Your search keyword '"Vivian L. Weiss"' showing total 2 results

1. Fine-Needle Aspiration-Based Patient-Derived Cancer Organoids

Author

Anna E. Vilgelm, Kensey Bergdorf, Melissa Wolf, Vijaya Bharti, Rebecca Shattuck-Brandt, Ashlyn Blevins, Caroline Jones, Courtney Phifer, Mason Lee, Cindy Lowe, Rachel Hongo, Kelli Boyd, James Netterville, Sarah Rohde, Kamran Idrees, Joshua A. Bauer, David Westover, Bradley Reinfeld, Naira Baregamian, Ann Richmond, W. Kimryn Rathmell, Ethan Lee, Oliver G. McDonald, and Vivian L. Weiss

Subjects

Clinical Medicine, Tissue Engineering, Cancer, Science

Abstract

Summary: Patient-derived cancer organoids hold great potential to accurately model and predict therapeutic responses. Efficient organoid isolation methods that minimize post-collection manipulation of tissues would improve adaptability, accuracy, and applicability to both experimental and real-time clinical settings. Here we present a simple and minimally invasive fine-needle aspiration (FNA)-based organoid culture technique using a variety of tumor types including gastrointestinal, thyroid, melanoma, and kidney. This method isolates organoids directly from patients at the bedside or from resected tissues, requiring minimal tissue processing while preserving the histologic growth patterns and infiltrating immune cells. Finally, we illustrate diverse downstream applications of this technique including in vitro high-throughput chemotherapeutic screens, in situ immune cell characterization, and in vivo patient-derived xenografts. Thus, routine clinical FNA-based collection techniques represent an unappreciated substantial source of material that can be exploited to generate tumor organoids from a variety of tumor types for both discovery and clinical applications.

Published

2020

2. Fine-Needle Aspiration-Based Patient-Derived Cancer Organoids

Author

Caroline Y Jones, Cindy Lowe, Naira Baregamian, Vivian L. Weiss, Melissa M. Wolf, David Westover, Sarah L. Rohde, Rebecca L. Shattuck-Brandt, James L. Netterville, Kelli L. Boyd, Courtney J. Phifer, Rachel Hongo, Vijaya Bharti, Ann Richmond, Joshua A. Bauer, Ashlyn Blevins, Kensey N. Bergdorf, Oliver G. McDonald, W. Kimryn Rathmell, Ethan Lee, Bradley I. Reinfeld, Anna E. Vilgelm, Mason A Lee, and Kamran Idrees

Subjects

0301 basic medicine, Clinical settings, 02 engineering and technology, Article, 03 medical and health sciences, Immune system, Tissue engineering, Organoid, Medicine, lcsh:Science, Cancer, Multidisciplinary, medicine.diagnostic_test, Tissue Engineering, business.industry, Melanoma, Tissue Processing, 021001 nanoscience & nanotechnology, medicine.disease, 030104 developmental biology, Fine-needle aspiration, Cancer research, lcsh:Q, Clinical Medicine, 0210 nano-technology, business

Abstract

Summary Patient-derived cancer organoids hold great potential to accurately model and predict therapeutic responses. Efficient organoid isolation methods that minimize post-collection manipulation of tissues would improve adaptability, accuracy, and applicability to both experimental and real-time clinical settings. Here we present a simple and minimally invasive fine-needle aspiration (FNA)-based organoid culture technique using a variety of tumor types including gastrointestinal, thyroid, melanoma, and kidney. This method isolates organoids directly from patients at the bedside or from resected tissues, requiring minimal tissue processing while preserving the histologic growth patterns and infiltrating immune cells. Finally, we illustrate diverse downstream applications of this technique including in vitro high-throughput chemotherapeutic screens, in situ immune cell characterization, and in vivo patient-derived xenografts. Thus, routine clinical FNA-based collection techniques represent an unappreciated substantial source of material that can be exploited to generate tumor organoids from a variety of tumor types for both discovery and clinical applications., Graphical Abstract, Highlights • Fine-needle aspiration (FNA) is safe, minimally invasive, and widely used clinically • FNA is a source of material for organoid culture and personalized medicine • This technique requires minimal processing, preserving histology, and immune cells • Downstream applications: high-throughput screens, immune analysis, and xenografts, Clinical Medicine; Tissue Engineering; Cancer

Published

2020