Your search keyword '"Wong, Vincenzo K."' showing total 11 results

1. Dual-energy CT for differentiation of hypodense liver lesions in pancreatic adenocarcinoma

Author

Jensen, Corey T., Wong, Vincenzo K., Likhari, Gauruv S., Daoud, Taher E., Ahmad, Moiz, Bassett, Roland, Pasyar, Sarah, Virarkar, Mayur K., Roman-Colon, Alicia M., and Liu, Xinming

Published

2024

2. Appearance of the Upper Urinary System After Treatment

Author

Wong, Vincenzo K., Gao, Mamie, and Horn, Gary Lloyd

Published

2025

3. Abdominal CT findings characteristic of Castleman disease: multi-centre review of 76 adult cases with abdominopelvic nodal involvement.

Author

Pickhardt, Perry J, Wong, Vincenzo K, Mellnick, Vincent, Sugi, Mark, and Aswani, Yashant

Subjects

*CASTLEMAN'S disease, *PLASMA cells, *COMPUTED tomography, *DIAGNOSIS, *FAT

Abstract

Objective: Characterize the CT findings of abdominopelvic Castleman disease, including a new observation involving the perinodal fat. Methods: Multi-centre search at 5 institutions yielded 76 adults (mean age, 42.1 ± 14.3 years; 38 women/38 men) meeting inclusion criteria of histopathologically proven Castleman disease with nodal involvement at abdominopelvic CT. Retrospective review of the dominant nodal mass was assessed for size, attenuation, and presence of calcification, and for prominence and soft-tissue infiltration of the perinodal fat. Hypervascular nodal enhancement was based on both subjective and objective comparison with aortic blood pool attenuation. Results: Abdominal involvement was unicentric in 48.7% (37/76) and multicentric in 51.3% (39/76), including 31 cases with extra-abdominal involvement. Histopathologic subtypes included hyaline vascular variant (HVV), plasma cell variant (PCV), mixed HVV/PCV, and HHV-8 variant in 39, 25, 3 and 9 cases, respectively. The dominant nodal mass measured 4.4 ± 1.9 cm and 3.2 ± 1.7 cm in mean long- and short-axis, respectively, and appeared hypervascular in 58.6% (41/70 with IV contrast). Internal calcification was seen in 22.4% (17/76). Infiltration of the perinodal fat, with or without hypertrophy, was present in 56.6% (43/76), more frequent with hypervascular vs non-hypervascular nodal masses (80.5% vs 20.7%; P < .001). Among HVV cases, 76.9% were unicentric, 71.1% appeared hypervascular, and 69.2% demonstrated perinodal fat infiltration. Conclusion: Hypervascular nodal masses demonstrating prominence and infiltration of perinodal fat at CT can suggest the specific diagnosis of Castleman disease, especially the HVV. Advances in knowledge: Abdominopelvic nodal masses that demonstrate hypervascular enhancement and prominent infiltration of the perinodal fat at CT can suggest the diagnosis of Castleman disease, but nonetheless requires tissue sampling. [ABSTRACT FROM AUTHOR]

Published

2024

4. Renal mass biopsy and thermal ablation: should biopsy be performed before or during the ablation procedure?

Author

Wells, Shane A., Wong, Vincenzo K., Wittmann, Tyler A., Lubner, Meghan G., Best, Sara L., Ziemlewicz, Timothy J., Hinshaw, J. Louis, Lee, Jr., Fred T, and Abel, E. Jason

Published

2017

5. Update on quantitative radiomics of pancreatic tumors.

Author

Virarkar, Mayur, Wong, Vincenzo K., Morani, Ajaykumar C., Tamm, Eric P., and Bhosale, Priya

Subjects

*RADIOMICS, *ENDOSCOPIC ultrasonography, *PANCREATIC tumors, *POSITRON emission tomography, *MAGNETIC resonance imaging, *COMPUTED tomography

Abstract

Radiomics is a newer approach for analyzing radiological images obtained from conventional imaging modalities such as computed tomography, magnetic resonance imaging, endoscopic ultrasonography, and positron emission tomography. Radiomics involves extracting quantitative data from the images and assessing them to identify diagnostic or prognostic features such as tumor grade, resectability, tumor response to neoadjuvant therapy, and survival. The purpose of this review is to discuss the basic principles of radiomics and provide an overview of the current clinical applications of radiomics in the field of pancreatic tumors. [ABSTRACT FROM AUTHOR]

Published

2022

6. 99mTc-EC-Guanine: Synthesis, Biodistribution, and Tumor Imaging in Animals

Author

Yang, David J., Ozaki, Kaoru, Oh, Chang-Sok, Azhdarinia, Ali, Yang, Thomas, Ito, Megumi, Greenwell, Allison, Bryant, Jerry, Kohanim, Saady, Wong, Vincenzo K., and Kim, E. Edmund

Published

2005

7. Magnetic Resonance Imaging of Hepatic Adenoma Subtypes.

Author

Wong, Vincenzo K., Fung, Alice W., and Elsayes, Khaled M.

Published

2021

8. Accuracy of liver metastasis detection and characterization: Dual-energy CT versus single-energy CT with deep learning reconstruction.

Author

Jensen, Corey T., Wong, Vincenzo K., Wagner-Bartak, Nicolaus A., Liu, Xinming, Padmanabhan Nair Sobha, Renjith, Sun, Jia, Likhari, Gauruv S., and Gupta, Shiva

Subjects

*LIVER metastasis, *COLORECTAL liver metastasis, *DEEP learning, *GENERALIZED estimating equations, *DUAL energy CT (Tomography), *DICOM (Computer network protocol)

Abstract

• In this prospective study of 30 participants (141 lesions [124 metastases, 17 benign]) with colorectal liver metastases on abdominal CT using deep learning image reconstruction, perceived image quality of dual-energy CT (DECT)(71/90 total scores were rated as high-quality) was not significantly different from single-energy CT (SECT)(62/90 total scores were rated as high-quality) (OR, 2.01; 95% CI:0.89, 4.57; P=0.093). • Liver lesion observer detection was equivalent between DECT and SECT (140/141 lesions detected) with the same accuracy of 92.9% (95% CI:87.3%, 96.5%; 131/141). • Subsequent use of DECT spectral HU lesion curves for liver lesions initially scored as indeterminate resulted in 34 correct characterizations (31 metastases, 3 benign) and no mischaracterizations. To assess whether image quality differences between SECT (single-energy CT) and DECT (dual-energy CT 70 keV) with equivalent radiation doses result in altered detection and characterization accuracy of liver metastases when using deep learning image reconstruction (DLIR), and whether DECT spectral curve usage improves accuracy of indeterminate lesion characterization. In this prospective Health Insurance Portability and Accountability Act–compliant study (March through August 2022), adult men and non-pregnant adult women with biopsy-proven colorectal cancer and liver metastases underwent SECT (120 kVp) and a DECT (70 keV) portovenous abdominal CT scan using DLIR in the same breath-hold (Revolution CT ES; GE Healthcare). Participants were excluded if consent could not be obtained, if there were nonequivalent radiation doses between the two scans, or if the examination was cancelled/rescheduled. Three radiologists independently performed lesion detection and characterization during two separate sessions (SECT DLIR medium and DECT DLIR high) as well as reported lesion confidence and overall image quality. Hounsfield units were measured. Spectral HU curves were provided for any lesions rated as indeterminate. McNemar's test was used to test the marginal homogeneity in terms of diagnostic sensitivity, accuracy and lesion detection. A generalized estimating equation method was used for categorical outcomes. 30 participants (mean age, 58 years ± 11, 21 men) were evaluated. Mean CTDI vol was 34 mGy for both scans. 141 lesions (124 metastases, 17 benign) with a mean size of 0.8 cm ± 0.3 cm were identified. High scores for image quality (scores of 4 or 5) were not significantly different between DECT (N = 71 out of 90 total scores from the three readers) and SECT (N = 62) (OR, 2.01; 95% CI:0.89, 4.57; P = 0.093). Equivalent image noise to SECT DLIR med (HU SD 10 ± 2) was obtained with DECT DLIR high (HU SD 10 ± 3) (P = 1). There was no significant difference in lesion detection between DECT and SECT (140/141 lesions) (99.3%; 95% CI:96.1%, 100%).The mean lesion confidence scores by each reader were 4.2 ± 1.3, 3.9 ± 1.0, and 4.8 ± 0.8 for SECT and 4.1 ± 1.4, 4.0 ± 1.0, and 4.7 ± 0.8 for DECT (odds ratio [OR], 0.83; 95% CI: 0.62, 1.11; P = 0.21). Small lesion (≤5mm) characterization accuracy on SECT and DECT was 89.1% (95% CI:76.4%, 96.4%; 41/46) and 84.8% (71.1%, 93.7%; 39/46), respectively (P = 0.41). Use of spectral HU lesion curves resulted in 34 correct changes in characterizations and no mischaracterizations. DECT required a higher strength of DLIR to obtain equivalent noise compared to SECT DLIR. At equivalent radiation doses and image noise, there was no significant difference in subjective image quality or observer lesion performance between DECT (70 keV) and SECT. However, DECT spectral HU curves of indeterminate lesions improved characterization. [ABSTRACT FROM AUTHOR]

Published

2023

9. Mastocytosis—A Review of Disease Spectrum with Imaging Correlation.

Author

Elsaiey, Ahmed, Mahmoud, Hagar S., Jensen, Corey T., Klimkowski, Sergio, Taher, Ahmed, Chaudhry, Humaira, Morani, Ajaykumar C., Wong, Vincenzo K., Salem, Usama I., Palmquist, Sarah M., and Elsayes, Khaled M.

Subjects

SKIN mast cell disease, CANCER invasiveness, MAST cell disease, EARLY detection of cancer, DIAGNOSTIC imaging, SYMPTOMS

Abstract

Simple Summary: In this review will discuss the clinical presentation, pathophysiology, and role of imaging in detection and extent estimation of the systemic involvement of the disease, in addition to demonstration of appearance on varying imaging modalities. Familiarity with the potential imaging findings associated with mastocytosis can aid in early disease diagnosis and classification and accordingly can lead directing further work up and better management. Mastocytosis is a rare disorder due to the abnormal proliferation of clonal mast cells. Mast cells exist in most tissues, mature in situ from hematopoietic stem cells and develop unique characteristics of local effector cells. Mastocytosis develops by activation mutation of the KIT surface receptor which is involved in the proliferation of a number of cell lines such as mast cells, germ cells, melanocytes, and hematopoietic cells. It manifests as two main categories: cutaneous mastocytosis and systemic mastocytosis. Imaging can play an important role in detection and characterization of the disease manifestation, not only by radiography and bone scans, but also magnetic resonance imaging and computed tomography, which can be more sensitive in the assessment of distinctive disease patterns. Radiologists should be aware of various appearances of this disease to better facilitate diagnosis and patient management. Accordingly, this review will discuss the clinical presentation, pathophysiology, and role of imaging in detection and extent estimation of the systemic involvement of the disease, in addition to demonstration of appearance on varying imaging modalities. Familiarity with the potential imaging findings associated with mastocytosis can aid in early disease diagnosis and classification and accordingly can lead directing further work up and better management. [ABSTRACT FROM AUTHOR]

Published

2021

10. PTEN Hamartoma Tumor Syndrome/Cowden Syndrome: Genomics, Oncogenesis, and Imaging Review for Associated Lesions and Malignancy.

Author

Dragoo, David D., Taher, Ahmed, Wong, Vincenzo K., Elsaiey, Ahmed, Consul, Nikita, Mahmoud, Hagar S., Mujtaba, Bilal, Stanietzky, Nir, and Elsayes, Khaled M.

Subjects

COWDEN syndrome, THYROID diseases, KIDNEYS, CARCINOGENESIS, NEOPLASTIC cell transformation, EARLY detection of cancer, GERM cells, UTERUS, GENOMICS, BREAST

Abstract

Simple Summary: In this manuscript, we present the associated imaging findings and imaging screening recommendations. Knowledge of the types of cancers commonly seen in Cowden syndrome and their imaging findings can aid in early tumor recognition during cancer screening to help ensure near-normal life spans in Cowden syndrome patients. PTEN hamartoma tumor syndrome/Cowden syndrome (CS) is a rare autosomal dominant syndrome containing a germline PTEN mutation that leads to the development of multisystem hamartomas and oncogenesis. Benign tumors such as Lhermitte–Duclos disease and malignant tumors involving the breast, thyroid, kidneys, and uterus are seen in CS. Radiologists have an integral role in the comanagement of CS patients. We present the associated imaging findings and imaging screening recommendations. Knowledge of the types of cancers commonly seen in CS and their imaging findings can aid in early tumor recognition during cancer screening to help ensure near-normal life spans in CS patients. [ABSTRACT FROM AUTHOR]

Published

2021

11. Imaging and Management of Bladder Cancer.

Author

Wong, Vincenzo K., Ganeshan, Dhakshinamoorthy, Jensen, Corey T., Devine, Catherine E., and Bolenz, Christian

Subjects

*MAGNETIC resonance imaging, *TUMOR classification, *CANCER, *COMPUTED tomography, *MEDICAL research, *GENITOURINARY organ radiography, BLADDER tumors

Abstract

Simple Summary: Bladder cancer is a complex disease, the sixth most common cancer, and one of the most expensive cancers to treat. In the last few decades, there has been a significant decrease in the bladder cancer-related mortality rate, potentially related to decreased smoking prevalence, improvements in diagnosing bladder cancer, and advances in treatment. Those advances in diagnostic tools and therapies and greater understanding of the disease are helping to evolve how bladder cancer is managed. The purpose of this article is to provide a review of bladder cancer pathology, diagnosis, staging, radiologic imaging, and management, and highlight recent developments and research. Methods: Keyword searches of Medline, PubMed, and the Cochrane Library for manuscripts published in English, and searches of references cited in selected articles to identify additional relevant papers. Abstracts sponsored by various societies including the American Urological Association (AUA), European Association of Urology (EAU), and European Society for Medical Oncology (ESMO) were also searched. Background: Bladder cancer is the sixth most common cancer in the United States, and one of the most expensive in terms of cancer care. The overwhelming majority are urothelial carcinomas, more often non-muscle invasive rather than muscle-invasive. Bladder cancer is usually diagnosed after work up for hematuria. While the workup for gross hematuria remains CT urography and cystoscopy, the workup for microscopic hematuria was recently updated in 2020 by the American Urologic Association with a more risk-based approach. Bladder cancer is confirmed and staged by transurethral resection of bladder tumor. One of the main goals in staging is determining the presence or absence of muscle invasion by tumor which has wide implications in regards to management and prognosis. CT urography is the main imaging technique in the workup of bladder cancer. There is growing interest in advanced imaging techniques such as multiparametric MRI for local staging, as well as standardized imaging and reporting system with the recently created Vesicle Imaging Reporting and Data System (VI-RADS). Therapies for bladder cancer are rapidly evolving with immune checkpoint inhibitors, particularly programmed death ligand 1 (PD-L1) and programmed cell death protein 1 (PD-1) inhibitors, as well as another class of immunotherapy called an antibody-drug conjugate which consists of a cytotoxic drug conjugated to monoclonal antibodies against a specific target. Conclusion: Bladder cancer is a complex disease, and its management is evolving. Advances in therapy, understanding of the disease, and advanced imaging have ushered in a period of rapid change in the care of bladder cancer patients. [ABSTRACT FROM AUTHOR]

Published

2021