observed through up to 5 and 0.5 cm, respectively, depending on the overlying tissue type or gelatin., Conclusions: We developed novel systems that can be fine-tuned to simulate variable tumor characteristics and tissue environments. These were used to evaluate the detection of fluorescent and gamma signals from IMI tracers and simulate IMI surgery., (© 2024 The Authors.)

Published

2025

18. Presence of non-Newtonian fluid in invasive pulmonary mucinous adenocarcinomas impacts fluorescence during intraoperative molecular imaging of lung cancer.

Author

Azari, Feredun, Kennedy, Gregory, Chang, Ashley, Nadeem, Bilal, Sullivan, Neil, Marfatia, Isvita, Din, Azra, Desphande, Charuhas, Kucharczuk, John, Delikatny, Edward J., and Singhal, Sunil

Subjects

*MUCINOUS adenocarcinoma, *NON-Newtonian fluids, *MOLECULAR diagnosis, *LUNG cancer, *COMPUTER-assisted surgery

Abstract

Background: Intraoperative molecular imaging (IMI) with folate-targeted NIR tracers has been shown to improve lesion localization in more than 80% of lung adenocarcinomas. However, mucinous adenocarcinomas (MAs) and invasive mucinous adenocarcinomas (IMAs) of the lung, which are variants of adenocarcinoma, appear to have decreased fluorescence despite appropriate folate receptor expression on the tumor surface. We hypothesized that the etiology may be related to light excitation and emission through non-Newtonian fluid (mucin) produced by goblet and columnar cancer cells. Methods: Intraoperative data for 311 subjects were retrospectively reviewed from a prospectively collected 6-year database. For standardization, all patients underwent infusion of the same targeted molecular optical contrast agent (pafolacianine, folate receptor-targeted NIR fluorochrome) for lung cancer resections. Then, the ratio of the mean fluorescence intensity of the tumors and background tissues (TBR) was calculated. Tumors were examined for mucin, FRa, FRb, and immunofluorescent tracer uptake by a board-certified pathologist. The optical properties of mucin analyzed by imaging software were used to create in vitro gel models to explore the effects on NIR tracer fluorescence intensity. Results: A large proportion (192, 62%) of the patients were female, with an average of 62.8 years and a 34-year mean pack smoking history. There were no severe (Clavien–Dindo > III) complications related to pafolacianine infusion. A total of 195 lesions in the study were adenocarcinomas, of which 19 (6.1%) were of the mucinous subtype. A total of 14/19 of the patients had a smoking history, and more than 74% of the IMA lesions were in the lower lobes. IMA lesions had a lower in situ TBR than nonmucinous adenocarcinomas (2.64 SD 0.23) vs (3.45 SD 0.11), respectively (p < 0.05). Only 9/19 (47%) were localized in situ. Tumor bisection and removal of mucin from IMAs significantly increased pafolacianine fluorescence, with resultant TBR not being significantly different from the control group (4.67 vs 4.89) (p = 0.19). Of the 16 lesions that underwent FR expression analysis, 15/16 had FR presence on cancer cells or tumor-associated macrophages in the tumor microenvironment. There was no statistically significant difference in fluorescence intensity during immunofluorescence analysis (4.99 vs 5.08) (p = 0.16). Physical removal of mucin from IMAs improved the TBR from 3.11 to 4.67 (p < 0.05). In vitro analysis of the impact of synthetic non-Newtonian fluid (agarose 0.5%) on NIR tracer fluorescence showed a decrease in MFI by a factor of 0.25 regardless of the concentration for each 5 mm thickness of mucin. Conclusion: The mucinous subtype of lung adenocarcinomas presents a unique challenge in pafolacianine-targeted IMI-guided resections. The presence of non-Newtonian fluids presents a physical barrier that dampens the excitation of the tracer and fluorescence emission detected by the camera. Knowledge of this phenomenon can allow the surgeon to critically analyze lesion fluorescence parameters during IMI-guided lung cancer resections. [ABSTRACT FROM AUTHOR]

Published

2022

19. Comparative Experience of Short-wavelength Versus Long-wavelength Fluorophores for Intraoperative Molecular Imaging of Lung Cancer.

Author

Kennedy, Gregory T., Azari, Feredun S., Chang, Ashley, Nadeem, Bilal, Bernstein, Elizabeth, Segil, Alix, Din, Azra, Marfatia, Isvita, Desphande, Charuhas, Okusanya, Olugbenga, Keating, Jane, Predina, Jarrod, Newton, Andrew, Kucharczuk, John C., and Singhal, Sunil

Abstract

Background: Intraoperative molecular imaging (IMI) using tumor-targeted optical contrast agents can improve cancer resections. The optimal wavelength of the IMI tracer fluorophore has never been studied in humans and has major implications for the field. To address this question, we investigated 2 spectroscopically distinct fluorophores conjugated to the same targeting ligand. Methods: Between December 2011 and November 2021, patients with primary lung cancer were preoperatively infused with 1 of 2 folate receptor-targeted contrast tracers: a short-wavelength folate-fluorescein (EC17; λem=520 nm) or a long-wavelength folate-S0456 (pafolacianine; λem=793 nm). During resection, IMI was utilized to identify pulmonary nodules and confirm margins. Demographic data, lesion diagnoses, and fluorescence data were collected prospectively. Results: Two hundred eighty-two patients underwent resection of primary lung cancers with either folate-fluorescein (n=71, 25.2%) or pafolacianine (n=211, 74.8%). Most tumors (n=208, 73.8%) were invasive adenocarcinomas. We identified 2 clinical applications of IMI: localization of nonpalpable lesions (n=39 lesions, 13.8%) and detection of positive margins (n=11, 3.9%). In each application, the long-wavelength tracer was superior to the short-wavelength tracer regarding depth of penetration, signal-to-background ratio, and frequency of event. Pafolacianine was more effective for detecting subpleural lesions (mean signal-to-background ratio=2.71 vs 1.73 for folate-fluorescein, P <0.0001). Limit of signal detection was 1.8 cm from the pleural surface for pafolacianine and 0.3 cm for folate-fluorescein. Conclusions: Long-wavelength near-infrared fluorophores are superior to short-wavelength IMI fluorophores in human tissues. Therefore, future efforts in all human cancers should likely focus on long-wavelength agents. [ABSTRACT FROM AUTHOR]

Published

2022

20. Intraoperative molecular imaging:3rd biennial clinical trials update

Author

Bou-Samra, Patrick, Muhammad, Najib, Chang, Austin, Karsalia, Ritesh, Azari, Feredun, Kennedy, Gregory, Stummer, Walter, Tanyi, Janos, Martin, Linda, Vahrmeijer, Alexander, Smith, Barbara, Rosenthal, Eben, Wagner, Patrick, Rice, David, Lee, Amy, Abdelhafeez, Hafeez, Malek, Marcus M., Kohanbash, Gary, Barry Edwards, Wilson, Henderson, Eric, Skjøth-Rasmussen, Jane, Orosco, Ryan, Gibbs, Summer, Farnam, Richard W., Shankar, Lalitha, Sumer, Baran, Kumar, Anand T.N., Marcu, Laura, Li, Lei, Greuv, Victor, Delikatny, Edward J., Lee, John Y.K., Singhal, Sunil, Bou-Samra, Patrick, Muhammad, Najib, Chang, Austin, Karsalia, Ritesh, Azari, Feredun, Kennedy, Gregory, Stummer, Walter, Tanyi, Janos, Martin, Linda, Vahrmeijer, Alexander, Smith, Barbara, Rosenthal, Eben, Wagner, Patrick, Rice, David, Lee, Amy, Abdelhafeez, Hafeez, Malek, Marcus M., Kohanbash, Gary, Barry Edwards, Wilson, Henderson, Eric, Skjøth-Rasmussen, Jane, Orosco, Ryan, Gibbs, Summer, Farnam, Richard W., Shankar, Lalitha, Sumer, Baran, Kumar, Anand T.N., Marcu, Laura, Li, Lei, Greuv, Victor, Delikatny, Edward J., Lee, John Y.K., and Singhal, Sunil

Abstract

Significance This third biennial intraoperative molecular imaging (IMI) conference shows how optical contrast agents have been applied to develop clinically significant endpoints that improve precision cancer surgery. Aim National and international experts on IMI presented ongoing clinical trials in cancer surgery and preclinical work. Previously known dyes (with broader applications), new dyes, novel nonfluorescence-based imaging techniques, pediatric dyes, and normal tissue dyes were discussed. Approach Principal investigators presenting at the Perelman School of Medicine Abramson Cancer Center’s third clinical trials update on IMI were selected to discuss their clinical trials and endpoints. Results Dyes that are FDA-approved or currently under clinical investigation in phase 1, 2, and 3 trials were discussed. Sections on how to move benchwork research to the bedside were also included. There was also a dedicated section for pediatric dyes and nonfluorescence-based dyes that have been newly developed. Conclusions IMI is a valuable adjunct in precision cancer surgery and has broad applications in multiple subspecialties. It has been reliably used to alter the surgical course of patients and in clinical decision making. There remain gaps in the utilization of IMI in certain subspecialties and potential for developing newer and improved dyes and imaging techniques., Significance: This third biennial intraoperative molecular imaging (IMI) conference shows how optical contrast agents have been applied to develop clinically significant endpoints that improve precision cancer surgery. Aim: National and international experts on IMI presented ongoing clinical trials in cancer surgery and preclinical work. Previously known dyes (with broader applications), new dyes, novel nonfluorescence-based imaging techniques, pediatric dyes, and normal tissue dyes were discussed. Approach: Principal investigators presenting at the Perelman School of Medicine Abramson Cancer Center's third clinical trials update on IMI were selected to discuss their clinical trials and endpoints. Results: Dyes that are FDA-approved or currently under clinical investigation in phase 1, 2, and 3 trials were discussed. Sections on how to move benchwork research to the bedside were also included. There was also a dedicated section for pediatric dyes and nonfluorescence-based dyes that have been newly developed. Conclusions: IMI is a valuable adjunct in precision cancer surgery and has broad applications in multiple subspecialties. It has been reliably used to alter the surgical course of patients and in clinical decision making. There remain gaps in the utilization of IMI in certain subspecialties and potential for developing newer and improved dyes and imaging techniques.

Published

2023

21. Precision Oncology in Lung Cancer Surgery.

Author

Bou-Samra P and Singhal S

Subjects

Humans, Precision Medicine, Medical Oncology, Lung Neoplasms surgery

Abstract

Precision in lung cancer surgery is our ability to use the most cutting edge and up to date information to provide personalized and targeted surgical care to our patients. It aims to tailor patient care to patient and tumor characteristics and susceptibilities as well as to optimize the ways treatments are administered. This may include specific perioperative medical treatment, changing operative techniques to more minimally invasive ones if the situation permits, performing sub-anatomical surgeries when possible, and using innovative tumor visualization methods to enhance detection of previously occult disease to ultimately decrease the extent of the planned resection., Competing Interests: Disclosure The authors have nothing to disclose., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

22. Near-infrared intraoperative molecular imaging with conventional neurosurgical microscope can be improved with narrow band "boost" excitation.

Author

Li, Carrie, Buch, Love, Cho, Steve, and Lee, John Y. K.

Subjects

*CLINICAL trial registries, *MICROSCOPES, *INTRAOPERATIVE radiotherapy, *GLIOBLASTOMA multiforme, *INDOCYANINE green, *BRAIN tumors

Abstract

Background: Intraoperative visualization of brain tumors with near-infrared (NIR)-fluorescent dyes is an emerging method for tumor margin approximation but are limited by existing fluorescence detection platforms. We previously showed that a dedicated NIR imaging platform outperformed a state-of-the-art neurosurgical microscope in fluorescence signal characteristics. This study examined whether conventional neurosurgical microscope NIR signal could be improved with the addition of a narrow wavelength excitation source. Methods: Imaging was conducted with a broad-spectrum neurosurgical microscope and commercial near-infrared module. Addition of an 805-nm laser was used to "boost" NIR excitation of indocyanine green (ICG). In vitro quantification was performed on serial dilutions of ICG. Patients underwent tumor resection with delayed 24-h imaging of ICG infusion. NIR fluorescence of dura, cortex, or tumor was quantified from images prior to (pre-boost) and following added excitation with the laser (post-boost). Signal to background ratio (SBR) of pre- and post-boost was calculated as a readout of image enhancement. Results: In vitro, excitation boost effected a 29% increase in mean SBR in six serial dilutions of ICG. Intraoperative boost was performed in 11 patients including meningioma, glioblastoma multiforme, and metastases. Increase in tumor fluorescence was pronounced under direct tumor visualization. Across all patients, boost excitation resulted in 35% mean improvement from pre-boost SBR (p < 0.001). Conclusion: Neurosurgical microscopes remain the preferred method of visualizing tumor during intracranial surgery. However, current modalities for NIR signal detection are suboptimal. We demonstrate that augmentation of a fluorescence microscope module with a focused excitation source is a simple mechanism of improving NIR tumor visualization. Clinical trial registration: NCT03262636 [ABSTRACT FROM AUTHOR]

Published

2019

23. Intraoperative Molecular Imaging with Second Window Indocyanine Green Facilitates Confirmation of Contrast-Enhancing Tissue During Intracranial Stereotactic Needle Biopsy: A Case Series.

Author

Li, Carrie, Sullivan, Patricia Zadnik, Cho, Steve, Nasrallah, MacLean P., Buch, Love, Isaac Chen, Han-Chiao, and Lee, John Y.K.

Subjects

*NEEDLE biopsy, *INDOCYANINE green, *VISIBLE spectra, *TARGET acquisition, *THERAPEUTICS

Abstract

Stereotactic needle biopsy provides a minimally invasive option for the diagnosis of intracranial lesions but is limited by inconclusive diagnoses on frozen pathology. For rapid pathology, 5-aminovelunic acid and sodium fluorescein have previously demonstrated potential as diagnostic adjuvants. Stereotactic biopsy with near-infrared (NIR) fluorophores has not been reported. We identified 5 representative cases using NIR fluorescent dye indocyanine green (ICG) administered in a high dose, delayed manner. Five patients underwent second window indocyanine green (SWIG)-guided stereotactic biopsy for diagnosis of suspected glioma or tumor recurrence. Up to 5 mg/kg ICG was administered approximately 24 hours prior to surgery. Biopsies were conducted in the standard fashion, targeting regions of suspected tumor using intraoperative frameless navigation. Samples were examined intraoperatively under standard visible light and for fluorescence using conventional NIR imaging platforms. Findings were correlated with frozen and final tumor pathology for all cases. A total of 10 biopsy specimens were obtained. Three did not fluoresce and did not demonstrate tumor on preliminary or final pathology, including a non-gadolinium-enhancing sample taken proximal to the final target. The remaining 7 fluoresced, of which 6 contained tumor and 1 contained necrosis. Fluorescence was also noted in a patient with radiation treatment effect. Overall fluorescence characteristics were highly concordant with preliminary and final diagnoses. SWIG provides rapid intraoperative confirmation of pathologic brain tissue by permeating neoplastic or inflammatory brain tissue via a mechanism similar to that of gadolinium enhancement. SWIG-guided stereotactic biopsy can improve surgical efficiency by enhancing confidence in acquisition of target tissue. [ABSTRACT FROM AUTHOR]

Published

2019

24. Single-institution experience of 500 pulmonary resections guided by intraoperative molecular imaging.

Author

Kennedy, Gregory T., Azari, Feredun S., Chang, Ashley, Nadeem, Bilal, Bernstein, Elizabeth, Segil, Alix, Din, Azra, Desphande, Charuhas, Okusanya, Olugbenga, Keating, Jane, Predina, Jarrod, Newton, Andrew, Kucharczuk, John C., and Singhal, Sunil

Abstract

Intraoperative molecular imaging (IMI) using tumor-targeted optical contrast agents can improve thoracic cancer resections. There are no large-scale studies to guide surgeons in patient selection or imaging agent choice. Here, we report our institutional experience with IMI for lung and pleural tumor resection in 500 patients over a decade. Between December 2011 and November 2021, patients with lung or pleural nodules undergoing resection were preoperatively infused with 1 of 4 optical contrast tracers: EC17, TumorGlow, pafolacianine, or SGM-101. Then, during resection, IMI was used to identify pulmonary nodules, confirm margins, and identify synchronous lesions. We retrospectively reviewed patient demographic data, lesion diagnoses, and IMI tumor-to-background ratios (TBRs). Five hundred patients underwent resection of 677 lesions. We found that there were 4 types of clinical utility of IMI: detection of positive margins (n = 32, 6.4% of patients), identification of residual disease after resection (n = 37, 7.4%), detection of synchronous cancers not predicted on preoperative imaging (n = 26, 5.2%), and minimally invasive localization of nonpalpable lesions (n = 101 lesions, 14.9%). Pafolacianine was most effective for adenocarcinoma-spectrum malignancies (mean TBR, 2.84), and TumorGlow was most effective for metastatic disease and mesothelioma (TBR, 3.1). False-negative fluorescence was primarily seen in mucinous adenocarcinomas (mean TBR, 1.8), heavy smokers (>30 pack years; TBR, 1.9), and tumors greater than 2.0 cm from the pleural surface (TBR, 1.3). IMI may be effective in improving resection of lung and pleural tumors. The choice of IMI tracer should vary by the surgical indication and the primary clinical challenge. [ABSTRACT FROM AUTHOR]

Published

2023

25. Mucins as contrast agent targets for fluorescence-guided surgery of pancreatic cancer.

Author

Muilenburg, Kathryn M., Isder, Carly C., Radhakrishnan, Prakash, Batra, Surinder K., Ly, Quan P., Carlson, Mark A., Bouvet, Michael, Hollingsworth, Michael A., and Mohs, Aaron M.

Subjects

*CONTRAST media, *PANCREATIC cancer, *MUCINS, *PANCREATIC surgery, *ONCOLOGIC surgery

Abstract

Pancreatic cancer is difficult to resect due to its unique challenges, often leading to incomplete tumor resections. Fluorescence-guided surgery (FGS), also known as intraoperative molecular imaging and optical surgical navigation, is an intraoperative tool that can aid surgeons in complete tumor resection through an increased ability to detect the tumor. To target the tumor, FGS contrast agents rely on biomarkers aberrantly expressed in malignant tissue compared to normal tissue. These biomarkers allow clinicians to identify the tumor and its stage before surgical resection and provide a contrast agent target for intraoperative imaging. Mucins, a family of glycoproteins, are upregulated in malignant tissue compared to normal tissue. Therefore, these proteins may serve as biomarkers for surgical resection. Intraoperative imaging of mucin expression in pancreatic cancer can potentially increase the number of complete resections. While some mucins have been studied for FGS, the potential ability to function as a biomarker target extends to the entire mucin family. Therefore, mucins are attractive proteins to investigate more broadly as FGS biomarkers. This review summarizes the biomarker traits of mucins and their potential use in FGS for pancreatic cancer. [Display omitted] • Mucins can be differentially or uniquely expressed in pancreatic cancer allowing them to serve as contrast agent targets. • Fluorescently-labeled, mucin-targeting molecules, e.g. antibodies, can intraoperatively illuminate pancreatic cancer. • Intraoperative imaging, or fluorescence-guided surgery, can potentially increase the rate of complete tumor resection. • Mucin-targeting fluorophores are in preclinical development and could complement other surgical imaging agents. [ABSTRACT FROM AUTHOR]

Published

2023

26. Intraoperative Molecular Imaging of Lung Cancer.

Author

Wong LY and Lui NS

Subjects

Humans, Fluorescent Dyes, Molecular Imaging methods, Optical Imaging methods, Lung Neoplasms diagnostic imaging, Lung Neoplasms surgery

Abstract

Intraoperative molecular imaging innovations have been propelled by the development of fluorescent contrast agents that specifically target tumor tissues and advanced camera systems that can detect the specified fluorescence. The most promising agent to date is OTL38, a targeted and near-infrared agent that was recently approved by the Food and Drug Administration for intraoperative imaging for lung cancer., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

27. Preclinical Lymph Node Model for Intraoperative Molecular Imaging of Cancer.

Author

Bou-Samra P, Chang A, Arambepola S, Guo E, Azari F, Kennedy G, Segil A, and Singhal S

Abstract

Purpose: Lymph node(LN) dissection is part of most oncologic resections. Intraoperatively identifying a positive LN(+ LN), that harbors malignant cells, can be challenging. We hypothesized that intraoperative molecular imaging(IMI) using a cancer-targeted fluorescent prober can identify + LNs. This study aimed to develop a preclinical model of a + LN and test it using an activatable cathepsin-based enzymatic probe, VGT-309., Procedures: In the first model, we used peripheral blood mononuclear cells (PBMC), representing the lymphocytic composition of the LN, mixed with different concentrations of human lung adenocarcinoma cell line A549. Then, they were embedded in a Matrigel ® matrix. A black dye was added to mimic LN anthracosis. Model two was created using a murine spleen, the largest lymphoid organ, injected with various concentrations of A549. To test these models, we co-cultured A549 cells with VGT-309. Mean fluorescence intensity(MFI) was. An independent sample t-test was used to compare the average MFI of each A549:negative control ratio., Results: A significant difference in MFI from our PBMC control was noted when A549 cells were 25% of the LN (p = 0.046) in both 3D cell aggregate models-where the LNs native parenchyma is replaced and the one where the tumor grows over the native parenchyma. For the anthracitic equivalents of these models, the first significant MFI compared to the control was when A549 cells were 9% of the LN (p = 0.002) in the former model, and 16.7% of the LN (p = 0.033) in the latter. In our spleen model, we first noted significance in MFI when A549 cells were 16.67% of the cellular composition.(p = 0.02)., Conclusions: A + LN model allows for a granular evaluation of different cellular burdens in + LN that can be assessed using IMI. This first exvivo + LN model can be used in preclinical testing of several existing dyes and in creating more sensitive cameras for IMI-guided LN detection., Competing Interests: Conflict of Interest The author(s) declare(s) that there is no conflict of interest regarding the publication of this article.

Published

2023

28. Intraoperative molecular imaging clinical trials: a review of 2020 conference proceedings

Author

Gregory T. Kennedy, Eben L. Rosenthal, Janos L. Tanyi, Alexander L. Vahrmeijer, Daniel A. Orringer, Sunil Singhal, Amy S. Lee, Summer L. Gibbs, Eric Henderson, Brian W. Pogue, John Y K Lee, Elizabeth Bernstein, Jie Tian, Linda W. Martin, Barbara L. Smith, Baran D. Sumer, Major K. Lee, Constantinos G. Hadjipanayis, Quyen T. Nguyen, Cleopatra Charalampaki, and Feredun Azari

Subjects

Paper, medicine.medical_specialty, Biomedical Engineering, Specialty, 01 natural sciences, Resection, 010309 optics, Biomaterials, optical biopsy, Surgical oncology, Neoplasms, 0103 physical sciences, Clinical endpoint, Humans, Medicine, Medical physics, Review Papers, intraoperative visualization, business.industry, Margins of Excision, Cancer, Aminolevulinic Acid, Surgical procedures, molecular imaging, medicine.disease, Atomic and Molecular Physics, and Optics, Electronic, Optical and Magnetic Materials, Clinical trial, tumor surgery, intraoperative molecular imaging, business, fluorescence-guided surgery, Cancer surgery

Abstract

Significance: Surgery is often paramount in the management of many solid organ malignancies because optimal resection is a major factor in disease-specific survival. Cancer surgery has multiple challenges including localizing small lesions, ensuring negative surgical margins around a tumor, adequately staging patients by discriminating positive lymph nodes, and identifying potential synchronous cancers. Intraoperative molecular imaging (IMI) is an emerging potential tool proposed to address these issues. IMI is the process of injecting patients with fluorescenttargeted contrast agents that highlight cancer cells prior to surgery. Over the last 5 to 7 years, enormous progress has been achieved in tracer development, near-infrared camera approvals, and clinical trials. Therefore, a second biennial conference was organized at the University of Pennsylvania to gather surgical oncologists, scientists, and experts to discuss new investigative findings in the field. Our review summarizes the discussions from the conference and highlights findings in various clinical and scientific trials.Aim: Recent advances in IMI were presented, and the importance of each clinical trial for surgical oncology was critically assessed. A major focus was to elaborate on the clinical endpoints that were being utilized in IMI trials to advance the respective surgical subspecialties.Approach: Principal investigators presenting at the Perelman School of Medicine Abramson Cancer Center's second clinical trials update on IMI were selected to discuss their clinical trials and endpoints.Results: Multiple phase III, II, and I trials were discussed during the conference. Since the approval of 5-ALA for commercial use in neurosurgical malignancies, multiple tracers and devices have been developed to address common challenges faced by cancer surgeons across numerous specialties. Discussants also presented tracers that are being developed for delineation of normal anatomic structures that can serve as an adjunct during surgical procedures.Conclusions: IMI is increasingly being recognized as an improvement to standard oncologic surgical resections and will likely advance the art of cancer surgery in the coming years. The endpoints in each individual surgical subspecialty are varied depending on how IMI helps each specialty solve their clinical challenges. (C) The Authors. Published by SPIE under a Creative Commons Attribution 4.0 Unported License.

Published

2021

29. Precision Surgery Guided by Intraoperative Molecular Imaging.

Author

Azari F, Zhang K, Kennedy GT, Chang A, Nadeem B, Delikatny EJ, and Singhal S

Subjects

Humans, Molecular Imaging methods, Fluorescent Dyes, Optical Imaging methods, Surgery, Computer-Assisted methods, Neoplasms surgery

Abstract

Intraoperative molecular imaging (IMI) has recently emerged as an important tool in the armamentarium of surgical oncologists. IMI allows real-time assessment of oncologic resection quality, margin assessment, and occult disease detection during real-time surgery. Numerous tracers have now been developed for use in IMI-guided tissue sampling. Fluorochromes localize to the tumor by taking advantage of their disorganized capillary milieu, overexpressed receptors, or upregulated enzymes. Although fluorescent tracers can suffer from issues of autofluorescence and lack of depth penetration, these challenges are being addressed through hybrid radioactive/fluorescent tracers and new tracers that fluoresce in the near-infrared (NIR-II [wavelength > 1,000 nm]) range. IMI is already being used to treat numerous cancers, with demonstrated improvement in cancer recurrence and patient outcomes without incurring significant burden on either clinicians or patients. In this comprehensive review, we discuss history, mechanism, current oncologic applications, and future directions of IMI-guided optical biopsy., (© 2022 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2022

30. Intraoperative Molecular Imaging of Lung Cancer: A Review.

Author

Lui NS and Singhal S

Subjects

Humans, Lymph Nodes pathology, Molecular Imaging methods, Lung Neoplasms diagnostic imaging, Lung Neoplasms pathology, Lung Neoplasms surgery

Abstract

Intraoperative molecular imaging shows great promise in the surgical treatment of lung cancer, in particular tumor localization, margin assessment, identification of additional nodules, and even potentially lymph node assessment. Advances in imaging agents and fluorescence surgical cameras will be the key. Although no imaging agent is currently Food and Drug Administration approved, targeted, near-infrared agents such as OTL38 are in phase III trials., Competing Interests: Disclosure N.S. Lui has a research grant from the Intuitive Foundation, United States. S. Singhal has no disclosures., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

31. Intraoperative molecular imaging clinical trials: a review of 2020 conference proceedings.

Author

Azari, Feredun, Kennedy, Gregory, Bernstein, Elizabeth, Hadjipanayis, Costas, Vahrmeijer, Alexander L., Smith, Barbara L., Rosenthal, Eben, Sumer, Baran, Tian, Jie, Henderson, Eric R., Lee, Amy, Nguyen, Quyen, Gibbs, Summer L., Pogue, Brian W., Orringer, Daniel A., Charalampaki, Patra, Martin, Linda W., Tanyi, Janos L., Kenneth Lee, Major, and Lee, John Y. K.

Subjects

*CLINICAL trials, *SURGICAL margin, *OPERATIVE surgery, *ONCOLOGIC surgery, *SURGICAL robots, *DIAGNOSTIC imaging

Abstract

Significance: Surgery is often paramount in the management of many solid organ malignancies because optimal resection is a major factor in disease-specific survival. Cancer surgery has multiple challenges including localizing small lesions, ensuring negative surgical margins around a tumor, adequately staging patients by discriminating positive lymph nodes, and identifying potential synchronous cancers. Intraoperative molecular imaging (IMI) is an emerging potential tool proposed to address these issues. IMI is the process of injecting patients with fluorescent-targeted contrast agents that highlight cancer cells prior to surgery. Over the last 5 to 7 years, enormous progress has been achieved in tracer development, near-infrared camera approvals, and clinical trials. Therefore, a second biennial conference was organized at the University of Pennsylvania to gather surgical oncologists, scientists, and experts to discuss new investigative findings in the field. Our review summarizes the discussions from the conference and highlights findings in various clinical and scientific trials. Aim: Recent advances in IMI were presented, and the importance of each clinical trial for surgical oncology was critically assessed. A major focus was to elaborate on the clinical endpoints that were being utilized in IMI trials to advance the respective surgical subspecialties. Approach: Principal investigators presenting at the Perelman School of Medicine Abramson Cancer Center's second clinical trials update on IMI were selected to discuss their clinical trials and endpoints. Results: Multiple phase III, II, and I trials were discussed during the conference. Since the approval of 5-ALA for commercial use in neurosurgical malignancies, multiple tracers and devices have been developed to address common challenges faced by cancer surgeons across numerous specialties. Discussants also presented tracers that are being developed for delineation of normal anatomic structures that can serve as an adjunct during surgical procedures. Conclusions: IMI is increasingly being recognized as an improvement to standard oncologic surgical resections and will likely advance the art of cancer surgery in the coming years. The endpoints in each individual surgical subspecialty are varied depending on how IMI helps each specialty solve their clinical challenges. [ABSTRACT FROM AUTHOR]

Published

2021